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Electrical formula Equations, Exercises of Electrical Engineering

Universitas Padjadjaran (UP)Electrical Engineering

Electrical engineering For university

Typology: Exercises

2017/2018

Uploaded on 04/24/2018

hamam-prigel
hamam-prigel 🇮🇩

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www.emersonct.com
800-893-2321
Symbols & Formulae
Electrical Formulae
Electrical Quantities
Quantity Symbol Unit Name Unit Symbol
Electromotive force E, e* Volt V
Potential difference V, v* Volt V
Current I, i* Ampere A
Magnetic fl ux ΦWeber Weber
Frequency f Hertz Hz
Flux linkage λWeber-turns -
Resistance R Ohm Ω
Inductance L Henry H
Capacitance C Farad F
Impedance Z Ohm Ω
Reactance X Ohm Ω
Power,dc,or active P Watt W
Power, reactive Q Volt-ampere
reactive VAr, var
Power, total or
apparent S Volt-ampere VA
Power factor angle ϕ- °, deg.
Angular velocity ωRadians per
second rads-1
Rotational velocity n Revolutions
per second s-1 ,rev s-1
Revolutions
per minute min-1, rpm
Effi ciency η-
Number of pairs
of poles p-
* Capital and small letters designate rms and instantaneous value
respectively.
AC Single-Phase
All quantities r.m.s. values:
V = I Z
Total or apparent power in VA = Vl = I2Z = V2 Z
Active power in watts, W =Vl cos ϕ
Reactive power in VAr = Vl sin ϕ
AC Three-Phase
(Assuming Balanced Symmetrical Waveform)
All quantities r.m.s values:
Vl = Line-to-line voltage
Vp = Phase voltage (line-to-neutral)
Il = line current (wye)
Ip = Phase current (delta)
In a WYE connected circuit, Vp = Vl 3, Vl =3Vp, Il = Ip
In a DELTA connected circuit: Ip = Il 3, Il =3 Ip Vl =
Vp
Total of apparent power in VA = 3 Vl Il
Active power in watts,W = 3 Vl Il cos ϕ
Reactive power in VAr = 3 Vl Il sin ϕ
Power factor (pf) = cos ϕ
= Active power / Apparent power
= W / VAr
Three-Phase Induction Motors
All quantities rms values:
kWmech = horsepower x 0.746
kWelec = 3 Vl Il cos ϕ at rated speed and load
where Vl = supply voltage Il = rated full load current
cos ϕ = rated full load power factor
Effi ciency, η = (kWmech kWelec) x 100 per cent
Phase current Ip = Il for wye connection
Ip = Il 3 for delta connection
Loads (phase values)
Resistance R, measured in Ohms (no energy storage)
Inductive reactance, XL = ωL = 2π ƒL Ohms (stores en-
ergy)
Where ƒ = frequency (Hz), L = Inductance (H)
Capacitative reactance, XC = 1/(ωC) = 1/ (2πƒC)
Where ƒ = frequency (Hz), C = Capacitance (F)
Impedance
Impedance is the algebraic sum of the separate load
values thus:
Z = (R2 + XL
2) or (R2 + XC2)
If R, XL and XC are present in series in the same circuit
then XL and XC may be summated, treating XC as nega-
tive, thus
Z = (R2 + (XL - XC)2)
CTi Automation - Phone: 800.894.0412 - Fax: 208.368.0415 - Web: www.ctiautomation.net - Email: info@ctiautomation.net
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800-893-

Symbols & Formulae

Electrical Formulae

Electrical Quantities

Quantity Symbol Unit Name Unit Symbol

Electromotive force E, e* Volt V Potential difference V, v* Volt V Current I, i* Ampere A Magnetic fl ux Φ Weber Weber Frequency f Hertz Hz Flux linkage λ Weber-turns - Resistance R Ohm Ω Inductance L Henry H Capacitance C Farad F Impedance Z Ohm Ω Reactance X Ohm Ω Power,dc,or active P Watt W

Power, reactive Q Volt-amperereactive VAr, var

Power, total or apparent S^ Volt-ampere^ VA Power factor angle ϕ - °, deg.

Angular velocity ω Radians per second rads-

Rotational velocity n Revolutions per second s^

-1 (^) ,rev s-

Revolutions per minute min-1, rpm

Effi ciency η - Number of pairs of poles p^ - * Capital and small letters designate rms and instantaneous value respectively.

