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Driving Torque in Energy Meter Formula

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Braking Torque is the retarding force generated by eddy currents opposing the disc's motion, ensuring accurate measurement by balancing the driving torque. Check FAQs

T b = K 1 \cdot V \cdot I \cdot \cos (ϕ i)

T_b - Braking Torque?K₁ - Spring Constant 1 in Induction?V - Total Voltage?I - Total Current in Induction?ϕ_i - Phase Angle?

Driving Torque in Energy Meter Example

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Here is how the Driving Torque in Energy Meter equation looks like with Values.

Here is how the Driving Torque in Energy Meter equation looks like with Units.

Here is how the Driving Torque in Energy Meter equation looks like.

25.4017 = 1.2 \cdot 20 \cdot 1.99 \cdot \cos (1.01)

25.4017N*m = 1.2Nm/rad \cdot 20V \cdot 1.99A \cdot \cos (1.01rad)

25.4017 = 1.2 \cdot 20 \cdot 1.99 \cdot \cos (1.01)

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Driving Torque in Energy Meter Solution

Follow our step by step solution on how to calculate Driving Torque in Energy Meter?

FIRST Step Consider the formula

T b = K 1 \cdot V \cdot I \cdot \cos (ϕ i)

Next Step Substitute values of Variables

∴

T b = 1.2Nm/rad \cdot 20V \cdot 1.99A \cdot \cos (1.01rad)

Next Step Prepare to Evaluate

∴

T b = 1.2 \cdot 20 \cdot 1.99 \cdot \cos (1.01)

Next Step Evaluate

∴

T b = 25.4016680528392N*m

LAST Step Rounding Answer

∴

T b = 25.4017N*m

Driving Torque in Energy Meter Formula Elements

Variables

Functions

Braking Torque

Braking Torque is the retarding force generated by eddy currents opposing the disc's motion, ensuring accurate measurement by balancing the driving torque.

Symbol: T_b

Measurement: TorqueUnit: N*m

Note: Value should be greater than 0.

Formulas to find Braking Torque

Spring Constant 1 in Induction

Spring Constant 1 in Induction is a factor that links driving torque to power consumption, ensuring accurate measurement of electrical energy use.

Symbol: K₁

Measurement: Torsion ConstantUnit: Nm/rad

Note: Value should be greater than 0.

Formulas to find Spring Constant 1 in Induction

Total Voltage

Total Voltage is the sum of the voltage across the load and shunt coils, facilitating the measurement of power consumption by the energy meter.

Symbol: V

Measurement: Electric PotentialUnit: V

Note: Value should be greater than 0.

Formulas to find Total Voltage

Total Current in Induction

Total Current in 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.

Symbol: I

Measurement: Electric CurrentUnit: A

Note: Value should be greater than 0.

Formulas to find Total Current in Induction

Phase Angle

Phase Angle is the difference in timing between the peaks of voltage and current waveforms in an AC circuit, affecting power flow and efficiency.

Symbol: ϕ_i

Measurement: AngleUnit: rad

Note: Value should be greater than 0.

Formulas to find Phase Angle

cos

Cosine of an angle is the ratio of the side adjacent to the angle to the hypotenuse of the triangle.

Syntax: cos(Angle)

Other formulas in Induction Type category

Go Driving Torque Induction

T D = K 2 \cdot N i

How to Evaluate Driving Torque in Energy Meter?

Driving Torque in Energy Meter evaluator uses Braking Torque = Spring Constant 1 in Induction*Total Voltage*Total Current in Induction*cos(Phase Angle) to evaluate the Braking Torque, 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 is denoted by T_b symbol.

How to evaluate Driving Torque in Energy Meter using this online evaluator? To use this online evaluator for Driving Torque in Energy Meter, enter Spring Constant 1 in Induction (K₁), Total Voltage (V), Total Current in Induction (I) & Phase Angle (ϕ_i) and hit the calculate button.

FAQs on Driving Torque in Energy Meter

What is the formula to find Driving Torque in Energy Meter?

The formula of Driving Torque in Energy Meter is expressed as Braking Torque = Spring Constant 1 in Induction*Total Voltage*Total Current in Induction*cos(Phase Angle). Here is an example- 24.99596 = 1.2*20*1.99*cos(1.01).

How to calculate Driving Torque in Energy Meter?

With Spring Constant 1 in Induction (K₁), Total Voltage (V), Total Current in Induction (I) & Phase Angle (ϕ_i) we can find Driving Torque in Energy Meter using the formula - Braking Torque = Spring Constant 1 in Induction*Total Voltage*Total Current in Induction*cos(Phase Angle). This formula also uses Cosine (cos) function(s).

Can the Driving Torque in Energy Meter be negative?

No, the Driving Torque in Energy Meter, measured in Torque cannot be negative.

Which unit is used to measure Driving Torque in Energy Meter?

Driving Torque in Energy Meter is usually measured using the Newton Meter[N*m] for Torque. Newton Centimeter[N*m], Newton Millimeter[N*m], Kilonewton Meter[N*m] are the few other units in which Driving Torque in Energy Meter can be measured.

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Driving Torque in Energy Meter Formula

Driving Torque in Energy Meter Example

Driving Torque in Energy Meter Solution

Driving Torque in Energy Meter Formula Elements

Other formulas in Induction Type category

How to Evaluate Driving Torque in Energy Meter?

FAQs on Driving Torque in Energy Meter

Variable Name