Thermodynamics I Lecture 1 PDF

Summary

This document is a thermodynamics lecture covering the fundamental concepts of Thermodynamics including laws, and processes. The document defines entropy, and introduces thermodynamics systems and properties.

Full Transcript

Thermodynamics I lecture 1 Dr. Yasmeen H.Abed

Chapter one
1-1 Introduction
Thermodynamics: the science that deals with heat and work and those properties
of matter that relate to heat and work.
Its study of the relationship between work, heat, and energy.
Deals with the conversion of energy from one form to another.
Deals with the interaction of a system and it surroundings..‫ ھﻮ اﻟﻌﻠﻢ اﻟﺬي ﯾﺘﻌﺎﻣﻞ ﻣﻊ اﻟﺤﺮارة واﻟﺸﻐﻞ وﺧﺼﺎﺋﺺ اﻟﻤﺎدة اﻟﺘﻲ ﺗﺘﻌﻠﻖ ﺑﺎﻟﺤﺮارة واﻟﺸﻐﻞ‬: ‫اﻟﺪﯾﻨﺎﻣﯿﻜﺎ اﻟﺤﺮارﯾﺔ‬.‫ دراﺳﺘﮫ ﻟﻠﻌﻼﻗﺔ ﺑﯿﻦ اﻟﺸﻐﻞ واﻟﺤﺮارة واﻟﻄﺎﻗﺔ‬.‫ ﯾﺘﻌﺎﻣﻞ ﻣﻊ ﺗﺤﻮﯾﻞ اﻟﻄﺎﻗﺔ ﻣﻦ ﺷﻜﻞ إﻟﻰ آﺧﺮ‬.‫ ﯾﺘﻌﺎﻣﻞ ﻣﻊ ﺗﻔﺎﻋﻞ اﻟﻨﻈﺎم وﻣﺤﯿﻄﮫ‬

Engineers concerned with power generating machinery should have a working
knowledge of all matters dealing with the conversion of heat energy into work or
power. The laws based on experimental results obtained from the study of gases and
vapours are useful in the design of boilers, steam engines, steam turbines, internal
combustion engines, gas turbines, refrigerating machines and air compressors. In
the present days of industrialization, demand for energy is increasing rapidly. It is,
therefore, necessary to design and operate thermal plants and machines at their
highest level of performance for efficient utilization of fuels and natural resources
available.
‫ﯾﺠﺐ أن ﯾﻜﻮن ﻟﺪى اﻟﻤﮭﻨﺪﺳﯿﻦ اﻟﻤﮭﺘﻤﯿﻦ ﺑﺂﻻت ﺗﻮﻟﯿﺪ اﻟﻄﺎﻗﺔ ﻣﻌﺮﻓﺔ ﻋﻤﻠﯿﺔ ﺑﺠﻤﯿﻊ اﻷﻣﻮر اﻟﻤﺘﻌﻠﻘﺔ ﺑﺘﺤﻮﯾﻞ‬
‫ اﻟﻘﻮاﻧﯿﻦ اﻟﻤﺴﺘﻨﺪة إﻟﻰ اﻟﻨﺘﺎﺋﺞ اﻟﺘﺠﺮﯾﺒﯿﺔ اﻟﺘﻲ ﺗﻢ اﻟﺤﺼﻮل ﻋﻠﯿﮭﺎ ﻣﻦ دراﺳﺔ‬.‫اﻟﻄﺎﻗﺔ اﻟﺤﺮارﯾﺔ إﻟﻰ ﻋﻤﻞ أو طﺎﻗﺔ‬
‫اﻟﻐﺎزات واﻷﺑﺨﺮة ﻣﻔﯿﺪة ﻓﻲ ﺗﺼﻤﯿﻢ اﻟﻐﻼﯾﺎت واﻟﻤﺤﺮﻛﺎت اﻟﺒﺨﺎرﯾﺔ واﻟﺘﻮرﺑﯿﻨﺎت اﻟﺒﺨﺎرﯾﺔ وﻣﺤﺮﻛﺎت اﻻﺣﺘﺮاق‬
‫ ﯾﺘﺰاﯾﺪ اﻟﻄﻠﺐ ﻋﻠﻰ‬، ‫ ﻓﻲ أﯾﺎم اﻟﺘﺼﻨﯿﻊ اﻟﺤﺎﻟﯿﺔ‬.‫اﻟﺪاﺧﻠﻲ واﻟﺘﻮرﺑﯿﻨﺎت اﻟﻐﺎزﯾﺔ وآﻻت اﻟﺘﺒﺮﯾﺪ وﺿﻮاﻏﻂ اﻟﮭﻮاء‬
‫ ﻣﻦ اﻟﻀﺮوري ﺗﺼﻤﯿﻢ وﺗﺸﻐﯿﻞ اﻟﻤﺤﻄﺎت واﻵﻻت اﻟﺤﺮارﯾﺔ ﺑﺄﻋﻠﻰ ﻣﺴﺘﻮى ﻣﻦ اﻷداء‬، ‫ ﻟﺬﻟﻚ‬.‫اﻟﻄﺎﻗﺔ ﺑﺴﺮﻋﺔ‬.‫ﻣﻦ أﺟﻞ اﻻﺳﺘﺨﺪام اﻟﻔﻌﺎل ﻟﻠﻮﻗﻮد واﻟﻤﻮارد اﻟﻄﺒﯿﻌﯿﺔ اﻟﻤﺘﺎﺣﺔ‬

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Thermodynamics I lecture 1 Dr. Yasmeen H.Abed

1-2 The thermodynamics laws are:
0th Law ⇒ Defines Temperature (T)
1st Law ⇒ Defines Energy (U)
2nd Law ⇒ Defines Entropy (S)
3rd Law ⇒ Gives Numerical Value to Entropy

Zeroth law of thermodynamics: states that if two thermodynamic systems are each
in thermal equilibrium with a third system, then they are in thermal equilibrium with
each other.
،‫ﯾﻧص اﻟﻘﺎﻧون اﻟﺻﻔري ﻟﻠدﯾﻧﺎﻣﯾﻛﺎ اﻟﺣرارﯾﺔ أﻧﮫ إذا ﺗواﺟد ﺟﺳﻣﺎن ﻓﻲ ﺣﺎﻟﺔ ﺗوازن ﺣراري ﻣﻊ ﺟﺳم ﺛﺎﻟث‬
‫ وﯾﺛﺑت اﻟﻘﺎﻧون اﻟﺻﻔري أن درﺟﺔ اﻟﺣرارة ھﻲ ﺧﺎﺻﯾﺔ أﺳﺎﺳﯾﺔ ﻟﻠﻣﺎدة‬،‫ﻓﮭﻣﺎ أﯾﺿًﺎ ﻓﻲ ﺣﺎﻟﺔ ﺗوازن ﻣﻊ ﺑﻌﺿﮭﻣﺎ‬.‫وھﻲ ﻗﺎﺑﻠﺔ ﻟﻠﻘﯾﺎس‬