AC Single-Phase All quantities r.m.s. values: V = I Z Total or apparent power in VA = Vl = I^2 Z = V 2  Z Active power in watts, W = Vl cos ϕ Reactive power in VAr = Vl sin ϕ

AC Three-Phase (Assuming Balanced Symmetrical Waveform) All quantities r.m.s values: Vl = Line-to-line voltage Vp = Phase voltage (line-to-neutral) I (^) l = line current (wye) Ip = Phase current (delta) In a WYE connected circuit, V (^) p = V (^) l 3, V (^) l = 3 V (^) p , Il = Ip In a DELTA connected circuit: Ip = Il  3, I (^) l = 3 I (^) p Vl = Vp Total of apparent power in VA =  3 V (^) l Il Active power in watts,W =  3 Vl Il cos ϕ Reactive power in VAr =  3 Vl Il sin ϕ Power factor (pf) = cos ϕ = Active power / Apparent power = W / VAr

Three-Phase Induction Motors All quantities rms values: kWmech = horsepower x 0. kW elec =  3 Vl Il cos ϕ at rated speed and load where V (^) l = supply voltage Il = rated full load current cos ϕ = rated full load power factor

Effi ciency, η = (kWmech  kW elec) x 100 per cent Phase current I (^) p = I (^) l for wye connection I (^) p = I (^) l  3 for delta connection

Loads (phase values) Resistance R, measured in Ohms (no energy storage) Inductive reactance, XL = ω L = 2π ƒ L Ohms (stores en- ergy) Where ƒ = frequency (Hz), L = Inductance (H) Capacitative reactance, XC = 1/(ω C ) = 1/(2πƒ C ) Where ƒ = frequency (Hz), C = Capacitance ( F )

Impedance Impedance is the algebraic sum of the separate load values thus:

Z = (R^2 + X L^2 ) or (R^2 + X C^2 )

If R, X (^) L and XC are present in series in the same circuit then X (^) L and XC may be summated, treating XC as nega- tive, thus

Z = (R^2 + (X L - X C )^2 )

CTi Automation - Phone: 800.894.0412 - Fax: 208.368.0415 - Web: www.ctiautomation.net - Email: info@ctiautomation.net

400

www.emersonct.com

800-893-

Symbols & Formulae

Electrical Formulae

Ohms Law

Amperes = Volts^ or Ohms = Volts Ohms Amperes or Volts = Amperes x Ohms

Power in DC Circuits

Horsepower = Volts x Amperes 746 Watts = Volts x Amperes

Kilowatts = Volts x Amperes 1,

Kilowatts-Hours = Volts x Amperes x Hours 1, Power in AC Circuits Kilovolt-Amperes (KVA):

kVA (1Ø) = Volts x Amperes 1,

kVA (3Ø) = Volts x Amperes x 1. 1,

Kilowatts (Kw)

kW (1Ø) = Volts x Amperes x Power Factor 1,

kW (3Ø) = Volts x Amperes x Power Factor x 1. 1,

Power Factor = Kilowatts Kilovolts x Amperes

Other Useful Formulae

Three-Phase (3Ø) Circuits

HP = E x^ I^ x^3 x Eff x PF

Motor Amps = HP x 746 E x 3 x Eff x PF

Motor Amps = kVA x 1000 3 x E

Motor Amps = kW x 1000 3 x E x PF

Power Factor = kW x 1000

E x I x 3

Kilowatt Hours = E x^ I^ x Hours x^ 3 x PF

Power (Watts) = E x I x 3 x PF

Material Densities Materials lb/in3^ gm/cm Aluminum 0.096 2. Brass 0.299 8. Bronze 0.295 8. Copper 0.322 8. Hard Wood 0.029 0. Soft Wood 0.018 0. Plastic 0.04 1. Glass 0.079-0.090 2.2-2. Titanium 0.163 4. Paper 0.025-0.043 0.7-1. Polyvinyl chloride 0.047-0.050 1.3-1. Rubber 0.033-0.036 0.92-0. Silicone Rubber, without fi ller

Cast Iron, gray 0.274 7. Steel 0.28 7.

Friction Coefficients Ffr=μWL Materials μ Steel on Steel (greased) ~0. Plastic on Steel ~0.15-0. Copper on Steel ~0. Brass on Steel ~0. Aluminum on Steel ~0. Steel on Steel ~0. Mechanism μ Ball Bushings <0. Linear Bearings <0. Dove-tail Slides ~0.2++ Gibb Ways ~0.5++

Mechanism Efficiencies Acme screw with brass nut ~0.35-0. Acme screw with plastic nut ~0.50-0. Ballscrew ~0.85-0. Chain and Sprocket ~0.95-0. Preloaded Ballscrew ~0.75-0. Spur or Bevel gears ~0. Timing Belts ~0.96-0. Worm Gears ~0.45-0. Helical Gear (1 reduction) ~0.

Mechanical Variables

CTi Automation - Phone: 800.894.0412 - Fax: 208.368.0415 - Web: www.ctiautomation.net - Email: info@ctiautomation.net