Deflecting Torque for AC operation in Electrodynamometer Solution

STEP 0: Pre-Calculation Summary
Formula Used
AC Operation Torque = RMS Current 1 in Electrodynamometer*RMS Current 2 in Electrodynamometer*cos(Phase Angle in Electrodynamometer)*Mutual Inductance with Angle
Tac = Irms1*Irms2*cos(ϕ)*dM|dθ
This formula uses 1 Functions, 5 Variables
Functions Used
cos - Cosine of an angle is the ratio of the side adjacent to the angle to the hypotenuse of the triangle., cos(Angle)
Variables Used
AC Operation Torque - (Measured in Newton Meter) - AC Operation Torque is a measure of the rotational force applied to an object. It causes objects to rotate around an axis, following the principles of rotational motion.
RMS Current 1 in Electrodynamometer - (Measured in Ampere) - RMS Current 1 in Electrodynamometer is the effective value of alternating current (AC), representing the equivalent direct current that delivers the same power to a coil 1 in electrodynamometer.
RMS Current 2 in Electrodynamometer - (Measured in Ampere) - RMS Current 2 in Electrodynamometer is the effective value of alternating current (AC), representing the equivalent direct current that delivers the same power to a coil 2 in electrodynamometer.
Phase Angle in Electrodynamometer - (Measured in Radian) - Phase Angle in Electrodynamometer measures the relative timing between two periodic waveforms, indicating the time difference between corresponding points of the waves.
Mutual Inductance with Angle - (Measured in Henry Per Radian) - Mutual Inductance with Angle refers to how the interaction between coils varies as the angle alters, influencing sensitivity and torque measurement accuracy.
STEP 1: Convert Input(s) to Base Unit
RMS Current 1 in Electrodynamometer: 0.75 Ampere --> 0.75 Ampere No Conversion Required
RMS Current 2 in Electrodynamometer: 1.25 Ampere --> 1.25 Ampere No Conversion Required
Phase Angle in Electrodynamometer: 0.39 Radian --> 0.39 Radian No Conversion Required
Mutual Inductance with Angle: 4 Henry Per Radian --> 4 Henry Per Radian No Conversion Required
STEP 2: Evaluate Formula
Substituting Input Values in Formula
Tac = Irms1*Irms2*cos(ϕ)*dM|dθ --> 0.75*1.25*cos(0.39)*4
Evaluating ... ...
Tac = 3.46840897446492
STEP 3: Convert Result to Output's Unit
3.46840897446492 Newton Meter --> No Conversion Required
FINAL ANSWER
3.46840897446492 3.468409 Newton Meter <-- AC Operation Torque
(Calculation completed in 00.006 seconds)

Credits

Creator Image
Created by Nikita Suryawanshi
Vellore Institute of Technology (VIT), Vellore
Nikita Suryawanshi has created this Calculator and 100+ more calculators!
Verifier Image
Verified by Devyaani Garg
Shiv Nadar University (SNU), Greater Noida
Devyaani Garg has verified this Calculator and 25+ more calculators!

Electrodynamometer Type Calculators

Deflection Angle for AC operation in Electrodynamometer
​ LaTeX ​ Go Deflection Angle AC Electrodynamometer = ((RMS Current 1 in Electrodynamometer*RMS Current 2 in Electrodynamometer)/Spring Constant in Electrodynamometer)*cos(Phase Angle in Electrodynamometer)*Mutual Inductance with Angle
Deflecting Torque for AC operation in Electrodynamometer
​ LaTeX ​ Go AC Operation Torque = RMS Current 1 in Electrodynamometer*RMS Current 2 in Electrodynamometer*cos(Phase Angle in Electrodynamometer)*Mutual Inductance with Angle
Deflection Angle for DC operation in Electrodynamometer
​ LaTeX ​ Go Deflection Angle DC Electrodynamometer = ((Direct Current 1 in Electrodynamometer*Direct Current 2 in Electrodynamometer)/Spring Constant in Electrodynamometer)*Mutual Inductance with Angle
Deflecting Torque for DC operation in Electrodynamometer
​ LaTeX ​ Go DC Operation Torque = Direct Current 1 in Electrodynamometer*Direct Current 2 in Electrodynamometer*Mutual Inductance with Angle

Deflecting Torque for AC operation in Electrodynamometer Formula

​LaTeX ​Go
AC Operation Torque = RMS Current 1 in Electrodynamometer*RMS Current 2 in Electrodynamometer*cos(Phase Angle in Electrodynamometer)*Mutual Inductance with Angle
Tac = Irms1*Irms2*cos(ϕ)*dM|dθ

What is done in deflecting torque calculation?