T A = TB , TA=TC so TB=TC

First law of thermodynamics: one of the most fundamental laws of nature is the
conservation of energy principle. It simply states that during an interaction, energy
can change from one form to another but the total amount of energy remains
constant.
‫ إﻧﮫ ﯾﻨﺺ ﺑﺒﺴﺎطﺔ‬.‫ أﺣﺪ أھﻢ ﻗﻮاﻧﯿﻦ اﻟﻄﺒﯿﻌﺔ وھﻮ ﻣﺒﺪأ اﻟﺤﻔﺎظ ﻋﻠﻰ اﻟﻄﺎﻗﺔ‬:‫اﻟﻘﺎﻧﻮن اﻷول ﻟﻠﺪﯾﻨﺎﻣﯿﻜﺎ اﻟﺤﺮارﯾﺔ‬.‫ ﯾﻤﻜﻦ أن ﺗﺘﻐﯿﺮ اﻟﻄﺎﻗﺔ ﻣﻦ ﺷﻜﻞ إﻟﻰ آﺧﺮ ﻟﻜﻦ اﻟﻜﻤﯿﺔ اﻹﺟﻤﺎﻟﯿﺔ ﻟﻠﻄﺎﻗﺔ ﺗﻈﻞ ﺛﺎﺑﺘﺔ‬، ‫ﻋﻠﻰ أﻧﮫ أﺛﻨﺎء اﻟﺘﻔﺎﻋﻞ‬

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‫‪Thermodynamics I‬‬ ‫‪lecture 1‬‬ ‫‪Dr. Yasmeen H.Abed‬‬

‫‪Second law of thermodynamics: energy has quality as well as quantity, and actual‬‬
‫‪processes occur in the direction of decreasing quality of energy. The second law of‬‬
‫‪thermodynamics introduces a new property called entropy, S.‬‬
‫‪Entropy is a measure of the randomness of the system or it is the measure of‬‬
‫‪energy or chaos within an isolated system. It can be considered as a quantitative‬‬
‫‪index that describes the quality of energy.‬‬

‫اﻟﻘﺎﻧﻮن اﻟﺜﺎﻧﻲ ﻟﻠﺪﯾﻨﺎﻣﯿﻜﺎ اﻟﺤﺮارﯾﺔ ھﻮﻋﺪم إﻣﻜﺎﻧﯿﺔ اﻧﺘﻘﺎل اﻟﺤﺮارة ﻣﻦ ﺟﺴﻢ ﺑﺎرد اﻟﻰ ﺟﺴﻢ ﺳﺎﺧﻦ وﻟﻜﻦ اﻟﻌﻜﺲ‬
‫ھﻮ اﻟﺼﺤﯿﺢ‪ ،‬ﻓﺎﻟﺤﺮارة ﺗﻨﺘﻘﻞ ﻣﻦ اﻟﺠﺴﻢ اﻟﺴﺎﺧﻦ اﻟﻰ اﻟﺠﺴﻢ اﻟﺒﺎرد‪.‬واﻟﻄﺎﻗﺔ اﻟﻤﻮﺟﻮدة ﻓﻲ ﻧﻈﺎم ﻣﻌﺰول ﺗﻨﺘﺸﺮ‬
‫وﺗﺘﻮزع ﻓﯿﮫ ﺑﺎﻟﺘﺴﺎوي ﻣﻊ ﻣﺮور اﻟﺰﻣﻦ‪.‬‬
‫وﻟﺬﻟﻚ اﻧﺘﺸﺎر اﻟﻄﺎﻗﺔ ﻓﻲ ﻧﻈﺎم ﯾﻌﻨﻲ ان ﺗﻤﯿﻞ اﻻﺧﺘﻼﻓﺎت ﻓﻲ ﺗﺮﻛﯿﺰ اﻟﻄﺎﻗﺔ ان ﺗﺨﺘﻔﻲ ﺑﻤﺮور اﻟﻮﻗﺖ ‪،‬ﻓﺘﺘﺴﺎوي‬
‫درﺟﺔ اﻟﺤﺮارة‪ ،‬وﯾﺘﺴﺎوي اﻟﻀﻐﻂ ‪ ،‬وﺗﺘﺴﺎوي اﻟﻜﺜﺎﻓﺔ‪.‬وھﻜﺬا اﻻﻧﺘﺮوﺑﻲ أﺣﺪ ھﺬه اﻟﺨﺼﺎﺋﺺ ﯾﻤﻜﻦ أﺧﺬھﺎ ﻣﻘﯿﺎس‬
‫ﻻﻧﺘﺸﺎر اﻟﻄﺎﻗﺔ أو اﻟﺤﺮارة‪.‬وﻟﺬﻟﻚ اﻟﻘﺎﻧﻮن اﻟﺜﺎﻧﻲ ﯾﺘﻌﻠﻖ ﺑﺎﻻﻧﺘﺮوﺑﻲ )اﻟﻔﻮﺿﻰ(‪.‬ﯾﺸﯿﺮ اﻟﻘﺎﻧﻮن اﻟﺜﺎﻧﻲ إﻟﻰ أن‬
‫ﻋﻤﻠﯿﺎت اﻟﺪﯾﻨﺎﻣﯿﻜﺎ اﻟﺤﺮارﯾﺔ أي اﻟﻌﻤﻠﯿﺎت اﻟﺘﻲ ﺗﺘﻀﻤﻦ ﻧﻘﻞ أو ﺗﺤﻮﯾﻞ اﻟﻄﺎﻗﺔ اﻟﺤﺮارﯾﺔ‪ ،‬ﻏﯿﺮ ﻋﻜﺴﯿﺔ ﻷﻧﮭﺎ ﺟﻤﯿﻌًﺎ‬
‫ﺗﺆدي إﻟﻰ زﯾﺎدة ﻓﻲ اﻹﻧﺘﺮوﺑﻲ ) زﯾﺎدة اﻟﻔﻮﺿﻰ(‪.‬‬

‫‪Third law of thermodynamics: The 3rd law of thermodynamics will essentially‬‬
‫‪allow us to make "sense" of entropies.‬‬
‫ﯾﻨﺺ اﻟﻘﺎﻧﻮن اﻟﺜﺎﻟﺚ ﻋﻠﻰ أﻧﮫ ﻟﻼﻧﺘﺮﺑﻲ ﻣﻘﯿﺎس ﻣﺤﺴﻮس ﯾﻤﻜﻦ ﺣﺴﺎﺑﮫ ‪.‬ﻋﻨﺪﻣﺎ ﺗﻘﺘﺮب درﺟﺔ ﺣﺮارة اﻟﻨﻈﺎم ﻣﻦ‬
‫اﻟﺼﻔﺮ اﻟﻤﻄﻠﻖ ‪ ،‬ﯾﺼﺒﺢ اﻹﻧﺘﺮوﺑﻲ ﺛﺎﺑﺘﺔ ‪ ،‬أو أن اﻟﺘﻐﯿﺮ ﻓﻲ اﻹﻧﺘﺮوﺑﯿﺎ ھﻮ ﺻﻔﺮ ‪.‬ﻋﻨﺪ اﺿﺎﻓﺔ اﻟﺤﺮارة ﺗﺰداد‬
‫اﻻﻧﺘﺮوﺑﻲ ) ﺗﺰداد اﻟﻔﻮﺿﻰ( ‪.‬‬

