02 BOPs / Woods D.R 2008 rules-of-thumb-in-Engineering-practice (epdf.tips)

Thermal conductivity

watts per square meter per degree Kelvin

cal/(s.cm.hC)

q 418.68

= W/(m.K)

per meter: W/(m2.K/m) a W/(m.K)

kcal/(h.m.hC)

q 1.163

= W/(m.K)

BTU/(h.ft hF)

q 1.7308

= W/(m.K)

thermal conductivity of

BTU/(h.ft2.hF/in)

q 0.1442

= W/(m.K)

liquid water:

0.6 W/(m.K)

gas:

20 mW/(m.K)

Volumetric heat transfer coefficient

watts per cubic meter per degree Kelvin:

CHU/(h.ft3.hC)

q 18.63

= W/(m3.K)

W/(m3.K)

BTU/(h.ft3.hF)

q 18.63

= W/(m3.K)

Coulomb, C

statcoulomb

q 0.3336

= nC

large value

1 C

abcoulomb

q 10

= C

medium value

100 mC

faraday

small value

50 pC

(based on C12)

q 96.487

= kC

electrostatic charge on

(chemical)

q 96.4957

= kC

a person:

100 nC

(physical)

q 96.5219

= kC

charge on an electron:

0.16 aC

amp<re-hr

q 3600

= C

charge transfer in/out

digital CMOS transistor:

10 pC

charge on 1000 mF

capacitor at 10 V

10 mC

Conversions for charge per unit area, dimensions: IT/L2

Surface charge density, electric derived field or displacement, dielectric polarization

Coulomb per square meter, C/m2

statcoulomb/cm2

q 3.336

= mC/m2

abcoulomb/cm2

q 0.1

= MC/m2

clay particles in water 40 mC/m2

statvolt/cm

q 0.2653

= mC/m2

small charge

mC/m2

abvolt/cm

q 7.96

= kC/m2

dielectric capacitors:

mC/m2

on control electrode

in CMOS device:

mC/m2

Volumetric charge density.

Coulomb per cubic meter, C/m3

statcoulomb/cm3

q 0.3336

= mC/m3

abcoulomb/cm3

q 10

= MC/m3

conduction electric charge.

in metal conductors:

16 GC/m3

in n-type semiconductors:

1.6 kC/m3

Current

Amp<re: A

statamp

q 0.33356

= nA

abamp

q 10

= A

start a 0.25 kW motor

13

A

esu current

q 0.3336

= nA

electric kettle

13

A

emu current

q 10

= A

refine alumina

10

kA

amp-turn

q 10

= A

usual current in low power junction

gilbert

q 0.7958

= A

type semiconductor

10 mA to 10 mA

usual control electrode or OFF

current in CMOS devices:

pA to nA

Magnetism, magnetic derived strength, magnetic intensity

Amp<re per meter, A/m

esu

q 2.653

= nA/m

gauss

q 79.577

= A/m

for iron

1 kA/m

oersted

q 79.577

= A/m

abamp<re-turn/cm

q 1

= kA/m

amp-turn/cm

q 100

= A/m

amp-turn/in

q 39.37

= A/m

praoerstead

q 4 p

= A/m

Appendix A: Units and Conversion of Units

353

Conversions for charge flowrate per unit area, dimensions: I/L2

Current density, current per unit area, charge flux

amp<re per square meter, A/m2

statamp/cm2

q 3.336

= mA/m2

abamp/cm2

q 100

= kA/m2

electroplating or electrorefining:

10 to 2000 A/m2

amp/ft2

q 10.87

= A/m2

semiconductor junction:

10 MA/m2

solar cell:

400 A/m2

Conversions for electric potential, dimensions: ML2/IT3

Electromotive force

Volt, V = J/A.s

statvolt

q 299.79

= V

Power transmission lines:

250 kV, 500 kV

esu electric pot.

q 299.79

= V

household circuits:

abvolt

q 10

= nV

North American

110 V(rms)

emu electric pot.

q 0.01

= mV

European & Asian

240 V (rms)

International

clay particles suspended in water:

80 mV

(1948) volt

q 1.000330

= V

magnetic phono cartridge

signal output level:

5 mV

muscle (EMG) cell potential:

1 mV

electrostatic potential

on human body:

1 kV

accelerating voltage

in TV picture tube:

30 kV

Conversions for electric potential per unit length, dimensions: ML/IT3

Potential gradient

Volt per meter, V/m = J/(m.A.s)

statvolt/cm

q 29.979

= kV/m

abvolt/cm

q 1

= mV/m

breakdown occurs in air:

2 MV/m

breakdown of semiconductors:

20 MV/m

radiated field near a transformer:

1 mV/m

Ohm, V = V/A

statohm

q 898.76

= GV

esu resistance

q 898.76

= GV

leakage resistance of

abohm

q 1

= nV

small telflon stand-off:

1014 V

emu resistance

q 1

= nV

coaxial cable:

1011 V

Gaussian cgs

q 898.76

= GV

finger to finger resistance

s/cm

q 898.76

= GV

potential:

50 kV

International

integrated circuit diffused

(1948) ohm

q 1.000495

= V

resistors:

