Total iron loss in Specimen Solution

STEP 0: Pre-Calculation Summary
Formula Used
Specimen Total Iron Loss = (Voltage Induced in S1*Voltage Induced in S2)/Potential Difference
W = (S1*S2)/V
This formula uses 4 Variables
Variables Used
Specimen Total Iron Loss - (Measured in Watt) - Specimen Total Iron Loss is defined as energy dissipated in the transformer's core due to the alternating magnetic flux.
Voltage Induced in S1 - (Measured in Volt) - Voltage Induced in S1 is the potential difference across it by either passing it through a magnetic field, or by moving the magnetic field past the conductor.
Voltage Induced in S2 - (Measured in Volt) - Voltage Induced in S2 is the potential difference across it generated by either passing it through a magnetic field, or by moving the magnetic field past the conductor.
Potential Difference - (Measured in Volt) - Potential Difference is the external work needed to bring a charge from one location to another location in an electric field.
STEP 1: Convert Input(s) to Base Unit
Voltage Induced in S1: 8 Volt --> 8 Volt No Conversion Required
Voltage Induced in S2: 5.1 Volt --> 5.1 Volt No Conversion Required
Potential Difference: 15.17647 Volt --> 15.17647 Volt No Conversion Required
STEP 2: Evaluate Formula
Substituting Input Values in Formula
W = (S1*S2)/V --> (8*5.1)/15.17647
Evaluating ... ...
W = 2.68837219722373
STEP 3: Convert Result to Output's Unit
2.68837219722373 Watt --> No Conversion Required
FINAL ANSWER
2.68837219722373 โ‰ˆ 2.688372 Watt <-- Specimen Total Iron Loss
(Calculation completed in 00.004 seconds)

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25 Instrument Dimensions Calculators

Spacing between Electrode
Go Electrode Spacing = (Parallel Plate Relative Permeability*(Electrode Effective Area*[Permitivity-vacuum]))/(Specimen Capacitance)
Hall Coefficient
Go Hall Coefficient = (Output Voltage*Thickness)/(Electric Current*Maximum Flux Density)
Length of Former
Go Former Length = Former EMF/(2*Magnetic Field*Former Breadth*Former Angular Speed)
Reluctance of Yoke's
Go Yokes Reluctance = (Magnetic Moment*Magnetic Circuits Reluctance)-Joints Reluctance
Reluctance of Joints
Go Joints Reluctance = (Magnetic Moment*Magnetic Circuits Reluctance)-Yokes Reluctance
True Magnetising Force
Go True Magnetism Force = Apparent Magnetic Force at length l+Apparent Magnetic Force at Length l/2
Length of Solenoid
Go Solenoid Length = Electric Current*Coil Turns/Magnetic Field
Apparent Magnetic Force at length l
Go Apparent Magnetic Force at length l = Coil Current at Length l*Coil Turns
Extention of Specimen
Go Specimen Extension = Magnetostriction Constant MMI*Specimen Actual Length
Hysteresis loss per unit volume
Go Hysteresis Loss per Unit Volume = Area of the hysteresis loop*Frequency
Area of Secondary Coil
Go Secondary Coil Area = Secondary Coil Flix Linkage/Magnetic Field
Linear velocity of Former
Go Former Linear Velocity = (Former Breadth/2)*Former Angular Speed
Area of hysteresis loop
Go Hysteresis Loop Area = Hysteresis Loss per Unit Volume/Frequency
Responsivity of Detector
Go Detector Responsivity = RMS Voltage/Detector RMS Incident Power
Standard Deviation for Normal Curve
Go Normal Curve Standard Deviation = 1/sqrt(Sharpness Of Curve)
Leakage Factor
Go Leakage Factor = Total Flux Per Pole/Armature Flux per Pole
Area of Cross-section of Specimen
Go Area of Cross Section = Maximum Flux Density/Magnetic Flux
Instrumentation Span
Go Instrumentation Span = Largest Reading-Smallest Reading
Damping Constant
Go Damping Constant = Damping Torque*Disc Angular Speed
Damping Torque
Go Damping Torque = Damping Constant/Disc Angular Speed
Primary Phasor
Go Primary Phasor = Transformer Ratio*Secondary Phasor
Revolution in KWh
Go Revolution = Number of Revolution/Energy Recorded
Energy Recorded
Go Energy Recorded = Number of Revolution/Revolution
Sharpness of Curve
Go Sharpness Of Curve = 1/((Normal Curve Standard Deviation)^2)
Coefficient of volumetric Expansion
Go Volumetric Expansion Coefficient = 1/Capillary Tube Length

Total iron loss in Specimen Formula

Specimen Total Iron Loss = (Voltage Induced in S1*Voltage Induced in S2)/Potential Difference
W = (S1*S2)/V

What is Zero speed?

In some types of equipment, a speed below a threshold value but close to zero is referred to as zero speed.

How to Calculate Total iron loss in Specimen?

Total iron loss in Specimen calculator uses Specimen Total Iron Loss = (Voltage Induced in S1*Voltage Induced in S2)/Potential Difference to calculate the Specimen Total Iron Loss, The Total iron loss in Specimen formula is defined as loss that is caused due to alternating flux in core of transformer. As loss occurs in core, therefore iron loss is also known as core loss. There are two types of iron losses, and they are eddy current loss and hysteresis loss. Specimen Total Iron Loss is denoted by W symbol.

How to calculate Total iron loss in Specimen using this online calculator? To use this online calculator for Total iron loss in Specimen, enter Voltage Induced in S1 (S1), Voltage Induced in S2 (S2) & Potential Difference (V) and hit the calculate button. Here is how the Total iron loss in Specimen calculation can be explained with given input values -> 2.688372 = (8*5.1)/15.17647.

FAQ

What is Total iron loss in Specimen?
The Total iron loss in Specimen formula is defined as loss that is caused due to alternating flux in core of transformer. As loss occurs in core, therefore iron loss is also known as core loss. There are two types of iron losses, and they are eddy current loss and hysteresis loss and is represented as W = (S1*S2)/V or Specimen Total Iron Loss = (Voltage Induced in S1*Voltage Induced in S2)/Potential Difference. Voltage Induced in S1 is the potential difference across it by either passing it through a magnetic field, or by moving the magnetic field past the conductor, Voltage Induced in S2 is the potential difference across it generated by either passing it through a magnetic field, or by moving the magnetic field past the conductor & Potential Difference is the external work needed to bring a charge from one location to another location in an electric field.
How to calculate Total iron loss in Specimen?
The Total iron loss in Specimen formula is defined as loss that is caused due to alternating flux in core of transformer. As loss occurs in core, therefore iron loss is also known as core loss. There are two types of iron losses, and they are eddy current loss and hysteresis loss is calculated using Specimen Total Iron Loss = (Voltage Induced in S1*Voltage Induced in S2)/Potential Difference. To calculate Total iron loss in Specimen, you need Voltage Induced in S1 (S1), Voltage Induced in S2 (S2) & Potential Difference (V). With our tool, you need to enter the respective value for Voltage Induced in S1, Voltage Induced in S2 & Potential Difference 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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