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Thermodynamics I lecture 1 Dr. Yasmeen H.Abed

1-3 Dimensions and units
Any physical quantity can be characterized by dimensions. The arbitrary
magnitudes assigned to the dimensions are called units.
There are two types of dimensions, primary or fundamental and secondary or
derived dimensions..‫ ﺗﺴﻤﻰ اﻟﻤﻘﺎدﯾﺮ اﻟﻤﺨﺼﺼﺔ ﻟﻸﺑﻌﺎد ﺑﺎﻟﻮﺣﺪات‬.‫ﯾﻤﻜﻦ ﺗﻤﯿﯿﺰ أي ﻛﻤﯿﺔ ﻣﺎدﯾﺔ ﺑﺎﻷﺑﻌﺎد‬.‫ واﻟﺜﺎﻧﻮﯾﺔ أو اﻟﻤﺸﺘﻘﺔ‬، ‫ اﻷﺑﻌﺎد اﻷوﻟﯿﺔ أو اﻷﺳﺎﺳﯿﺔ‬، ‫ھﻨﺎك ﻧﻮﻋﺎن ﻣﻦ اﻷﺑﻌﺎد‬

Primary dimensions are mass, m; length, L; time, θ; temperature, T
Secondary dimensions are the ones that can be derived ‫ ﻣﺴﺘﻤﺪ‬from primary
dimensions such as: velocity (m/s), pressure (Pa = kg/m.s2), Volume m3 ,
energy kg m2/s2
There are two unit systems currently available:
 USCS (United States Customary System) or English (British) system.
 SI (International System)
English system has no apparent systematic numerical base, and various units in
this system are related to each other rather arbitrarily (12 in =1 ft , 1 mile =5280 ft ,
etc.), which makes it confusing and difficult to learn.
We, however, will use SI units exclusively in this course. The SI units are based
on decimal relationship ‫ اﻟﻌﻼﻗﺔ اﻟﻌﺸﺮﯾﺔ‬between units. The prefixes used to express the
multiples of the various units are listed in Table 1-1,

Table 1-1

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Thermodynamics I lecture 1 Dr. Yasmeen H.Abed

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Thermodynamics I lecture 1 Dr. Yasmeen H.Abed

1-4 Unit Conversion

Ex 1: convert 3 km/h to m/s Ex 2: convert 255 mL to L

1 km= 1000 m L=1000 m L
1 h= 60 min
1min=60 s mL=0.001 L
3 × × × =.
255𝑚𝐿 × = 0.255 𝐿
1000 𝑚 3000 𝑚
=3 = = 0.833 𝑚/𝑠
3600 𝑠 3600 𝑠

Ex 3: convert 0.028 km to cm Ex 4: convert 8432 L to ML
km=1000 m ML=𝟏𝟎𝟔 L
1m=100 cm 8432 𝐿 × =
0.028 𝑘𝑚 × × = 2800 𝑐𝑚 = 8432 × 10 𝑀𝐿 = 0.008432 𝑀𝐿
Ex 5: convert 45 mile/h to m/s

1mi=5280 ft , 1m=3.281 ft , 1min=60 s , 1h=60min
𝑚𝑖 5280 𝑓𝑡 1𝑚 1ℎ 1 𝑚𝑖𝑛 237600 𝑚 𝑚
45 × × × × = = 20.1
ℎ 1 𝑚𝑖 3.281 𝑓𝑡 60𝑚𝑖𝑛 60 𝑠 13761 𝑠 𝑠

Ex 6: convert 9 ton/h to lbm/min

1 ton= 1000 kg
1h=60 min
1 kg= 2.205 lbm
9 𝑡𝑜𝑛 1000 𝑘𝑔 ℎ lbm lbm
× × × = 68.027
ℎ 𝑡𝑜𝑛 60 𝑚𝑖𝑛 2.205 𝑘𝑔 𝑘𝑔

Important note: in engineering all equations must be dimensionally homogenous.
This means that every term in an equation must have the same units. It can be used
as a sanity check for your solution.
‫ ھﺬا ﯾﻌﻨﻲ أن ﻛﻞ ﻣﺼﻄﻠﺢ ﻓﻲ‬.‫ ﻓﻲ اﻟﮭﻨﺪﺳﺔ ﯾﺠﺐ أن ﺗﻜﻮن ﺟﻤﯿﻊ اﻟﻤﻌﺎدﻻت ﻣﺘﺠﺎﻧﺴﺔ اﻷﺑﻌﺎد‬: ‫ﻣﻼﺣﻈﺔ ﻣﮭﻤﺔ‬.‫ ﯾﻤﻜﻦ اﺳﺘﺨﺪام ﻛﻮﺳﯿﻠﺔ ﻟﻠﺘﺤﻘﻖ ﻣﻦ ﺳﻼﻣﺔ اﻟﺤﻞ اﻟﺨﺎص ﺑﻚ‬.‫اﻟﻤﻌﺎدﻟﺔ ﯾﺠﺐ أن ﯾﻜﻮن ﻟﮫ ﻧﻔﺲ اﻟﻮﺣﺪات‬

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‫‪Thermodynamics I‬‬ ‫‪lecture 1‬‬ ‫‪Dr. Yasmeen H.Abed‬‬

‫‪1-4 Definitions‬‬

‫‪System: is a quantity of matter or a region in space‬‬
‫‪chosen for study.‬‬
‫‪Surroundings: Everything outside the system‬‬
‫‪boundary.‬‬
‫‪Boundary: The surface dividing the System from the‬‬
‫‪Surroundings.‬‬

‫اﻟﻨﻈﺎم‪ :‬ھﻮ ﻛﻤﯿﺔ ﻣﻦ اﻟﻤﺎدة أو ﻣﻨﻄﻘﺔ ﻓﻲ اﻟﻔﻀﺎء ﯾﺘﻢ اﺧﺘﯿﺎرھﺎ ﻟﻠﺪراﺳﺔ‪.‬‬

‫اﻟﺒﯿﺌﺔ اﻟﻤﺤﯿﻄﺔ‪ :‬ﻛﻞ ﺷﻲء ﺧﺎرج ﺣﺪود اﻟﻨﻈﺎم‪.‬‬

‫اﻟﺤﺪود‪ :‬اﻟﺴﻄﺢ اﻟﺬي ﯾﻔﺼﻞ اﻟﻨﻈﺎم ﻋﻦ اﻟﻤﺤﯿﻂ‪.‬‬

‫‪1-Closed System (control mass ): fixed non-changing mass of fluid within the‬‬
‫‪system, i.e., no mass transfer across the system boundary but can have energy‬‬
‫‪exchange with the surroundings in the form of heat or work, can cross the‬‬
‫‪boundary, and the volume of a closed system does not have to be fixed.. Example:‬‬
‫‪piston-cylinder assembly‬‬