I10 kV

Conversions for resistance per unit length, dimensions: ML/I2T3

Resistivity

Ohm-meter, V.m

statohm.cm

q 8.9876

= GV.m

esu resistance

q 8.9876

= GV.m

steel

620 nV.m

abohm.cm

q 10

= pV.m

copper

17 nV.m

emu resistance

q 10

= pV.m

nichrome

1000 nV.m

microohm-cm

q 10

= nV.m

semiconductors

1 mV.m to 5 kV.m

ohm-cm

q 0.01

= V.m

insulators

10 kV.m to 104 GV.m

ohm-circular

mil per ft

q 1.662

= nV.m

Conversions for conductance, dimensions: I2T3/ML2

Electrical conductivity

Siemen, S = A/V

statmho

q 1.113

= pS

abmho

q 1

= GS

Conversions for conductance per unit length, dimensions: I2T3/ML3

Specific conductivity, length conductivity

Siemen per meter, S/m

statmho/cm

q 0.1113

= nS/m

liquid solutions

1 mS/m

abmho/cm

q 10

= TS/m

Volume conductivity

Siemens per cubic meter, S/m3

statmho/cm3

q 1.113

= mS/m3

abmho/cm3

q 1000

= TS/m3

Conversions for capacitance, dimensions: I2T4/ML2

Farad, F = C/V

statfarad

q 1.113

= pF

large capacitances to correct power factor

esu capacitance

q 1.113

= pF

100 mF

abfarad

q 1

= GF

DC power supplies, rectification

emu capacitance

q 1

= GF

10 mF

Gaussian-cm

q 1.113

= pF

audio amplifier bypass

International

50 mF

(1948) farad

q 0.999505

= F

radio frequency bypass

1 nF

rationalized unit

emu/cm3

q 4 p

= rationalized unit

Conversions for magnetic mass susceptibility, dimensions: L3/M

cubic meters per kilogram, m3/kg

emu/g

q 4 pE-3

= m3/kg

cm3/g

q 4 pE-3

= m3/kg

Weber, Wb = V.s

esu line

q 0.2998

= kWb

maxwell

q 0.01

= mWb

iron core magnet for HiFi speaker

Gauss-cm2

q 0.01

= mWb

1 mWb

Maxwell

q 10

= nWb

unit pole

q 0.12566

= mWb

kiloline

q 10

= mWb

Conversions for magnetic flux density, dimensions: M/IT2

Magnetic induction, magnetic force vector

Tesla, T = Wb/m2

esu

q 0.2998

= MT

gauss

q 0.10

= mT

iron core magnet

1 T

gamma

q 1

= nT

air core magnet

1 mT

kiloline/in2

q 15.5

= mT

magnetic deflecting yoke of TV

A/m

q 4 pE-7

= T

picture tube provides field of

2 mT

q 0.4 p

= mT

earth’s magnetic field

0.1 mT

strong bar magnet

0.2 T

Conversions for inductance, dimensions: ML2/I2T2

Henry, H = Wb/A

stathenry

q 0.8988

= TH

5 cm length of 1 mm

esu inductance

q 0.8988

= TH

diameter wire

10 nH

Gaussian esu

q 0.8988

= TH

for very high radio

abhenry

q 1

= nH

frequencies

mH

emu inductance

q 1

= nH

usual radio

International

frequencies

mH to mH

(1948) henry

q 1.000495

= H

audio frequencies

H

iron core electromagnet at a

scrap yard:

10 H

small transformer with multiturns of

very fine wire:

5000 H

candela per square meter, cd/m2

candle/ft2

q 10.764

= cd/m2

candle/in2

q 1.55

= kcd/m2

ft-lambert

q 3.426

= cd/m2

lux = lumens per square meter, ‘m/m2

ft candle

q 10.76391

= ‘m/m2

second, s

minute

q 60

= s

h

q 3600

= s

day

q 86400

= s

a

q 31.55

= Ms

electrical circuit

60 Hz

audio frequency

kHz

radio frequency

MHz

rotational speed, angular velocity

radians per second, 1/s

r/min

q 2p/60

= rad/s

revolution per minute is commonly used

rad/s

q 60/2p

= r/min

and is accepted by the supplementary

practice guide 1978.

rpm for motors

nominal 1800 r/min

(1750 r/min actual)

radian, rad

degree

q 0.01745

= rad

circle

= 2p rad

minute (angle)

q 2.9088E-4

= rad

second (angle)

q 4.848E-6

= rad

air

23 % O2; 76.8 % N2 w/w

p

3.1416

21 % O2; 79 % N2 v/v

e

2.7183

Avogardo’s number,

6.02217

E23 particles/mol

molar volume

22.4 L at 0 hC and

Ideal gas constant,

8.3143

J/mol.K

101.325 kPa

8.3143

Pa.m3/mol.K

std. atmosphere

101.325 kPa

Boltzman constant, k

1.38 E-23 J/K

std. gravity

Faraday’s constant

9.6487

E4 C/equivalent

acceleration

9.80665 m/s2

charge on an electron

1.60219

E-19 C

velocity of sound in

velocity of light, c

2.997925 E8 m/s

dry air at 0 hC

331.5 m/s

mass of an electron

9.10956

E-31 kg

mass density of water at 4 hC

mass of a proton

1.67239

E-27 kg

0.999973 Mg/m3

mass of a neutron

1.6747

E-27 kg

temperature at absolute zero