Precision Temperature Measurement & Control Devices
NTC THERMISTORS
Negative Temperature Coefficient (NTC) thermistors are thermally sensitive semiconductor resistors which
exhibit a decrease in resistance as absolute temperature increases. Change in the resistance of the NTC
thermistor can be brought about either by a change in the ambient temperature or internally by self-heating
resulting from current flowing through the device. Most of the practical applications of NTC thermistors are
based on these material characteristics.
ACCU-CURVE™
FEATURES
• Wide Ohmic Value Range
• Accurate & Stable
• D.C. 1mW/°C
• Fast Thermal Response Time
• T.C. 10 Sec. in Air
• Compact Epoxy Package Style
• High Sensitivity
INTERCHANGEABLE THERMISTORS
Ametherm manufactures precision resistance-temperature matched ACCU-CURVE™ thermistors. These devices
offer interchangeability over a broad temperature range and eliminate the need to individually calibrate or
provide circuit compensation for part variability. Accurate temperature measurement to
+
0.1 °C
is available
over the 0°C to 70°C temperature range. Standard ohmic values at 25°C range from 2,252 to 100,000 ohms.
THERMISTOR TERMINOLOGY FOR TEMPERATURE MEASUREMENT
& CONTROL DEVICES
•
D.C.
— The dissipation constant is the ratio, normally expressed in milliwatts per degree C (mw/°C), at a
specified ambient temperature, of a change in power dissipated in a thermistor to the resultant change in
body temperature.
•
T.C.
— The thermal time constant is the time required for a thermistor to change 63.2% of the total
difference between its initial and final body temperature when subjected to a step function change in
temperature under zero-power conditions and is normally expressed in seconds (S).
•
Alpha (Ω) or Temperature Coefficient of Resistance
— The temperature coefficient of resistance is the
ratio at a specified temperature, T, of the rate of change of zero-power resistance with temperature to the
zero-power resistance of the thermistor. The temperature coefficient is commonly expressed in percent per
degree C (%/°C).
Applications
There are numerous ways of measuring temperature electronically. Improvements in thermistor technology, coupled with the introduction of integrated
circuitry, have made precision temperature measurement systems very cost effective. Microprocessors, A/D converters, interface electronics and displays
are readily available. Circuit designs with built-in thermistor resistance-temperature algorithms have gained wide spread acceptance in precision
temperature metrology. ACCU-CURVE™ style thermistors are used in many applications that require a high degree of accuracy and reliability.
Some of the most popular applications of NTC ACCU-CURVE™ thermistors include:
• Temperature Measurement & Control
• Temperature Sensors
SELECTION CONSIDERATIONS FOR NTC ACCU-CURVE™ DEVICES
Interchangeable ACCU-CURVE™ NTC thermistors are usually selected when a high degree of measurement accuracy is required over a wide
temperature range. By modifying the Alpha equation, the resistance and temperature tolerances can be calculated for various temperature intervals.
Because thermistors are non-linear with respect to their resistance-temperature characteristics, Alpha therefore is non-linear across their resistance-
temperature range. As an example, a thermistor material curve with an Alpha of -4.4%/°C @ 25°C will have an Alpha of -3.8%/°C @ 50°C. For
practical applications we recommend that the standardized R/T curves be used.
ACCU-CURVE™ thermistors can dissipate 1mW/°C. As a result, the possibility of error induced by excessive current flow, which would defeat the level of
accuracy these devices are capable of representing, may exist in some circuits. To prevent this type of error, Ametherm recommends that circuit design
engineers select the highest R value their circuit will tolerate for applications > 5 Volts to minimize any self-heating of the thermistor device. Refer to
the ACCU-CURVE™ Specifications table for resistance values and temperature tolerances.
Ametherm offers two standard R/T curves, “C” & “W”, with temperature coefficients of resistance (Ω) of -4.4%/°C and -4.7%/°C, and Beta (ß) values
of 3965°K and 4250°K. To determine the nominal resistance value of a thermistor at a specified temperature, multiply its resistance at 25°C value by
the corresponding RT/R25 value for the desired temperature and applicable R-T curve from the ACCU-CURVE™.
T: 800-808-2434 | 775-884-2434 (Outside the United States and Canada | www.ametherm.com | info@ametherm.com
Integrated technical exchanges
京公网安备 11010802033920号
EEWORLD