‫اﻟﻨﻈﺎم اﻟﻤﻐﻠﻖ ) ﻛﺘﻠﺔ ﺛﺎﺑﺘﺔ( ‪ :‬ﻛﺘﻠﺔ ﺛﺎﺑﺘﺔ ﻏﯿﺮ ﻣﺘﻐﯿﺮة ﻣﻦ اﻟﺴﻮاﺋﻞ داﺧﻞ اﻟﻨﻈﺎم ‪ ،‬أي ﻻ ﯾﻮﺟﺪ اﻧﺘﻘﺎل ﻟﻠﻜﺘﻠﺔ ﻋﺒﺮ‬
‫ﺣﺪود اﻟﻨﻈﺎم وﻟﻜﻦ ﯾﻤﻜﻦ أن ﯾﻜﻮن ﻟﮭﺎ ﺗﺒﺎدل ﻟﻠﻄﺎﻗﺔ ﻣﻊ اﻟﻤﻨﺎطﻖ اﻟﻤﺤﯿﻄﺔ ﻓﻲ ﺷﻜﻞ ﺣﺮارة أو ﺷﻐﻞ ‪ ،‬وﯾﻤﻜﻨﮭﺎ‬
‫ﻋﺒﻮر اﻟﺤﺪود ‪ ،‬اﻟﺤﺠﻢ ﻓﻲ اﻟﻨﻈﺎم اﻟﻤﻐﻠﻖ ﻻ ﯾﺠﺐ أن ﯾﻜﻮن ﺛﺎﺑﺘﺎ‪.‬ﻣﺜﻞ اﺳﻄﻮاﻧﺔ اﻟﻤﻜﺒﺲ‪ ،‬ﻻ ﯾﻤﻜﻦ ﻟﻜﺘﻠﺔ اﻟﻐﺎز‬
‫ﻋﺒﻮر ﺣﺪودھﺎ‪.‬أي ‪ ،‬ﻻ ﯾﻤﻜﻦ ﻷي ﻛﺘﻠﺔ أن ﺗﺪﺧﻞ أو ﺗﺘﺮك اﻟﻤﻜﺎن اﻟﻤﻐﻠﻖ ﻓﻲ اﻻﺳﻄﻮاﻧﺔ ‪ ،‬ﻟﻜﻦ ﺗﺘﺴﺮب اﻟﺤﺮارة‬
‫اﻟﻰ اﻟﻤﺤﯿﻂ و ﯾﻤﻜﻦ اﻻﺳﺘﻔﺎدة ﻣﻦ ﺣﺮﻛﺔ اﻟﻤﻜﺒﺲ ﻛﺸﻐﻞ ﻟﻨﻈﺎم اﺧﺮ‪.‬‬

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‫‪Thermodynamics I‬‬ ‫‪lecture 1‬‬ ‫‪Dr. Yasmeen H.Abed‬‬

‫‪2-Open System (Control Volume): fixed volume in space, the mass and energy‬‬
‫‪exchange permitted across the system boundary it usually encloses a device that‬‬
‫‪involves mass flow such as a compressor, turbine, or nozzle.‬‬
‫اﻟﻨﻈﺎم اﻟﻤﻔﺘﻮح )ﺣﺠﻢ ﺛﺎﺑﺖ(‪ :‬اﻟﺤﺠﻢ اﻟﺜﺎﺑﺖ ﻓﻲ اﻟﻨﻈﺎم ‪،‬ﻟﻜﻦ ﯾﺴﻤﺢ ﺑﺘﺒﺎدل اﻟﻜﺘﻠﺔ واﻟﻄﺎﻗﺔ ﻋﺒﺮ ﺣﺪود اﻟﻨﻈﺎم ‪،‬‬
‫ﻋﺎدةً ﻣﺎ ﻧﺮاه ﻓﻲ ﺟﮭﺎز ﯾﺘﻀﻤﻦ ﺗﺪﻓﻘًﺎ ﻣﺴﺘﻤﺮ ﺑﺎﻟﻜﺘﻠﺔ ﻣﺜﻞ اﻟﻀﺎﻏﻂ ‪ ،‬اﻟﺘﻮرﺑﯿﻦ ‪ ،‬ﻓﻮھﮫ )اﻟﻨﻮزل( ‪ ،‬او ﺳﺨﺎن اﻟﻤﺎء‪.‬‬
‫ﻓﻲ ﺳﺨﺎن اﻟﻤﺎء ﻛﺘﻠﺔ اﻟﻤﺎء ﺗﺪﺧﻞ و ﺗﺨﺮج ﻟﻜﻦ ﺣﺠﻢ اﻟﻤﻜﺎن ﺛﺎﺑﺖ ‪.‬ﻓﻲ اﻟﻔﻮھﮫ ﺣﺪود اﻟﻨﻈﺎم ﺗﻜﻮن ﺛﺎﺑﺘﺔ ﺣﻘﯿﻘﯿﺔ‬
‫ﻣﺘﻤﺜﻠﺔ ﺑﺠﺪار اﻟﻔﻮھﮫ اﻣﺎ ﺣﺪود دﺧﻮل و ﺧﺮوج اﻟﻜﺘﻠﮫ ﻓﻲ ﺣﺪود ﺧﯿﺎﻟﯿﺔ‪.‬ﻓﻲ اﻟﻀﺎﻏﻂ ﯾﻜﻮن اﺣﺪ ﺣﺪود اﻟﻨﻈﺎم‬
‫ﻣﺘﺤﺮﻛﺔ واﻻﺧﺮى ﺛﺎﺑﺘﮫ‪.‬‬

‫‪3- Isolated System: Special case of closed system that does not interact at all with‬‬
‫‪the surroundings, e.g., no heat transfer across system boundary.‬‬

‫اﻟﻨﻈﺎم اﻟﻤﻌﺰول‪ :‬ﺣﺎﻟﺔ ﺧﺎﺻﺔ ﻣﻦ اﻟﻨﻈﺎم اﻟﻤﻐﻠﻖ ﻻ ﯾﺘﻔﺎﻋﻞ‬
‫ﻋﻠﻰ اﻹطﻼق ﻣﻊ اﻟﺒﯿﺌﺔ اﻟﻤﺤﯿﻄﺔ ‪ ،‬ﻋﻠﻰ ﺳﺒﯿﻞ اﻟﻤﺜﺎل ‪ ،‬ﻋﺪم‬
‫اﻧﺘﻘﺎل اﻟﺤﺮارة ﻋﺒﺮ ﺣﺪود اﻟﻨﻈﺎم‪.‬‬

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Thermodynamics I lecture 1 Dr. Yasmeen H.Abed

