Resistance thermometer

Resistance thermometers, also called resistance temperature detectors or resistive thermal devices (RTDs), are sensors used to measure temperature by correlating the resistance of the RTD element with temperature. Most RTD elements consist of a length of fine coiled wire wrapped around a ceramic or glass core. The element is usually quite fragile, so it is often placed inside a sheathed probe to protect it. The RTD element is made from a pure material whose resistance at various temperatures has been documented. The material has a predictable change in resistance as the temperature changes; it is this predictable change that is used to determine temperature.

As they are almost invariably made of platinum, they are often called platinum resistance thermometers (PRTs). They are slowly replacing the use of thermocouples in many industrial applications below 600 °C, due to higher accuracy and repeatability.[1]

Contents

R vs T relationship of various metals

Common RTD sensing elements constructed of platinum, copper or nickel have a unique, and repeatable and predictable resistance versus temperature relationship (R vs T) and operating temperature range. The R vs T relationship is defined as the amount of resistance change of the sensor per degree of temperature change.

Platinum is a noble metal and has the most stable resistance to temperature relationship over the largest temperature range. Nickel elements have a limited temperature range because the amount of change in resistance per degree of change in temperature becomes very non-linear at temperatures over 572 ºF (300 ºC). Copper has a very linear resistance to temperature relationship, however copper oxidizes at moderate temperatures and cannot be used over 302ºF (150ºC).

Platinum is the best metal for RTDs because it follows a very linear resistance to temperature relationship and it follows the R vs T relationship in a highly repeatable manner over a wide temperature range. The unique properties of platinum make it the material of choice for temperature standards over the range of -272.5 ºC to 961.78 ºC, and is used in the sensors that define the International Temperature Standard, ITS-90. It is made using platinum because of its linear resistance-temperature relationship and its chemical inertness.

The basic differentiator between metals used as resistive elements is the linear approximation of the R vs T relationship between 0 and 100 ºC and is referred to as alpha, α. The equation below defines α, its units are ohm/ohm/ºC.

\alpha = \left[ R_{100} - R_0 \right]
 R_0 = the resistance of the sensor at 0°C
 R_{100} = the resistance of the sensor at 100°C

Pure platinum has an alpha of 0.003925 ohm/ohm/ºC and is used in the construction of laboratory grade RTDs. Conversely two widely recognized standards for industrial RTDs IEC 6075 and ASTM E-1137 specify an alpha of 0.00385 ohms/ohm/ºC. Before these standards were widely adopted several different alpha values were used. It is still possible to find older probes that are made with platinum that have alpha values of 0.003916 ohms/ohm/ºC and 0.003902 ohms/ohm/ºC.

These different alpha values for platinum are achieved by doping; basically carefully introducing impurities into the platinum. The impurities introduced during doping become embedded in the lattice structure of the platinum and result in a different R vs.T curve and hence alpha value.[2]

Calibration

To characterize the R vs T relationship of any RTD over a temperature range that represents the planned range of use, calibration must be performed at temperatures other than 0ºC and 100ºC. Two common calibration methods are the fixed point method and the comparison method. [3]

RTD Element Types

There are three main categories of RTD sensors; Thin Film, Wire-Wound, and Coiled Elements. While these types are the ones most widely used in industry there are some places were other more exotic shapes are used, for example carbon resistors are used at ultra low temperatures (-173 °C to -273 °C).[4]

The current international standard which specifies tolerance, and the temperature-to-electrical resistance relationship for platinum resistance thermometers is IEC 60751:2008, ASTM E1137 is also used in the United States. By far the most common devices used in industry have a nominal resistance of 100 ohms at 0 °C, and are called Pt100 sensors ('Pt' is the symbol for platinum). The sensitivity of a standard 100 ohm sensor is a nominal 0.00385 ohm/°C. RTDs with a sensitivity of 0.00375 and 0.00392 ohm/°C as well as a variety of others are also available.

Function

Resistance thermometers are constructed in a number of forms and offer greater stability, accuracy and repeatability in some cases than thermocouples. While thermocouples use the Seebeck effect to generate a voltage, resistance thermometers use electrical resistance and require a power source to operate. The resistance ideally varies linearly with temperature.

