大葉大學圖書館 |

Essential engineering thermodynamics :a student's guide /

紀錄類型:	書目-語言資料,印刷品 : Monograph/item
杜威分類號:	621.402/1
書名/作者:	Essential engineering thermodynamics : : a student's guide // Yumin Zhang.
作者:	Zhang, Yumin.
出版者:	[San Rafael, Calif.] : : Morgan & Claypool,, c2018.
面頁冊數:	xi, 67 p. : : ill. ;; 24 cm.
標題:	Thermodynamics.
ISBN:	9781681734231 (pbk.) :
ISBN:	9781681734255 (hbk.)
書目註:	Includes bibliographical references (p. 65-66).
內容註:	1. Thermodynamics properties -- 1.1 Criteria of ideal gas -- 1.2 Ideal gas law -- 1.3 Pressure and work -- 1.4 Temperature and Zeroth law -- 1.5 Internal energy -- 1.6 Enthalpy -- 2. Thermodynamics laws -- 2.1 1st law of thermodynamics -- 2.2 Entropy -- 2.3 2nd law of thermodynamics -- 2.4 3rd law of thermodynamics -- 2.5 Maxwell relations -- 3. Control mass processes -- 3.1 State and properties -- 3.2 Phase change -- 3.3 Isochoric process -- 3.4 Isobaric process -- 3.5 Isothermal process -- 3.6 Adiabatic and isentropic process -- 4. Control volume processes -- 4.1 Mass rate equation -- 4.2 Energy rate equation -- 4.3 Nozzle and diffuser -- 4.4 Compressor and turbine -- 4.5 Throttle valve -- 4.6 Entropy rate equation -- 5. Advanced topics -- 5.1 Entropy and information -- 5.2 Equilibrium in isolated systems -- 5.3 Equilibrium with heat transfer -- 5.4 Crystal growth -- 5.5 Chemical potential -- 5.6 Dissipative structures -- 5.7 Socioeconomic systems -- Bibliography -- Author's biography.
摘要、提要註:	Engineering Thermodynamics is a core course for students majoring in Mechanical and Aerospace Engineering. Before taking this course, students usually have learned Engineering Mechanics-- Statics and Dynamics, and they are used to solving problems with calculus and differential equations. Unfortunately, these approaches do not apply for Thermodynamics. Instead, they have to rely on many data tables and graphs to solve problems. In addition, many concepts are hard to understand, such as entropy. Therefore, most students feel very frustrated while taking this course. The key concept in Engineering thermodynamics is state-properties: If one knows two properties, the state can be determined, as well as the other four properties. Unlike most textbooks, the 1st two chapters of this book introduce thermodynamic properties and laws with the ideal gas model, where equations can be engaged. In this way, students can employ their familiar approaches, and thus can understand them much better. In order to help students understand entropy in depth, interpretation with statistical physics is introduced. Chapters 3 and 4 discuss control-mass and control-volume processes with general fluids, where the data tables are used to solve problems. Chapter 5 covers a few advanced topics, which can also help students understand the concepts in thermodynamics from a broader perspective.

Essential engineering thermodynamics :a student's guide /
Zhang, Yumin.

Essential engineering thermodynamics :a student's guide /Yumin Zhang. - [San Rafael, Calif.] :Morgan & Claypool,c2018. - xi, 67 p. :ill. ;24 cm. - Synthesis lectures on mechanical engineering,#162573-3168 ;.

Includes bibliographical references (p. 65-66).

1. Thermodynamics properties -- 1.1 Criteria of ideal gas -- 1.2 Ideal gas law -- 1.3 Pressure and work -- 1.4 Temperature and Zeroth law -- 1.5 Internal energy -- 1.6 Enthalpy -- 2. Thermodynamics laws -- 2.1 1st law of thermodynamics -- 2.2 Entropy -- 2.3 2nd law of thermodynamics -- 2.4 3rd law of thermodynamics -- 2.5 Maxwell relations -- 3. Control mass processes -- 3.1 State and properties -- 3.2 Phase change -- 3.3 Isochoric process -- 3.4 Isobaric process -- 3.5 Isothermal process -- 3.6 Adiabatic and isentropic process -- 4. Control volume processes -- 4.1 Mass rate equation -- 4.2 Energy rate equation -- 4.3 Nozzle and diffuser -- 4.4 Compressor and turbine -- 4.5 Throttle valve -- 4.6 Entropy rate equation -- 5. Advanced topics -- 5.1 Entropy and information -- 5.2 Equilibrium in isolated systems -- 5.3 Equilibrium with heat transfer -- 5.4 Crystal growth -- 5.5 Chemical potential -- 5.6 Dissipative structures -- 5.7 Socioeconomic systems -- Bibliography -- Author's biography.