4- Adiabatic system: A closed or open system that does not exchange energy with
the surroundings by heat , but still work could be. A process can be adiabatic by
some other ways, either the process is very fast, so that there is no time for heat
transfer to take place, or the temperature difference between system and
surrounding is zero, or the system is insulated in some way.
‫ ﺳواء اﻟﻧظﺎم ﻣﻐﻠق أو ﻣﻔﺗوح ﻻ ﯾﺗم ﺗﺑﺎدل اﻟطﺎﻗﺔ ﻣﻊ اﻟﻣﺣﯾط ﺑﺎﻟﺣرارة ﻻ ﻣن داﺧﻠﮫ وﻻ ﻣن‬: ‫اﻟﻧظﺎم اﻻدﯾﺑﺎﺗﻲ‬
‫ و ﻋدم ﺗﺑﺎدل اﻟﺣرارة ھو اﻣﺎ ﺑﺳﺑب ﺣدوث اﻟﻌﻣﻠﯾﺔ ﺑﺳرﻋﺔ وﻻ ﯾوﺟد اﻟوﻗت‬.‫ ﻓﻘط ﺣدوث ﺷﻐل‬، ‫ﺧﺎرﺟﮫ‬
‫ او ﯾﻛون اﻟﻧظﺎم ﻣﻌزول ﺑطرﯾﻘﺔ ﻣﺎ‬، ‫اﻟﻛﺎﻓﻲ ﻟﻠﺗﺑﺎدل او ﯾﻛون اﻟﻧظﺎم ﻣﺣﺎط ﺑوﺳط ذات درﺟﺔ ﺣرارة ﻣﺳﺎوﯾﺔ ﻟﮫ‬.‫ﻋن اﻟﺑﯾﺋﺔ اﻟﻣﺣﯾطﺔ ﺑﮫ‬
Important note: some thermodynamics relations that are applicable to closed and
open systems are different. Thus, it is extremely important to recognize the type of
system we have before start analyzing it..‫ ﺑﻌض اﻟﻌﻼﻗﺎت اﻟدﯾﻧﺎﻣﯾﻛﯾﺔ اﻟﺣرارﯾﺔ ﺗﻛون ﻣﺧﺗﻠﻔﺔ و ﺗﻧطﺑق ﻋﻠﻰ اﻷﻧظﻣﺔ اﻟﻣﻐﻠﻘﺔ واﻟﻣﻔﺗوﺣﺔ‬: ‫ﻣﻼﺣظﺔ ﻣﮭﻣﺔ‬.‫ ﻣن اﻟﻣﮭم ﻟﻠﻐﺎﯾﺔ اﻟﺗﻌرف ﻋﻠﻰ ﻧوع اﻟﻧظﺎم ﻟدﯾﻧﺎ ﻗﺑل اﻟﺑدء ﻓﻲ ﺗﺣﻠﯾﻠﮭﺎ‬، ‫وﺑﺎﻟﺗﺎﻟﻲ‬
Working substance: the substance contained within the boundaries of the system,
and the various processes can be done on it, for example steam , air …..
Pure substance: the homogenous substance that has fixed chemical composition
whether it is a single or a multi elements..‫ ﻣﺛل اﻟﺑﺧﺎر واﻟﮭواء‬، ‫ وﯾﻣﻛن إﺟراء اﻟﻌﻣﻠﯾﺎت اﻟﻣﺧﺗﻠﻔﺔ ﻋﻠﯾﮭﺎ‬، ‫ اﻟﻣﺎدة اﻟﻣوﺟودة داﺧل ﺣدود اﻟﻧظﺎم‬:‫ﻣﺎدة اﻟﻌﻣل‬.‫ اﻟﻣﺎدة اﻟﻣﺗﺟﺎﻧﺳﺔ ذات اﻟﺗرﻛﯾب اﻟﻛﯾﻣﯾﺎﺋﻲ اﻟﺛﺎﺑت ﺳواء ﻛﺎﻧت ﻣﻔردة أو ﻣﺗﻌددة اﻟﻌﻧﺎﺻر‬:‫اﻟﻣﺎدة اﻟﻧﻘﯾﺔ‬
Systems

Surface free to do work

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Thermodynamics I lecture 1 Dr. Yasmeen H.Abed

1-6 Properties of a System
In classical thermodynamics, the substance is assumed to be a continuum,
homogenous matter with no microscopic holes. This assumption holds as long as the
volumes, and length scales are large with respect to the intermolecular spacing.

System property: Any characteristic of a system substance used to describe the
system condition and can be measured like pressure, temperature, volume is called
a property.

‫ ﯾﺴﺘﻤﺮ‬.‫ ﯾُﻔﺘﺮض أن ﺗﻜﻮن اﻟﻤﺎدة ﻣﺘﺼﻠﺔ وﻣﺘﺠﺎﻧﺴﺔ ﺑﺪون ﺛﻘﻮب ﻣﺠﮭﺮﯾﺔ‬، ‫ﻓﻲ اﻟﺪﯾﻨﺎﻣﯿﻜﺎ اﻟﺤﺮارﯾﺔ اﻟﻜﻼﺳﯿﻜﯿﺔ‬.‫ھﺬا اﻻﻓﺘﺮاض طﺎﻟﻤﺎ ﻛﺎﻧﺖ اﻷﺣﺠﺎم وﻣﻘﺎﯾﯿﺲ اﻟﻄﻮل ﻛﺒﯿﺮة ﻓﯿﻤﺎ ﯾﺘﻌﻠﻖ ﺑﺎﻟﺘﺒﺎﻋﺪ ﺑﯿﻦ اﻟﺠﺰﯾﺌﺎت‬. (property ‫ ﺗﺴﻤﻰ أي ﺧﺎﺻﯿﺔ ﻟﻤﺎدة اﻟﻨﻈﺎم اﻟﻤﺴﺘﺨﺪﻣﺔ ﻟﻮﺻﻒ ﺣﺎﻟﺔ اﻟﻨﻈﺎم ﺑـ ) ﺧﺎﺻﯿﺔ‬: ‫ﺧﺎﺻﯿﺔ اﻟﻨﻈﺎم‬.‫وﯾﻤﻜﻦ ﻗﯿﺎﺳﮭﺎ ﻣﺜﻞ اﻟﻀﻐﻂ ودرﺟﺔ اﻟﺤﺮارة واﻟﺤﺠﻢ‬

There are two types of properties:
1. Intensive property : the property is independent of system mass (Value may
not vary throughout the system), e.g., pressure, temperature ,density
‫ اﻟﻀﻐﻂ ودرﺟﺔ اﻟﺤﺮارة واﻟﻜﺜﺎﻓﺔ‬، ‫ ﻋﻠﻰ ﺳﺒﯿﻞ اﻟﻤﺜﺎل‬، ‫ﺧﻮاص ﻣﺴﺘﻘﻠﺔ ﻋﻦ ﻛﺘﻠﺔ اﻟﻨﻈﺎم‬

2. Extensive property: the property value for the system is the sum of the
values of the parts into which the system is divided (depends on the system
size) e.g., U, V,S,H,W, Q.
،V ،U ،m ‫ھﻲ ﻣﺠﻤﻮع ﻗﯿﻢ اﻷﺟﺰاء اﻟﺘﻲ ﯾﻘﺴﻢ إﻟﯿﮭﺎ اﻟﻨﻈﺎم )ﯾﻌﺘﻤﺪ ﻋﻠﻰ ﺣﺠﻢ اﻟﻨﻈﺎم( ﻋﻠﻰ ﺳﺒﯿﻞ اﻟﻤﺜﺎل‬
Q ،W ،H ،S

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Thermodynamics I lecture 1 Dr. Yasmeen H.Abed

Specific property : which is defined as extensive property per unit mass. Like ,
v =V/m specific volume , u=U/m specific internal energy ,

s=S/m specific isotropy..

