Post on 23-Dec-2015
Development of Characteristic Equation for Thermometer
P M V SubbaraoProfessor
Mechanical Engineering Department
Clues for Design of a thermometer ….
Common Thermometers
(1) An element
(2) Bobbin
(3) Sheath
(4) Connecting wires
Liquid in Glass
Thermometer
Thermocouple Thermometer
Resistance Thermometer
Development of Characteristic Equation for a Thermometer
Conservation of Energy during a time dt
Heat in – heat out = Change in energy of thermometer
System theof eTemperatur ousInstantanetTs
tTs tTtf
fluid ric thermometof eTemperatur ousInstantanetTtf
Thermal Resistance of Thermometer Bulb
Rg
Rs Rg Rd
Ts(t) Ttf(t)
Thermometric fluidAssume no losses from the stem.
Heat in = Change in energy of thermometer
System heat transfer coefficients in W/m2K @ 20 °C
tfgs RRRU
1
dtTTUAinheat tfsbulb
Change in energy of thermometer: tftfbulb dTCV
tftfbulbtfsbulb TCVdtTTUA
sbulbtfbulbtf
tfbulb TUATUAdt
dTCV
Thermal Resistance of Thermometer Bulb
Rg
The energy balance for mercury in the bulb:
igbulbtftfbulbtftf
tfbulb TAhTAhdt
dTCV .
The energy balance for the glass wall has both inflow and outflow of heat:
)()( ,,,
tfigbulbtfogsbulbsavgg
gg TTAhTTAhdt
dTCm
)()( tfgbulbtfggsbulbgsg
gg TTAUTTAUdt
dTCm
gbulbtfgtfbulbtfgtf
tfbulb TAUTAUdt
dTCV
Substitution of relevant expressions and after manipulations we get:
stftftf DTCT
dt
dTB
dt
TdA
2
2
)()( tfgbulbtfggsbulbgsg
gg TTAUTTAUdt
dTCm
tftf
bulbtfg
tfbulbg T
dt
dT
AU
CVT
stfntf
ntf TT
dt
dT
dt
Td 2
2
2
2
stftf
bulb
tfbulb TTdt
dT
UA
CV
bulb
tfbulb
UA
CV Define Time constant
stftf TT
dt
dT
s
Tsss s
tftf
s
Tss s
tf 1 1ss
Ts s
tf
Step Response of Thermometers : First Order Model
1s
T
s
Ts ss
tf
1
s
T
s
Ts ss
tf
1
11
ss
Ts stf
1
111
ss
TtT stf
t
TtT stf exp1
t
TtT stf exp1
bulb
tfbulb
UA
CV
Step Response of Thermometers : First Order Model
stfntf
ntf TT
dt
dT
dt
Td 2
2
2
2
22
2
2 nn
nstf sss
TST
Transient response of Liquid-in-Glass Thermometer
0
2
4
6
8
10
0 100 200 300 400 500 600
Time, s
Tem
pera
ture
(in
devi
atio
n fo
rm),
C
Response of Thermometers: Periodic Loading
• If the input is a sine-wave, the output response is quite different;
• but again, it will be found that there is a general solution for all situations of this kind.
stftf
bulb
tfbulb TTdt
dT
UA
CV
22
max,max
s
stSinTT ssss
22
max,
ssss s
tftf
22
max,1
sss s
tf
122
max,
ss
s stf
122
max,1
sstT s
tf
t
tTe
TtT s
t
stf
1
22
max,
22max,
tan
sin11
Ts,
max
- T
tf,m
ax
Temperature: Standards & Insturuments
P M V SubbaraoProfessor
Mechanical Engineering Department
Selection of an Instrument for a Range….
International Practice
• The thermodynamic scale of temperature (or the absolute scale) was derived from the second law of thermodynamics.
• This scale is independent of any thermometric substance. • The unit for the absolute scale is K - Kelvin, named after Lord
Kelvin (William Thomson). • 1K= 1/273.16 th of the temperature at the triple point of water.• For practical purposes an International Practical Temperature
Scale, IPTS-68 (adopted in 1968) has been used for 22 years. • This scale was based on a number of fixed and easily
reproducible points. • Definite numerical values of temperature were assigned to these
points. • For interpolation purposes between the fixed points, specified
formulas relating temperature to the readings on certain temperature-measuring instruments were used.
NN Fixed points : ipts1968 Temperature, C
1. Triple point of equilibrium-hydrogen (s+l+v) -259.34
2. Boiling point of equilibrium hydrogen (l+v) at 33.33 kPa -256.108
3. Normal boiling point of equilibrium hydrogen at 101325 Pa
-252.87
4. Normal boiling point of neon -246.048
5. Triple point of oxygen -218.789
6. Normal boiling point of oxygen -182.962
7. Triple point of water 0.01
8. Normal boiling point of water 100
9. Normal freezing point of zinc (s+l) at 101325 Pa 419.58
10. Normal freezing point of silver (s+l) at 101325 Pa 961.93
11. Normal freezing point of gold (s+l) at 101325 Pa 1064.43
N Fixed points:its1990 Temperature, C
1. Normal boiling point of helium -270.15 to --268.15
2. Triple point of equilibrium-hydrogen (s+l+v) 259.3467
3. Boiling point of equilibrium hydrogen (l+v) at 33.33 kPa -256.15
4. Normal boiling point of equilibrium hydrogen at 101325 Pa -252.85
5. Triple point of neon -248.5939
6. Triple point of oxygen -218.7916
7. Triple point of argon -189.3442
8. Triple point of mercury -38.8344
9. Triple point of water 0.01
10. Melting point of gallium 29.7646
11. Normal freezing point of indium (s+l) at 101325 Pa 156.5985
12. Normal freezing point of tin (s+l) at 101325 Pa 231.928
13. Normal freezing point of zinc (s+l) at 101325 Pa 419.527
14. Normal freezing point of aluminium (s+l) at 101325 Pa 660.323
15. Normal freezing point of silver (s+l) at 101325 Pa 961.78
16. Normal freezing point of gold (s+l) at 101325 Pa 1064.18
17. Normal freezing point of copper (s+l) at 101325 Pa 1084.62
Accuracy Realization of Temperature Scale