The platinum detecting wire needs to be kept free of contamination to remain stable. A platinum wire or film is supported on a former in such a way that it gets minimal differential expansion or other strains from its former, yet is reasonably resistant to vibration. RTD assemblies made from iron or copper are also used in some applications. Commercial platinum grades are produced which exhibit a temperature coefficient of resistance 0.00385/°C (0.385%/°C) (European Fundamental Interval).[6] The sensor is usually made to have a resistance of 100 Ω at 0 °C. This is defined in BS EN 60751:1996 (taken from IEC 60751:1995). The American Fundamental Interval is 0.00392/°C,[7] based on using a purer grade of platinum than the European standard. The American standard is from the Scientific Apparatus Manufacturers Association (SAMA), who are no longer in this standards field. As a result the "American standard" is hardly the standard even in the US.

Measurement of resistance requires a small current to be passed through the device under test. This can cause resistive heating, causing significant loss of accuracy if manufacturers' limits are not respected, or the design does not properly consider the heat path. Mechanical strain on the resistance thermometer can also cause inaccuracy. Lead wire resistance can also be a factor; adopting three- and four-wire, instead of two-wire, connections can eliminate connection lead resistance effects from measurements (see below); three-wire connection is sufficient for most purposes and almost universal industrial practice. Four-wire connections are used for the most precise applications.

Advantages and limitations

Advantages of platinum resistance thermometers:

Limitations:

Sources of error:

The common error sources of a PRT are:

RTDs vs Thermocouples

The two most common ways of measuring industrial temperatures are with resistance temperature detectors (RTDs) and thermocouples. Choice between them is usually determined by four factors.

Construction

These elements nearly always require insulated leads attached. At temperatures below about 250 °C PVC, silicon rubber or PTFE insulators are used. Above this, glass fibre or ceramic are used. The measuring point, and usually most of the leads, require a housing or protective sleeve, often made of a metal alloy which is chemically inert to the process being monitored. Selecting and designing protection sheaths can require more care than the actual sensor, as the sheath must withstand chemical or physical attack and provide convenient attachment points.

Wiring configurations

Two-wire configuration

The simplest resistance thermometer configuration uses two wires. It is only used when high accuracy is not required, as the resistance of the connecting wires is added to that of the sensor, leading to errors of measurement. This configuration allows use of 100 meters of cable. This applies equally to balanced bridge and fixed bridge system.

Three-wire configuration

In order to minimize the effects of the lead resistances, a three-wire configuration can be used. Using this method the two leads to the sensor are on adjoining arms. There is a lead resistance in each arm of the bridge so that the resistance is cancelled out, so long as the two lead resistances are accurately the same. This configuration allows up to 600 meters of cable.

Error on the schematic : A three wire RTD is connected in the following manner. One lead is connected to R1. That wire's lead resistance is measured as a part of the RTD resistance. One wire (of the two on the other end of the RTD) is connected to the lower end of R3. This wire's lead resistance is measured with R3, the reference resistor. One wire (of the two on the other end of the RTD) is connected to the supply return. (ground) This resistance is normally considered too low to matter in the measurement and is in series with the currents through the RTD and the reference resistor (R3) The lead resistance effects are all translated into common mode voltages that are rejected (common mode rejection) by the instrumentation amplifier. The wires are typically the same gauge and made of the same wire, to minimise temperature coefficient issues.

Four-wire configuration

The four-wire resistance thermometer configuration increases the accuracy and reliability of the resistance being measured: the resistance error due to lead wire resistance is zero. In the diagram above a standard two-terminal RTD is used with another pair of wires to form an additional loop that cancels out the lead resistance. The above Wheatstone bridge method uses a little more copper wire and is not a perfect solution. Below is a better configuration, four-wire Kelvin connection. It provides full cancellation of spurious effects; cable resistance of up to 15 Ω can be handled.

Classifications of RTDs

The highest accuracy of all PRTs is the Standard platinum Resistance Thermometers (SPRTs). This accuracy is achieved at the expense of durability and cost. The SPRTs elements are wound from reference grade platinum wire. Internal lead wires are usually made from platinum while internal supports are made from quartz or fuse silica. The sheaths are usually made from quartz or sometimes Inconel depending on temperature range. Larger diameter platinum wire is used, which drives up the cost and results in a lower resistance for the probe (typically 25.5 ohms). SPRTs have a wide temperature range (-200°C to 1000°C) and approximately accurate to ±0.001°C over the temperature range. SPRTs are only appropriate for laboratory use.