1-7 Processes and Cycles

System state : condition of the thermodynamic system as
described by its properties (P1,T1,….)
Phase : A quantity of matter which is homogenous in
chemical composition can exist in three phases (solid,
liquid ,gas)

Process : Is the transformation of a system from
one state to another state,
for example heating ,cooling , compression ,
expansion……
Path : The series of states that a system passes
throughout during a process..‫ ﺳﻠﺴﻠﺔ ﺗﻐﯿﺮ اﻟﺤﺎﻻت اﻟﺘﻲ ﯾﻤﺮ ﺑﮭﺎ اﻟﻨﻈﺎم ﺧﻼل اﻟﻌﻤﻠﯿﺔ‬:‫اﻟﻤﺴﺎر‬

Cycle : Is a sequence of processes that begins and ends at the same state..‫ ھﻲ ﺳﻠﺴﻠﺔ ﻣﻦ اﻟﻌﻤﻠﯿﺎت ﺗﺒﺪأ وﺗﻨﺘﮭﻲ ﻓﻲ ﻧﻔﺲ اﻟﺤﺎﻟﺔ‬:‫اﻟﺪورة‬

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Thermodynamics I lecture 1 Dr. Yasmeen H.Abed

1-8 Pressure
Pressure is the force exerted by a fluid per unit area
Force: A body when start moving, brought to rest or change direction it is said to
exert a force on it.
Newton's second law gives 𝐹 = 𝑚 ∗ 𝑎 where m=mass (kg)

∴𝐹 =𝑚∗ =𝑚 =𝑚 (𝑘𝑔 = 𝑁)
Newton(N): is the force required to accelerate a unit mass at rate one meter per
squared second

Weight :is the attraction force between a body and earth. Weight is normally
change with altitude and position.
𝑚
𝑤𝑒𝑖𝑔ℎ𝑡 = 𝑚 ∗ 𝑔 𝑘𝑔. = 𝑁 𝑤𝑒𝑖𝑔ℎ𝑡 = 𝜌 𝑉 ∗ 𝑔
𝑠
g: (gravitational acceleration) =9.81 m/s2
𝒎
𝑭 𝒌𝒈. 𝟐 𝑵
𝒔
Pressure = = ( = = 𝐏𝐚)
𝑨 𝒎𝟐 𝒎𝟐
𝑚
Work = 𝐹∗𝑥 ( 𝑘𝑔. ∗𝑚 = 𝑁∗𝑚 = 𝐽)
𝑠2

In fluids, gases and liquids, we speak of pressure; in solids this is stress.

Prove 𝑃 =𝜌𝑔ℎ
P= =
𝑤𝑒𝑖𝑔ℎ𝑡 𝑜𝑓 𝑙𝑖𝑞𝑢𝑖𝑑
𝐴
𝑚𝑔 𝜌 𝑉 𝑔
𝑃 = =
𝐴 𝐴
𝜌𝐴ℎ𝑔
=
𝐴
𝑃=𝜌𝑔ℎ

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Thermodynamics I lecture 1 Dr. Yasmeen H.Abed

Units:
1 Pa = 1 N/m2
standard atmosphere = 101,325 Pa
1 bar = 100,000 Pa = 100 kPa = 0.1 MPa
a-Atmospheric pressure (Patm.)
The local atmospheric pressure, Patm. measurement
via a mercury Barometer.

𝑃 =𝜌 ∗ 𝑔 ∗ ℎ ( 760 mm)
= 13600*9.81*0.76
=101325 Pa
=101.325 kPa
=1.01325 bar
= 1 atm
The density of mercury is 13.5 times the density of water
Note: 1 standard atmosphere = 760 mm (29.9 in.) mercury = 10,260 mm water

b-Gauge pressure ,( Pg. ):
A pressure measured relative to the local
atmospheric pressure, Patm.
It is (+,-) sign Gauge pressure measurement via a
manometer.
The cross sectional area of the tube is not
important.

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Thermodynamics I lecture 1 Dr. Yasmeen H.Abed

Bourdon Tube is a device that measures pressure using mechanical deformation.
Pressure Transducers are devices that use piezoelectric to measure pressure.

Pressure
Transduce
rs

c-Absolute pressure , Pabs. :

Pressure measured relative to a perfect vacuum.(+) 𝑃 =𝑃 ∓𝑃

In thermodynamics calculations, always use absolute pressure. Most pressure
measuring devices are calibrated to read zero in the atmosphere.

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Thermodynamics I lecture 1 Dr. Yasmeen H.Abed

1-9 Temperature and temperature scale

Temperature :measure of hotness or coldness it not easy to give an exact definition
for it level of temperature freezing cold, cold , warm, hot ,red-hot.
Temperature scale based on some easily reference state such as freezing and boiling
points of water.
Ice point : is the temperature of mixture of ice and water that is in equilibrium
with air saturated with vapour at a pressure of 1 atm.
Steam point: is the temperature of a mixture of liquid water and water vapour in
equilibrium at a pressure of 1 atm.

Means of Temperature Measurement
All temperature measurements are based on the change of certain property with
temperature, such means can be listed here as ;
:‫وﺳﺎﺋﻞ ﻗﯿﺎس درﺟﺔ اﻟﺤﺮارة‬
‫ وﯾﻤﻜﻦ‬، ‫ﺗﺴﺘﻨﺪ ﺟﻤﯿﻊ ﻣﻘﺎﯾﯿﺲ درﺟﺔ اﻟﺤﺮارة ﻋﻠﻰ ﺗﻐﯿﯿﺮ ﺧﺎﺻﯿﺔ ﻣﻌﯿﻨﺔ ﻣﻦ ﺧﻮاص اﻟﻤﺎدة ﻣﻊ درﺟﺔ اﻟﺤﺮارة‬
‫إدراج ھﺬه اﻟﻮﺳﺎﺋﻞ ﻋﻠﻰ اﻟﻨﺤﻮ اﻟﺘﺎﻟﻲ ؛‬
 Volumetric expansion of a liquid (bulb thermometer)
 Pressure exerted by gas (gas thermometer)
 Vapour pressure of liquids(steam pressure thermometer)
 Electric resistance of solids (resistance thermometer)
 Thermoelectricity (thermocouple thermometer)
 Thermal radiation (pyrometer)

(‫اﻟﺘﻤﺪد اﻟﺤﺠﻤﻲ ﻟﻠﺴﺎﺋﻞ )ﻣﺤﺮار ﺑﺼﻠﻲ‬ 
(‫اﻟﻀﻐﻂ اﻟﻐﺎز )ﻣﻘﯿﺎس ﺣﺮارة اﻟﻐﺎز‬
(‫ﺿﻐﻂ ﺑﺨﺎر اﻟﺴﻮاﺋﻞ )ﻣﻘﯿﺎس ﺣﺮارة ﺿﻐﻂ اﻟﺒﺨﺎر‬
(‫اﻟﻤﻘﺎوﻣﺔ اﻟﻜﮭﺮﺑﺎﺋﯿﺔ ﻟﻠﻤﻮاد اﻟﺼﻠﺒﺔ )ﻣﺤﺮار اﻟﻤﻘﺎوﻣﺔ‬
(‫اﻟﻜﮭﺮﺑﺎء اﻟﺤﺮارﯾﺔ )ﻣﻘﯿﺎس ﺣﺮارة ﻣﺰدوج‬
(‫اﻹﺷﻌﺎع اﻟﺤﺮاري )اﻟﺒﯿﺮوﻣﺘﺮ‬

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Thermodynamics I lecture 1 Dr. Yasmeen H.Abed

Temperature scales
There are four major temperature scales that are used around the world –
Fahrenheit and Celsius are frequently used in everyday, around the house
measurements, while the absolute zero-based Kelvin and Rankine scales are more
commonly used in industry and the sciences.

