\naccredited laboratory, Swedac’s registration number 0076.\u00a0<\/em>\n\t\t\t\t
![\"Fixpunkter](\"https:\/\/www.pentronic.se\/wp-content\/uploads\/2019\/05\/fixpunkter-en.jpg\" "\\"Fixpunkter")
\n\n\t\tInterpolation\n\t<\/h2>\n\t\t\t\t![\"Kalibrering\"](\"https:\/\/www.pentronic.se\/wp-content\/uploads\/2019\/02\/PEN_L5Q0823-1280x1120.jpg\" "\\"Kalibrering\\"")
\n\t
The gaps between the fixed points temperatures are filled out by the use of an interpolation thermometer. This thermometer is in normal temperature ranges of the type SPRT, Standard Platinum Resistance Thermometer. Platinum is an electrically very stable element in these ranges. The SPRT changes its resistance very predictably with temperature and a good resistance bridge is used to present the measuring result.<\/p>\n
Practically the SPRT will be fixed-point calibrated within 14 K – 962 \u00baC and then it will be used as reference at temperatures between the fixed points. At calibration reference and object are held at the same temperature in different types of baths and furnaces. This is what we call comparison calibration.<\/p>\n
The reference sensor’s reading at the calibration temperature is not identical to the true value and this applies to the object as well. Always there is an uncertainty about the measured temperatures depending on fluctating errors that you can not measure. This is what we call measurement uncertainty and it can be calculated.<\/p>\n
As an example Pentronic’s laboratory measures fixed points with a measurement uncertainty down to \u00b10.0016 \u00baC at the triple point of water. At comparison calibration the best uncertainty Pentronic can perform is \u00b10.015 \u00b0C.<\/p>\n
\n\t\tTraceability\n\t<\/h2>\n\t\t\t\t![\"PEN_L5Q0845\"](\"https:\/\/www.pentronic.se\/wp-content\/uploads\/2019\/02\/pen_l5q0845-1280x853.jpg\" "\\"PEN_L5Q0845\\"")
\n\tTraceability is a key word in calibration. Traceability is required to make sure that the measured temperature with its calculated measurement uncertainty agrees with the ITS-90.
\nTraceability is a very important demand in quality assurance management systems such as ISO 9000. Calibration with no traceability is no calibration at all. Traceability always starts with internationally set definitions.\n\n\t\tAccreditation\n\t<\/h2>\n\t
The international bureau of measures and weight, the BIPM, in Paris is the authority for all quantities of the world. BIPM is probably most welknown for keeping the kilogramme prototype, the last “visible” standard. At European level the EA, European co-operation for Accreditation runs the co-operation among the laboratories.<\/p>\n
The member countries have committed themselves to accept calibrations performed by other nations’ labs. Practically this means that a calibration made by Pentronic is adequate in the other member nations. Each country has a delegate in the EA. Swedac is the representative body of Sweden, DKD in Germany etcetera. The task of the national bodies is to accredit – approve – and currently supervise the national laboratory and other accredited labs.<\/p>\n
Pentronic’s laboratory is accredited for temperature calibration since 1988 and is able to realize the most used range of the temperature scale by using its own fixed points. See table above. Pentronic was among the first manufactures of temperature sensors in Europe with an in-house accredited calibration laboratory.<\/p>\n
Pentronic offers accredited calibration of equipment as a service. Read more about the service<\/a> or order calibration<\/a>.<\/p>\n\t\t\t\t The accreditation is quality assured by the ISO\/IEC 17025 standard. This standard requires much more from the lab than other general quality assurance standars do:<\/p>\n Calibration of industrial temperature sensors can, depending on accuracy requirements (measurement uncertainty), take place in an accredited laboratory or in your own industrial lab with traceability to an accredited laboratory and thus to the ITS-90 scale.<\/p>\n The fastest, simplest and most economic way to calibrate a temperature sensor is to compare it a sensor which is traceably calibrated. This comparison can also be performed “in the field”, i e on site or in an industrial lab. For this purpose there are a variety of calibration equipment in the market: Baths, furnaces, dry-block portabel furnaces and even portable fixed point cells as well as indispensable instrumentation.