Another classification of laboratory PRTs is Secondary Standard platinum Resistance Thermometers (Secondary SPRTs). They are constructed like the SPRT, but the materials are more cost-effective. SPRTs commonly use reference grade, high purity smaller diameter platinum wire, metal sheaths and ceramic type insulators. Internal lead wires are usually a nickel based alloy. Secondary SPRTs are limited in temperature range (-200°C to 500°C) and are approximately accurate to ±0.03°C over the temperature range.

Industrial PRTs are designed to withstand industrial environments. They can be almost as durable as a thermocouple. Depending on the application industrial PRTs can use thin film elements or coil wound elements. The internal lead wires can range from PTFE insulated stranded nickel plated copper to silver wire, depending on the sensor size and application. Sheath material is typically stainless steel; higher temperature applications may demand Inconel. Other materials are used for specialized applications.

Applications

Sensor assemblies can be categorized into two groups by how they are installed or interface with the process: immersion or surface mounted.

Other applications may require special water proofing or pressure seals. A heavy-duty underwater temperature sensor is designed for complete submersion under rivers, cooling ponds, or sewers. Steam autoclaves require a sensor that is sealed from intrusion by steam during the vacuum cycle process.

Immersion sensors generally have the best measurement accuracy because they are in direct contact with the process fluid. Surface mounted sensors are measuring the pipe surface as a close approximation of the internal process fluid.

History

The application of the tendency of electrical conductors to increase their electrical resistance with rising temperature was first described by Sir William Siemens at the Bakerian Lecture of 1871 before the Royal Society of Great Britain. The necessary methods of construction were established by Callendar, Griffiths, Holborn and Wein between 1885 and 1900.

Standard resistance thermometer data

Temperature sensors are usually supplied with thin-film elements. The resisting elements are rated in accordance with BS EN 60751:2008 as:

Tolerance Class Valid Range
F 0.3 -50 to +500 °C
F 0.15 -30 to +300 °C
F 0.1 0 to +150 °C

Resistance thermometer elements can be supplied which function up to 1000 °C. The relation between temperature and resistance is given by the Callendar-Van Dusen equation,

R_T = R_0 \left[ 1 %2B AT %2B BT^2 %2B CT^3 (T-100) \right] \; (-200\;{}^{\circ}\mathrm{C} < T < 0\;{}^{\circ}\mathrm{C}),
R_T = R_0 \left[ 1 %2B AT %2B BT^2 \right] \; (0\;{}^{\circ}\mathrm{C} \leq T < 850\;{}^{\circ}\mathrm{C}).

Here, R_T is the resistance at temperature T, R_0 is the resistance at 0 °C, and the constants (for an alpha=0.00385 platinum RTD) are

A =  3.9083 \times 10^{-3} \; {}^{\circ}\mathrm{C}^{-1}
B = -5.775 \times 10^{-7} \; {}^{\circ}\mathrm{C}^{-2}
C = -4.183 \times 10^{-12} \; {}^{\circ}\mathrm{C}^{-4}.

Since the B and C coefficients are relatively small, the resistance changes almost linearly with the temperature.

Values for various popular resistance thermometers

Values for various popular resistance thermometers
Temperature
in °C
Pt100
in Ω
Pt1000
in Ω
PTC
in Ω
NTC
in Ω
NTC
in Ω
NTC
in Ω
NTC
in Ω
NTC
in Ω
Typ: 404 Typ: 501 Typ: 201 Typ: 101 Typ: 102 Typ: 103 Typ: 104 Typ: 105
−50 80.31 803.1 1032
−45 82.29 822.9 1084
−40 84.27 842.7 1135 50475
−35 86.25 862.5 1191 36405
−30 88.22 882.2 1246 26550
−25 90.19 901.9 1306 26083 19560
−20 92.16 921.6 1366 19414 14560
−15 94.12 941.2 1430 14596 10943
−10 96.09 960.9 1493 11066 8299
−5 98.04 980.4 1561 31389 8466
0 100.00 1000.0 1628 23868 6536
5 101.95 1019.5 1700 18299 5078
10 103.90 1039.0 1771 14130 3986
15 105.85 1058.5 1847 10998
20 107.79 1077.9 1922 8618
25 109.73 1097.3 2000 6800 15000
30 111.67 1116.7 2080 5401 11933
35 113.61 1136.1 2162 4317 9522
40 115.54 1155.4 2244 3471 7657
45 117.47 1174.7 2330 6194
50 119.40 1194.0 2415 5039
55 121.32 1213.2 2505 4299 27475
60 123.24 1232.4 2595 3756 22590
65 125.16 1251.6 2689 18668
70 127.07 1270.7 2782 15052
75 128.98 1289.8 2880 12932
80 130.89 1308.9 2977 10837
85 132.80 1328.0 3079 9121
90 134.70 1347.0 3180 7708
95 136.60 1366.0 3285 6539
100 138.50 1385.0 3390
105 140.39 1403.9
110 142.29 1422.9
150 157.31 1573.1
200 175.84 1758.4
Copied from German version, please don't remove