A- The Celsius scale to measure temperatures. The
Celsius scale is sometimes referred to as
the centigrade scale, because it is based on a 100
degree division between the freezing and boiling
points of water: water freezes at 0 degrees Celsius
and boils at 100 degrees C.

B- The Kelvin scale was adapted from the Celsius
scale. Kelvin was designed in order to set the
zero point of the temperature scale at absolute
zero. To convert from Celsius to Kelvin by
adding 273.15 to a Celsius temperature. Water
freezes at 273.15 K, and boils at 373.15 K.
Because of its direct relation to absolute zero,
Kelvin temperature is widely used in scientific
equations and calculations. For instance, the ideal
gas law, uses Kelvin as its standard unit.

T(K) = t(℃) + 273.15 , 0℃ = 273.15K , ∆T(K) = ∆t(℃)

C- The Fahrenheit scale On this scale, the interval between the water freezes
at 32 degrees Fahrenheit, and boils at 212 degrees F. It is divided to 180
degree. The Fahrenheit temperature scale includes negative temperatures,
below 0 degrees F
9
t(℉) = t(℃) + 32
5
D- Rankine scale provides an absolute zero-based equivalent to the Fahrenheit
scale. Essentially, it is for the Fahrenheit scale what Kelvin is for Celsius.
Temperatures can be converted from Fahrenheit to Rankine by adding 459.67.
Absolute zero is thus located at 0 degrees Rankine. Water freezes at 491.67
degrees R, and boils at 671.67 degrees R.

T(R) = t(℉) + 459.67 T(R) = T(K)

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Thermodynamics I lecture 1 Dr. Yasmeen H.Abed

Microscopic point of view: Temperature is a measure of the internal molecular
motion, e.g., average molecule kinetic energy At a temperature of –273.15C
molecular motion ceases Temperature in units of degrees kelvin, K, is measured
relative to this absolute zero temperature, so 0 K = -273C
‫ ﻣﺘﻮﺳﻂ‬، ‫ ﻋﻠﻰ ﺳﺒﯿﻞ اﻟﻤﺜﺎل‬، ‫ درﺟﺔ اﻟﺤﺮارة ھﻲ ﻣﻘﯿﺎس ﻟﻠﺤﺮﻛﺔ اﻟﺠﺰﯾﺌﯿﺔ اﻟﺪاﺧﻠﯿﺔ‬:‫وﺟﮭﺔ ﻧﻈﺮ ﺗﺤﺖ اﻟﻤﺠﮭﺮ‬
‫ ﺗﺘﻮﻗﻒ اﻟﺤﺮﻛﺔ اﻟﺠﺰﯾﺌﯿﺔ ﻋﻦ درﺟﺔ‬، ‫ درﺟﺔ ﻣﺌﻮﯾﺔ‬- 273.15 ‫اﻟﻄﺎﻗﺔ اﻟﺤﺮﻛﯿﺔ ﻟﻠﺠﺰيء ﻋﻨﺪ درﺟﺔ ﺣﺮارة‬
‫ ﻟﺬﻟﻚ‬، ‫ ﯾﺘﻢ ﻗﯿﺎﺳﮭﺎ ﺑﺎﻟﻨﺴﺒﺔ ﻟﺪرﺟﺔ ﺣﺮارة اﻟﺼﻔﺮ اﻟﻤﻄﻠﻖ‬،K ، ‫اﻟﺤﺮارة ﺑﻮﺣﺪات درﺟﺔ ﻛﻠﻔﻦ‬
‫ درﺟﺔ ﻣﺌﻮﯾﺔ‬273- = ‫ﺻﻔﺮ ﻛﻠﻔﻦ‬
1-10 State and Equilibrium
At a given state, all the properties of a system have fixed values. Thus, if the value
of even One property changes, the state will change to different one.
In an equilibrium state, there are no unbalanced potentials (or driving forces) within
the system.

condition of the thermodynamic system as described by its properties
(P1,T1,….)
A system is at steady-state if none of the system properties change with time
A system is in equilibrium if when the system is isolated from its
surroundings there are no changes in its properties Example: thermal
equilibrium

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Thermodynamics I lecture 1 Dr. Yasmeen H.Abed

1-11 Kilocalorie
The measurement of heat is called calorimetry. The calorie, or gram calorie, is the
quantity of heat required to raise the temperature of 1 gram of pure water 1°C. The
kilocalorie, or kilogram calorie, is the quantity of heat required to raise the
temperature of 1 kg of pure water 1°C; it is equal to 1,000 cal.

1 J= 0.239 Cal

1-12 Volume

Volume: The space occupied by the substance, if increases than it expands, or
decreases thus it is compressed. Unit (m3) and for liquid (L) , 1m3=1000L

Specific volume: which is defined as volume per unit mass. That is,
v, =V/m m3/kg

Density : is defined as mass per unit volume
𝒎 𝒌𝒈
𝝆= 𝒎𝟑
𝑽
The reciprocal of density is the specific volume
𝟏
𝝆=
𝒗

1-13 The mass flow rate (for open system)

(𝑚̇): is the mass flow rate of substance (fluid) which passes per unit time.its units
in SI( kg/s)

𝑚̇ =𝜌 𝐶𝐴
Where
𝛒= the density kg/m3
C= the velocity m/s
A= the cross section area m2

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Thermodynamics I lecture 1 Dr. Yasmeen H.Abed

1-14 The volumetric flow rate (for open system)

𝑉̇ : is the volume flow rate of substance (fluid) which passes per unit time. its unit
in SI (m3/s)

𝑉̇ = 𝐶𝐴

Where
A: cross sectional area of conduit m2 ‫ﻣﺳﺎﺣﺔ ﻣﻘطﻊ اﻻﻧﺑوب او اﻟﻘﻧﺎه‬
C: flow velocity inside the conduit m/s ‫ﺳرﻋﺔ اﻟﻣﺎﺋﻊ داﺧل اﻻﻧﺑوب او اﻟﻘﻧﺎه‬
̇ / ̇
𝑉̇ = 𝐶𝐴 = = 𝑣 𝑚̇ = =
/

1-15 Examples :

Example 1.1. On a piston of 10 cm diameter a force of 1000 N is uniformly applied.
Find the pressure on the piston.( N/m2) & (kPa)

Solution. Diameter of the piston d = 10 cm (= 0.1 m)
Force applied on the piston, F = 1000 N
∴ Pressure on the piston, P = = = 127307 =.
kN
127.307. = 127.307kPa
𝑚

Example 1.2. A tube contains an oil of specific gravity 0.9 to a depth of 120 cm.
Find the gauge pressure at this depth (in kN/m2).