<\/p>\n A dry-block furnace can be the most practical solution in order to calibrate not too large a number of sensors at a time, and with moderate accuracy requirements. A modern dry-block furnace is compactly built and can easily be brought for on-site missions.<\/p>\n There are many designs available and the one by first sight most easily operated furnace is provided with built-in reference sensor measuring the temperature of the bottom of the hole for the sensor to be calibrated. This design is not very accurate as heat transfer and unwanted temperature differences in the block affect both temperature readings:<\/p>\nThe best design is the classic one, one hole for the reference sensor and one or more holes for the sensor to be calibrated. Besides all these sensors should be in equal distance from the heat windings, normally in the same radius from the center of a cylindrical block. See pictures. Liquid baths give you the best accuracy at comparison calibration. They are available in different sizes and the largest ones can also be used for mass calibration.<\/p>\nA high quality liquid bath is much better than a dry-block furnace with air gaps between sensors and temperature block. Liquid flows about the sensor probes which improves heat transfer considerably. At comparison calibrations the baths’ contribution to measurement uncertainty can be reduced to parts of milliKelvins. The liquid in the bath is chosen to suite the temperature range of the calibration:<\/p>\n For temperatures above 100 \u00baC closed fluidized baths are available. Working ranges span from +50 to +700 \u00b0C.<\/p>\n Here aluminum powder is used as heat transfer medium. The powder is stirred by the aid of flowing air.<\/p>\n Old types of fluidized baths are noisy and have a tendency to scatter aluminum powder dust. Isotech’s design, the Ayres’ bath, is completely closed and free from this disadvantage.<\/p>\n\t\t\t\t For temperatures above 500 \u00b0C tubular and spherical furnaces are being used. Their working principle is not far from that of a dry-block calibrator. Due to the high temperature radiation and convection in air dominate the transfer of heat.<\/p>\n These furnaces are mostly intended for laboratory use. Normally the upper temperature limit is about 1300 \u00b0C.<\/p>\n\t\t\t\t Calibration requires accurate and stable instrumentation. Normally two indicators are used, the one connected to the reference sensor and the other one connected to the senser to be calibrated. Also there are combined indicators with two input channels A and B which also can show the difference between the sensors’ temperatures, A-B. Even indicators with combined inputs for Pt100(RTD) and thermocouples are available as well as multi channel indicators for simultaneous calibration of several sensors.<\/p>\n Accurate resistance thermometers like working standards need so called resistance bridges to be accurately calibrated. There are three types of such bridges:<\/p>\n Four-wire connection is an absolute requirement for high-accuracy calibration regardless of the measurement technique being used.<\/p>\n\t By comparison calibration the test sensor is compared to a reference sensor – a temperature sensor with known properties mapped at an accredited calibration laboratory.<\/p>\n The ultimate reference temperature sensor, the SPRT, is constructed solely for careful use in the lab. Its construction is fragile as the high purity platinum wire coil has to be freely suspended in a quartz tube. The SPRT sensor is most accurate but not for use in the field.<\/p>\n For industrial calibration a “working standard” is used which is an improved version of an industrial Pt100 sensor (IPRT) or a traceably calibrated sensor of the same type as the sensor which is to be calibrated.<\/p>\n Pentronic delivers all types. A way increasingly appreciated by Pentronic’s customers is that a sensor from the manufactured batch is traceably calibrated at Pentronic’s accredited laboratory. This temperature sensor will be kept at the customer’s lab and to be used as reference sensor to maintain the requirements for traceability according to the ISO 9000 standard.