The function for temperature value acquisition (C++)

The following code provides a temperature sensor Pt100 or Pt1000 from its current resistance.

float GetPt100Temperature(float r)
{
    float const Pt100[] = {  80.31,   82.29,  84.27,  86.25,  88.22,  90.19,  92.16,  94.12,  96.09,  98.04,
                                100.0,    101.95, 103.9,  105.85, 107.79, 109.73, 111.67, 113.61, 115.54, 117.47,
                                119.4,  121.32, 123.24, 125.16, 127.07, 128.98, 130.89, 132.8,  134.7,  136.6,
                                138.5,  140.39, 142.29, 157.31, 175.84, 195.84};
    int t = -50, i, dt = 0;
    if (r > Pt100[i = 0])
      while (250 > t) {
        dt = (t < 110) ? 5 : (t > 110) ? 50 : 40;
        if (r < Pt100[++i])
          return t + (r - Pt100[i-1]) * dt / (Pt100[i] - Pt100[i-1]);
        t += dt;
      };
 
    return t;
}
 
float GetPt1000Temperature(float r)
{
    return GetPt100Temperature(r / 10);
}

See also

References

  1. ^ Common RTD sensing elements constructed of platinum copper or nickel have a unique, and repeatable and predictable resistance versus temperature relationship (R vs T) and operating temperature range. The R vs T relationship is defined as the amount of resistance change of the sensor per degree of temperature change. Frequently asked questions about RTD’s, http://www.burnsengineering.com/pgd.asp?pgid=docfaq, retrieved 2009-09-18 
  2. ^ http://www.burnsengineering.com/tech-papers/
  3. ^ Calibration, http://www.burnsengineering.com/document/papers/Calibration-Why_When_How_Handout.pdf, retrieved 2011-11-16 
  4. ^ Carbon Resistors, http://www.bipm.org/utils/common/pdf/its-90/TECChapter11.pdf, retrieved 2011-11-16 
  5. ^ RTD Element Types, http://canteach.candu.org/library/20030701.pdf, retrieved 2011-11-16 
  6. ^ http://www.instrumentationservices.net/hand-held-thermometers.php
  7. ^ http://hyperphysics.phy-astr.gsu.edu/hbase/electric/restmp.html
  8. ^ Interchangeability, http://www.burnsengineering.com/document/pdf/interchangeability.pdf, retrieved 2009-09-18 
  9. ^ Insulation Resistance, http://www.burnsengineering.com/document/pdf/a080211.pdf, retrieved 2009-09-18 
  10. ^ Stability, http://www.burnsengineering.com/document/pdf/a080306.pdf, retrieved 2009-09-18 
  11. ^ Repeatability, http://www.burnsengineering.com/document/papers/PRT_Error_Sources_Part_4_Repeatability.pdf, retrieved 2009-09-18 
  12. ^ Hysteresis, http://www.burnsengineering.com/document/papers/PRT_Error_Sources_Part_5_Hysteresis.pdf, retrieved 2009-09-18 
  13. ^ http://www.omega.com/temperature/Z/pdf/z241-245.pdf
  14. ^ Small Line Direct Imersion, http://www.burnsengineering.com/document/pdf/a110425.pdf, retrieved 2011-11-16 
  15. ^ Thermowell, http://www.burnsengineering.com/document/pdf/A080528.pdf, retrieved 2011-11-16 
  16. ^ Averaging Sensors, http://www.burnsengineering.com/document/pdf/a100415.pdf, retrieved 2011-11-16 
  17. ^ Elbow Thermowell, http://www.burnsengineering.com/document/pdf/A080218.pdf, retrieved 2011-11-16 
  18. ^ Surface Sensor, http://www.burnsengineering.com/document/pdf/A071011.pdf, retrieved 2011-11-16 

External links