Solution. Specific gravity of oil = 0.9 , 𝑆𝐺 =
Depth of oil in the tube, h = 120 cm = (1.2 m)
We know that 𝑃 = 𝜌 𝑔 ℎ = (0.9 𝜌 ) ∗ 9.81 ∗ 1.2
𝑁
= 0.9 × 1000 × 9.81 × 1.2
𝑚
𝑁 𝑘𝑁
= 10594.8 = 10.5948
𝑚 𝑚
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Thermodynamics I lecture 1 Dr. Yasmeen H.Abed

Example 1.3. The vacuum pressure reading of a tank (Pg) given 15 kPa and
atmospheric pressure (Patm) is 750 mmHg. Find the absolute pressure in the tank.
Properties The density of mercury is given to be (ρ = 13,590 kg/m3).

Solution : Analysis The atmospheric (or barometric) pressure can be expressed as
kg m
𝑃𝑎𝑡𝑚 = 𝜌 𝑔 ℎ = 13,590 ∗ 9.81 ∗ 0.75𝑚 = 99,988.425 Pa = 99.988 kPa
𝑚 𝑠
Then the absolute pressure in the tank becomes
𝑃 =𝑃 −𝑃 = 99.988 kPa − 15 kPa ≅ 85 kPa

Example 1.4. A pressure gage connected to a tank reads
500 kPa. Find the absolute pressure in the tank if the
atmospheric pressure (Patm) is 94 kPa.
Solution :
𝑃 =𝑃 +𝑃 = 94𝑘𝑃𝑎 + 500𝑘𝑃𝑎 = 594 𝑘𝑃𝑎

Example 1.5. A vertical piston–cylinder device contains a gas, the piston has a mass
of 50 kg and a diameter of 22 cm. Find the absolute pressure (Pabs ) of the gas if the
atmospheric pressure (Patm) is 0.97 bar.

Solution :
𝑃 =𝑃 +𝑃
𝐹 𝑚∗𝑔
=𝑃 + =𝑃 +
𝐴 𝐴
𝑚
𝐹 𝑚∗𝑔 50 𝑘𝑔 ∗ 9.81
𝑃 = = = 𝜋 𝑠
𝐴 𝐴 (0.22) 𝑚
4
𝑁 1 𝑏𝑎𝑟
= 12,898 = 12,898 Pa = 12,898 ∗ = 0.129 𝑏𝑎𝑟
𝑚 10

∴ 𝑃 = 0.97𝑏𝑎𝑟 + 0.129 𝑏𝑎𝑟 = 1.099 bar

Where = 𝑃𝑎 , 1 𝑏𝑎𝑟 = 10 𝑃𝑎 ∴ 1 𝑃𝑎 =

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Thermodynamics I lecture 1 Dr. Yasmeen H.Abed

Example 1.6 A vertical piston–cylinder device contains a gas. Pressure of the gas
is be increased by placing some weights on the piston. The piston with the weights
has a mass of 2 kg and a diameter of 24 cm. The atmospheric pressure is be measured
by a mercury barometric, the mercury high is 750 mm. Determine the pressure gage
and the absolute pressure (Pabs ) of the gas in mmHg ،PSI ،bar & kPa units.
The density of mercury is given to be (ρ = 13,600 kg/m3).

Solution :

0.003253 mHg = 3.253 mmHg

mHg = 753.2 mmHg

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Thermodynamics I lecture 1 Dr. Yasmeen H.Abed

Example 1.7 A U-tube mercury manometer with
one arm open to atmosphere is used to measure
pressure in a steam pipe. The level of mercury in
open arm is 97.5 mm greater than that in the arm
connected to the pipe. Some of steam in the pipe
condenses in the manometer arm connected to the
pipe. The height of this column is 34 mm. The
atmospheric pressure is 760 mm of Hg. Find the
absolute pressure of steam in mm Hg, Pa and bar
unites.

Solution :

Equation the pressure in mmHg on both arms above the line X-X , we get
𝑃 + 𝑃 =𝑃 +𝑃 P in mmHg

𝜌 ℎ
𝑡𝑜 𝑓𝑖𝑛𝑑 𝑃 ∶ 𝜌 𝑔 ℎ =𝜌 𝑔 ℎ , ℎ =
𝜌
𝜌 ℎ 1000 ∗ 34
∴𝑃 𝑖𝑛 ℎ = = = 2.5 𝑚𝑚𝐻𝑔
𝜌 13600
∴ 𝑃 + 2.5 = 760 + 97.5

∴ 𝑃 = 855 𝑚𝑚𝐻𝑔

855 𝑚𝑚𝐻𝑔 𝑘𝑔 𝑚 𝑁
= ∗ 13600 ∗ 9.81 = 114,070.68 = 114,070.68 𝑃𝑎
𝑚𝑚𝐻𝑔 𝑚 𝑠 𝑚
1000 𝑚𝐻𝑔
𝑏𝑎𝑟
∴ 𝑃 = 114,070.68 𝑃𝑎 ∗ 5 = 1.1407 𝑏𝑎𝑟
10 𝑃𝑎

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Thermodynamics I lecture 1 Dr. Yasmeen H.Abed

Example 1.8

Solution :

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Thermodynamics I lecture 1 Dr. Yasmeen H.Abed

H.W

1. The atmospheric pressures at the top and the bottom of a building are read by a
barometer to be 96.0 and 98.0 kPa. If the density of air is 1.0 kg/m3, what is the
height of the building ?

2. A vacuum gage connected to a chamber reads 35 kPa at a location where the
atmospheric pressure is 92 kPa. Determine the absolute pressure in the chamber.

3. The absolute pressure in water at a depth of 5 m is read to be 145 kPa.
Determine (a) the local atmospheric pressure, and (b) the absolute pressure at a
depth of 5 m in a liquid whose specific gravity is 0.85 at the same location.

4. The piston of a vertical piston–cylinder device containing a gas has a mass of 60
kg and a cross-sectional area of 𝟒×𝟏𝟎-2 𝒎𝟐, as shown in Fig. The local
atmospheric pressure is 0.97 bar, and the gravitational acceleration is 9.81 m/s 2.
(a) Determine the pressure inside the cylinder. (b) If some heat is transferred to
the gas and its volume is doubled, do you expect the pressure inside the cylinder
to change?

5. convert (20 m3) to ( ft3), Liter & gallon unites.

convert (0.0025 lbm/in3) to ( kg/m3) & (slug/ft3) unites.

convert (120W) to (Btu/h) & (hp)

Note : Btu = British thermal unit of heat

6. The temperature is 45O C , find the Temperature in F , K and R.

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