<\/p>\n\t\t\t\t About calibration of temperature sensors General about temperature and calibration Calibration can be translated to comparison. Swedish Standard SS020106 defines calibration as follows in brief version: “Calibration is an action in order to settle the connection between the displayed value of a measurement system and the corresponding values realized by using standards.” When it comes […]<\/p>\n","protected":false},"author":1,"featured_media":0,"parent":7742,"menu_order":4,"comment_status":"closed","ping_status":"closed","template":"template-content_page.php","meta":{"_acf_changed":false,"_genesis_hide_title":false,"_genesis_hide_breadcrumbs":false,"_genesis_hide_singular_image":false,"_genesis_hide_footer_widgets":false,"_genesis_custom_body_class":"","_genesis_custom_post_class":"","_genesis_layout":"","footnotes":""},"class_list":{"0":"post-4398","1":"page","2":"type-page","3":"status-publish","5":"entry"},"acf":[],"yoast_head":"\n![\"The](\"https:\/\/www.pentronic.se\/wp-content\/uploads\/2019\/02\/tpv.jpg\" "\\"TPV\\"")
\n\t\tThe triple point of water defines \n0,01 \u00b0C of the temperature scale \nITS-90 and is its fundamental fixed point. This cell can realise the fixed-point temperature in fractions of 0,001 \u00b0C.\n\n\t\tOn probation\n\t<\/h2>\n\t
\n
![\"PEN_L5Q0852\"](\"https:\/\/www.pentronic.se\/wp-content\/uploads\/2019\/02\/pen_l5q0852-1280x853.jpg\" "\\"PEN_L5Q0852\\"")
\n\n\t\tYour part of the calibration\n\t<\/h2>\n\t\t\t\t
![\"Picture](\"https:\/\/www.pentronic.se\/wp-content\/uploads\/2022\/03\/akl2021-5-853x1280.jpg\" "\\"AKL2021-5\\"")
\n\t\n\t\tKalibration equipment\n\t<\/h2>\n\t\t\t\t
![\"Axial](\"https:\/\/www.pentronic.se\/wp-content\/uploads\/2019\/04\/blockkal-ax-en-w200-1.jpg\" "\\"Blockkal")
\n\t\tAxial error contribution depends\non different stem losses due to varying probe thickness or due\nto different probe lengths.\n\t\t\t\t![\"\u0394Tp](\"https:\/\/www.pentronic.se\/wp-content\/uploads\/2019\/04\/blockkal-rad-en-w200-1.jpg\" "\\"Blockkal")
\n\t\t\u0394Tp indicates pressure depen-\ndent temperature drop in case\nof replaceable inserts being\nused. Normally the gradient \u0394T\nis the radial error contribution\nused in uncertainty calculation.\n\tPortable dry-block furnaces<\/h3>\n
\nDry-block furnaces are available for temperatures ranging from -100 \u00b0C to 1200 \u00b0C\n\tLiquid baths<\/h3>\n
\nThe most advanced calibration baths that Pentronic can offer are used by national labs worldwide.\n\n
![\"PEN_L5Q0782\"](\"https:\/\/www.pentronic.se\/wp-content\/uploads\/2019\/02\/pen_l5q0782-683x1024.jpg\" "\\"PEN_L5Q0782\\"")
\n\t\t\t\t![\"Fluidiserande](\"https:\/\/www.pentronic.se\/wp-content\/uploads\/2019\/02\/fluidiserande-bad-300x280.png\" "\\"Fluidiserande")
\n\tFluidized baths<\/h3>\n
![\"Ugn\"](\"https:\/\/www.pentronic.se\/wp-content\/uploads\/2019\/06\/ugn-1.jpg\" "\\"Ugn\\"")
\n\tFurnaces<\/h3>\n
![\"Pentronic\"](\"https:\/\/www.pentronic.se\/wp-content\/uploads\/2019\/02\/instrument-1-1024x710.jpg\" "\\"Pentronic\\"")
\n\tInstrumentation<\/h3>\n
\n
Reference temperature sensors<\/h3>\n
![\"PEN_L5Q0798\"](\"https:\/\/www.pentronic.se\/wp-content\/uploads\/2019\/02\/pen_l5q0798-853x1280.jpg\" "\\"PEN_L5Q0798\\"")
\n\n\t\tInterval of calibration\n\t<\/h2>\n\tPermissable time interval between calibrations depends on the actual use of the sensor. A usual thumb rule says once a year but special circumstances can cause need for either shorter intervals or longer ones. High accuracy requirements and harsh environment call for short intervalls while longer intervals can be allowed when accuracy is not too big a demand and when the measuring environment is not influencing the sensor.
\nRecurrent calibration map the measurement equipment over time. It is usual to start with dense calibration intervals and when the long time drift is observed the interval could be extended if relevant.
\nAlways there is the risk for unexpected incidents like anybody drops the sensor on the floor.\n\tThis motivates the introduction of regular functional checks to the reference equipment several times between the regular calibrations.
\nFor platinum sensors, e g Pt100s, 0 \u00baC ice water baths are suitable. Also the very-simple-to-use fixed point of gallium at 29 \u00baC is very suitable but more expensive than the ice bath.\n\t\t\t\t![\"Drift](\"https:\/\/www.pentronic.se\/wp-content\/uploads\/2019\/04\/drift-en-w200-1.jpg\" "\\"Drift")
\n\n","protected":false},"excerpt":{"rendered":"