Engineering Thermodynamics is a core course for students majoring in Mechanical and Aerospace Engineering. Before taking this course, students usually have learned Engineering Mechanics-- Statics and Dynamics, and they are used to solving problems with calculus and differential equations. Unfortunately, these approaches do not apply for Thermodynamics. Instead, they have to rely on many data tables and graphs to solve problems. In addition, many concepts are hard to understand, such as entropy. Therefore, most students feel very frustrated while taking this course. The key concept in Engineering thermodynamics is state-properties: If one knows two properties, the state can be determined, as well as the other four properties. Unlike most textbooks, the 1st two chapters of this book introduce thermodynamic properties and laws with the ideal gas model, where equations can be engaged. In this way, students can employ their familiar approaches, and thus can understand them much better. In order to help students understand entropy in depth, interpretation with statistical physics is introduced. Chapters 3 and 4 discuss control-mass and control-volume processes with general fluids, where the data tables are used to solve problems. Chapter 5 covers a few advanced topics, which can also help students understand the concepts in thermodynamics from a broader perspective.

ISBN: 9781681734231 (pbk.) :NTD 1,094Subjects--Topical Terms:

172172
Thermodynamics.

LC Class. No.: TJ265 / .Z424 2018

Dewey Class. No.: 621.402/1

Essential engineering thermodynamics :a student's guide /
LDR:03125cam a2200217 a 4500 001 482296
005 20190222092000.0
008 190624s2018 caua b 000 0 eng d
020 $a 9781681734231 (pbk.) : $c NTD 1,094
020 $a 9781681734255 (hbk.)
020 $z 9781681734248 (ebk.)
040 $a YDX $b eng $c YDX $d OCLCQ $d IPC $d OCLCO $d OCLCF $d VSC $d DYU
041 0 $a eng
050 4 $a TJ265 $b .Z424 2018
082 0 4 $a 621.402/1 $2 23
100 1 $a Zhang, Yumin. $3 697048
245 1 0 $a Essential engineering thermodynamics : $b a student's guide / $c Yumin Zhang.
260 $a [San Rafael, Calif.] : $b Morgan & Claypool, $c c2018.
300 $a xi, 67 p. : $b ill. ; $c 24 cm.
490 0 $a Synthesis lectures on mechanical engineering, $x 2573-3168 ; $v #16
504 $a Includes bibliographical references (p. 65-66).
505 0 $a 1. Thermodynamics properties -- 1.1 Criteria of ideal gas -- 1.2 Ideal gas law -- 1.3 Pressure and work -- 1.4 Temperature and Zeroth law -- 1.5 Internal energy -- 1.6 Enthalpy -- 2. Thermodynamics laws -- 2.1 1st law of thermodynamics -- 2.2 Entropy -- 2.3 2nd law of thermodynamics -- 2.4 3rd law of thermodynamics -- 2.5 Maxwell relations -- 3. Control mass processes -- 3.1 State and properties -- 3.2 Phase change -- 3.3 Isochoric process -- 3.4 Isobaric process -- 3.5 Isothermal process -- 3.6 Adiabatic and isentropic process -- 4. Control volume processes -- 4.1 Mass rate equation -- 4.2 Energy rate equation -- 4.3 Nozzle and diffuser -- 4.4 Compressor and turbine -- 4.5 Throttle valve -- 4.6 Entropy rate equation -- 5. Advanced topics -- 5.1 Entropy and information -- 5.2 Equilibrium in isolated systems -- 5.3 Equilibrium with heat transfer -- 5.4 Crystal growth -- 5.5 Chemical potential -- 5.6 Dissipative structures -- 5.7 Socioeconomic systems -- Bibliography -- Author's biography.
520 3 $a Engineering Thermodynamics is a core course for students majoring in Mechanical and Aerospace Engineering. Before taking this course, students usually have learned Engineering Mechanics-- Statics and Dynamics, and they are used to solving problems with calculus and differential equations. Unfortunately, these approaches do not apply for Thermodynamics. Instead, they have to rely on many data tables and graphs to solve problems. In addition, many concepts are hard to understand, such as entropy. Therefore, most students feel very frustrated while taking this course. The key concept in Engineering thermodynamics is state-properties: If one knows two properties, the state can be determined, as well as the other four properties. Unlike most textbooks, the 1st two chapters of this book introduce thermodynamic properties and laws with the ideal gas model, where equations can be engaged. In this way, students can employ their familiar approaches, and thus can understand them much better. In order to help students understand entropy in depth, interpretation with statistical physics is introduced. Chapters 3 and 4 discuss control-mass and control-volume processes with general fluids, where the data tables are used to solve problems. Chapter 5 covers a few advanced topics, which can also help students understand the concepts in thermodynamics from a broader perspective.
650 0 $a Thermodynamics. $3 172172