Mechanical work done by the instrument is directly proportional to the deflecting torque. The deflecting torque is a function of the product of the instantaneous current flowing through both coils, fixed and moving, and the power factor of the instrument. It is inversely proportional to the change in the deflecting angle

How to Calculate Deflecting Torque for AC operation in Electrodynamometer?

Deflecting Torque for AC operation in Electrodynamometer calculator uses AC Operation Torque = RMS Current 1 in Electrodynamometer*RMS Current 2 in Electrodynamometer*cos(Phase Angle in Electrodynamometer)*Mutual Inductance with Angle to calculate the AC Operation Torque, Deflecting Torque for AC operation in Electrodynamometer formula refers to the deflecting torque which is generated by the interaction between the magnetic fields of the fixed and moving coils. This torque is proportional to the product of the currents in these coils and the cosine of the phase angle between them, effectively measuring the average power in the circuit. AC Operation Torque is denoted by Tac symbol.

How to calculate Deflecting Torque for AC operation in Electrodynamometer using this online calculator? To use this online calculator for Deflecting Torque for AC operation in Electrodynamometer, enter RMS Current 1 in Electrodynamometer (Irms1), RMS Current 2 in Electrodynamometer (Irms2), Phase Angle in Electrodynamometer (ϕ) & Mutual Inductance with Angle (dM|dθ) and hit the calculate button. Here is how the Deflecting Torque for AC operation in Electrodynamometer calculation can be explained with given input values -> 4.335511 = 0.75*1.25*cos(0.39)*4.

FAQ

What is Deflecting Torque for AC operation in Electrodynamometer?
Deflecting Torque for AC operation in Electrodynamometer formula refers to the deflecting torque which is generated by the interaction between the magnetic fields of the fixed and moving coils. This torque is proportional to the product of the currents in these coils and the cosine of the phase angle between them, effectively measuring the average power in the circuit and is represented as Tac = Irms1*Irms2*cos(ϕ)*dM|dθ or AC Operation Torque = RMS Current 1 in Electrodynamometer*RMS Current 2 in Electrodynamometer*cos(Phase Angle in Electrodynamometer)*Mutual Inductance with Angle. RMS Current 1 in Electrodynamometer is the effective value of alternating current (AC), representing the equivalent direct current that delivers the same power to a coil 1 in electrodynamometer, RMS Current 2 in Electrodynamometer is the effective value of alternating current (AC), representing the equivalent direct current that delivers the same power to a coil 2 in electrodynamometer, Phase Angle in Electrodynamometer measures the relative timing between two periodic waveforms, indicating the time difference between corresponding points of the waves & Mutual Inductance with Angle refers to how the interaction between coils varies as the angle alters, influencing sensitivity and torque measurement accuracy.
How to calculate Deflecting Torque for AC operation in Electrodynamometer?
Deflecting Torque for AC operation in Electrodynamometer formula refers to the deflecting torque which is generated by the interaction between the magnetic fields of the fixed and moving coils. This torque is proportional to the product of the currents in these coils and the cosine of the phase angle between them, effectively measuring the average power in the circuit is calculated using AC Operation Torque = RMS Current 1 in Electrodynamometer*RMS Current 2 in Electrodynamometer*cos(Phase Angle in Electrodynamometer)*Mutual Inductance with Angle. To calculate Deflecting Torque for AC operation in Electrodynamometer, you need RMS Current 1 in Electrodynamometer (Irms1), RMS Current 2 in Electrodynamometer (Irms2), Phase Angle in Electrodynamometer (ϕ) & Mutual Inductance with Angle (dM|dθ). With our tool, you need to enter the respective value for RMS Current 1 in Electrodynamometer, RMS Current 2 in Electrodynamometer, Phase Angle in Electrodynamometer & Mutual Inductance with Angle and hit the calculate button. You can also select the units (if any) for Input(s) and the Output as well.
Let Others Know
Facebook
Twitter
Reddit
LinkedIn
Email
WhatsApp
Copied!