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|Max Power Dissi.:||125 MW/C||Thermal Time:||360sec|
MF74 10/18 Current Limiting Power NTC Thermistor 10Ohm 18A 25mm Diameter For Super Power Lamps
Advantage of apply MF74 NTC THERMISTOR
Best choice for limiting inrush current
Leading Technology Perfect Function Originate in domestic
Max steady state current : 120A
Inrush current is the momentary surge of current created when power is turned on to motors,transformers,power suppliers and heating elements. The more power required by industrial equipment,the larger the inrush current. It can effectively quench the inrush current by means of in series with power NTC thermistor in return circuit of power supply. The thermistor’s resistance decreases dramatically following the inrush,allowing the steady state curent to flow with very little resistance.This effect provides inrush current protection, yet allows efficiency during normal operation.The power NTC Thermistor produced by Guangdong Uchi Technology Co.,Ltd. with large scale,especially MF73T,MF73,MF74,MF75 serial products with big size,which can be applied in such inrush protection with industrial level as industrial robots and automation.
Reliable configuration and convenient installation
Strongest capability of surge current protection and energy absorption
PATENT NO: 03277490.7
Power conversion,switch powe,UPS Power
All kinds of of super power lamps
|P/N||R25±20%(Ω)||Max steady state current Imax(A)||Approx R of Max current Rmax(Ω)||Thermal time constant (mW/C)||Thermal time constant (s)|
Thermistor is a ceramic semiconducting element made from exorbitant oxides material. It has the feature that the resistance changes according to the ambient temperature. Namely, their resistance declines with the rising of ambient temperature at a determinated measuring power. With this feature NTC thermistor and temperature sensor can be applied in the situation of temperature compensation, measurement and control and surge current protection.
Main Techno-Parameter of NTC Thermistor
1.Zero Power Resistance RT
At rated temperature, it is the resistance measured by the measuring power which causes the resistance change that can be ignored relative to the whole measuring error.
2.Rated Zero Power ResistanceR25
The rated resistance of thermistor which is the zero power resistance measured at 25℃ and signed on the thermistor.
B value is the thermal exponent of negative temperature coefficient thermistor, which is defined as the ratio of the difference between the napierian logarithms of zero power resistance at two temperatures to the difference between the two temperatures’ reciproal.
In the equation:
RT1- the zero power resistance at T1
RT2- the zero power resistance at T2
Unless the particular indication, B value is figured out from the zero power resistances at 25℃(298.15K) and 50℃(323.15K) and B value is not a rigorous constant in the range of operating temperature.
4.Temperature Coefficient of Zero Power ResistanceαT
At rated temperature, it is the ratio of the zero power resistance change rate with temperature to the zero power resistance itself. Namely:
αT-the temperature coefficient of zero power resistance at T
RT-the zero power resistance at T
B- B value
5. Dissipation Coefficientδ
At rated ambient temperature, it is the ratio of consumption power change rate of thermistor to the change of the corresponding temperature, namely:
In the range of operating temperature, δ has a little change with the ambient.
6. Thermal Time Constantτ
At zero power, it is measured as time in seconds which needed for thermistor temperature change of 63.2% difference between initial and final thermistor temperature when the temperature breaks.
τis in direct ratio to thermal capacity C of thermistor and in inverse ratio to the dissipation coefficient, namely:
7. Max. Steady State Current
The maximum allowable continuous current passing through thermistor at 25℃.
8. Resistance-temperature Characteristic
The reliant relationship between the zero power resistance of thermistor and its temperature.
R-T curve NTC thermistor
9. Static V-I characteristic refers to the relationship between voltage and current when NTC thermistor establishes the thermal balance state, because the variable range of the relationship between terminal voltage and current of thermistor is very wide, its voltage and current curve is often represent by double logarithms coordinates.