Driving Torque in Energy Meter Calculator

✖Spring Constant 1 Induction is a factor that links driving torque to power consumption, ensuring accurate measurement of electrical energy use.ⓘ Spring Constant 1 Induction [K₁]			+10% -10%
✖Total Voltage Induction is the sum of the voltage across the load and shunt coils, facilitating the measurement of power consumption by the energy meter.ⓘ Total Voltage Induction [V]			+10% -10%
✖Total Current Induction is the sum of the load current passing through the current coil, creating a magnetic field that interacts with the voltage coil to measure power.ⓘ Total Current Induction [I]			+10% -10%
✖Phase Angle Induction is the difference in timing between the peaks of voltage and current waveforms in an AC circuit, affecting power flow and efficiency.ⓘ Phase Angle Induction [ϕ_i]			+10% -10%

✖Braking Torque Induction is the retarding force generated by eddy currents opposing the disc's motion, ensuring accurate measurement by balancing the driving torque.ⓘ Driving Torque in Energy Meter [T_b]

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Formula

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Driving Torque in Energy Meter

Formula

`"T"_{"b"} = "K"_{"1"}*"V"*"I"*cos("ϕ"_{"i"})`

Example

`"1004.863N*m"="12Nm/rad"*"20V"*"8A"*cos("1.02rad")`

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Driving Torque in Energy Meter Solution

STEP 0: Pre-Calculation Summary

Formula Used

Braking Torque Induction = Spring Constant 1 Induction*Total Voltage Induction*Total Current Induction*cos(Phase Angle Induction)
T_b = K₁*V*I*cos(ϕ_i)
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

Braking Torque Induction - (Measured in Newton Meter) - Braking Torque Induction is the retarding force generated by eddy currents opposing the disc's motion, ensuring accurate measurement by balancing the driving torque.
Spring Constant 1 Induction - (Measured in Newton Meter per Radian) - Spring Constant 1 Induction is a factor that links driving torque to power consumption, ensuring accurate measurement of electrical energy use.
Total Voltage Induction - (Measured in Volt) - Total Voltage Induction is the sum of the voltage across the load and shunt coils, facilitating the measurement of power consumption by the energy meter.
Total Current Induction - (Measured in Ampere) - Total Current Induction is the sum of the load current passing through the current coil, creating a magnetic field that interacts with the voltage coil to measure power.
Phase Angle Induction - (Measured in Radian) - Phase Angle Induction is the difference in timing between the peaks of voltage and current waveforms in an AC circuit, affecting power flow and efficiency.

STEP 1: Convert Input(s) to Base Unit

Spring Constant 1 Induction: 12 Newton Meter per Radian --> 12 Newton Meter per Radian No Conversion Required
Total Voltage Induction: 20 Volt --> 20 Volt No Conversion Required
Total Current Induction: 8 Ampere --> 8 Ampere No Conversion Required
Phase Angle Induction: 1.02 Radian --> 1.02 Radian No Conversion Required

STEP 2: Evaluate Formula

Substituting Input Values in Formula

T_b = K₁*V*I*cos(ϕ_i) --> 12*20*8*cos(1.02)

Evaluating ... ...

T_b = 1004.86262640317

STEP 3: Convert Result to Output's Unit

1004.86262640317 Newton Meter --> No Conversion Required

FINAL ANSWER

1004.86262640317 ≈ 1004.863 Newton Meter <-- Braking Torque Induction

(Calculation completed in 00.004 seconds)

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Created by Nikita Suryawanshi

Vellore Institute of Technology (VIT), Vellore

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< 2 Induction Type Calculators

Driving Torque in Energy Meter

Go Braking Torque Induction = Spring Constant 1 Induction*Total Voltage Induction*Total Current Induction*cos(Phase Angle Induction)

Driving Torque Induction

Go Driving Torque Induction = Spring Constant 2 Induction*Disc Speed Induction

Driving Torque in Energy Meter Formula

Braking Torque Induction = Spring Constant 1 Induction*Total Voltage Induction*Total Current Induction*cos(Phase Angle Induction)
T_b = K₁*V*I*cos(ϕ_i)

How does driving torque work?

Driving torque works by the principle of electromagnetic induction. When electricity flows through the meter's coils, it creates magnetic fields. The interaction between these magnetic fields generates a force, known as driving torque, which causes the meter's disc to rotate. This rotation is proportional to the amount of electrical energy consumed, allowing the meter to measure the energy usage accurately.

How to Calculate Driving Torque in Energy Meter?

Driving Torque in Energy Meter calculator uses Braking Torque Induction = Spring Constant 1 Induction*Total Voltage Induction*Total Current Induction*cos(Phase Angle Induction) to calculate the Braking Torque Induction, Driving Torque in Energy Meter formula refers to the force that rotates the meter's disc. It's generated by the interaction between magnetic fields produced by the voltage and current passing through the meter. Braking Torque Induction is denoted by T_b symbol.

How to calculate Driving Torque in Energy Meter using this online calculator? To use this online calculator for Driving Torque in Energy Meter, enter Spring Constant 1 Induction (K₁), Total Voltage Induction (V), Total Current Induction (I) & Phase Angle Induction (ϕ_i) and hit the calculate button. Here is how the Driving Torque in Energy Meter calculation can be explained with given input values -> -1349.209107 = 12*20*8*cos(1.02).

FAQ

What is Driving Torque in Energy Meter?

Driving Torque in Energy Meter formula refers to the force that rotates the meter's disc. It's generated by the interaction between magnetic fields produced by the voltage and current passing through the meter and is represented as T_b = K₁*V*I*cos(ϕ_i) or Braking Torque Induction = Spring Constant 1 Induction*Total Voltage Induction*Total Current Induction*cos(Phase Angle Induction). Spring Constant 1 Induction is a factor that links driving torque to power consumption, ensuring accurate measurement of electrical energy use, Total Voltage Induction is the sum of the voltage across the load and shunt coils, facilitating the measurement of power consumption by the energy meter, Total Current Induction is the sum of the load current passing through the current coil, creating a magnetic field that interacts with the voltage coil to measure power & Phase Angle Induction is the difference in timing between the peaks of voltage and current waveforms in an AC circuit, affecting power flow and efficiency.

How to calculate Driving Torque in Energy Meter?

Driving Torque in Energy Meter formula refers to the force that rotates the meter's disc. It's generated by the interaction between magnetic fields produced by the voltage and current passing through the meter is calculated using Braking Torque Induction = Spring Constant 1 Induction*Total Voltage Induction*Total Current Induction*cos(Phase Angle Induction). To calculate Driving Torque in Energy Meter, you need Spring Constant 1 Induction (K₁), Total Voltage Induction (V), Total Current Induction (I) & Phase Angle Induction (ϕ_i). With our tool, you need to enter the respective value for Spring Constant 1 Induction, Total Voltage Induction, Total Current Induction & Phase Angle Induction and hit the calculate button. You can also select the units (if any) for Input(s) and the Output as well.

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