skip to content
Covid-19 virus
COVID-19 Resources

Reliable information about the coronavirus (COVID-19) is available from the World Health Organization (current situation, international travel). Numerous and frequently-updated resource results are available from this WorldCat.org search. OCLC’s WebJunction has pulled together information and resources to assist library staff as they consider how to handle coronavirus issues in their communities.

Image provided by: CDC/ Alissa Eckert, MS; Dan Higgins, MAM
Graphical thermodynamics and ideal gas power cycles : ideal gas thermodynamics in brief Preview this item
ClosePreview this item
Checking...

Graphical thermodynamics and ideal gas power cycles : ideal gas thermodynamics in brief

Author: Moufid I Helal
Publisher: New York, [New York] (222 East 46th Street, New York, NY 10017) : Momentum Press, 2017.
Series: Thermal science and energy engineering collection.
Edition/Format:   eBook : Document : EnglishView all editions and formats
Summary:
In this book, an almost new approach to modern thermodynamics has been applied. One or more useful qualitative discussion statements have been extracted from each equation. These and other important statements were numbered and their titles were situated in an index entitled "Helal and Others' statements, definitions and rules." This ensures very quick obtaining of the required (for discussing and solving problems)  Read more...
Rating:

(not yet rated) 0 with reviews - Be the first.

Subjects
More like this

Find a copy online

Links to this item

Find a copy in the library

&AllPage.SpinnerRetrieving; Finding libraries that hold this item...

Details

Genre/Form: Electronic books
Additional Physical Format: Print version:
Material Type: Document, Internet resource
Document Type: Internet Resource, Computer File
All Authors / Contributors: Moufid I Helal
ISBN: 9781606505076 1606505076
OCLC Number: 1000560268
Notes: Author's name on covers: Mufid I. Helal.
Description: 1 online resource (xxx, 269 pages) : illustrations.
Contents: 1. Basic concepts and definitions --
1.1 Unit systems --
1.1.1 Introduction --
1.1.2 The international system of units --
1.1.2.1 Deriving some secondary units from the primary ones --
1.1.3 The U.S. customary system (also known as the English system) --
1.1.4 The technical unit system --
1.1.5 Force and mass main units' conversions --
1.1.6 Weight of a body --
1.1.7 Pressure units --
1.1.8 Others' definitions --
1.1.9 Energy units --
1.1.10 Temperature units --
1.1.11 About dimensions' units in the calculating equations --
1.2 Calculations and discussions in thermodynamics --
1.2.1 Calculating the area under a plane curve --
1.2.1.1 Graphical calculation of the area under y = f(x) curve --
1.2.1.2 Analytical calculation of the area under y = f(x) curve --
1.2.1.3 Tabular calculation of the area under y = f(x) curve --
1.2.2 Tabular determination of y-value versus a given x-value --
1.2.3 Difference between two functions of the same variable --
1.3 Summary --
Chapter endnotes 2. The working fluid and its basic properties --
2.1 Energy and its transformations --
2.1.1 Introduction --
2.1.2 Types of energy --
2.1.3 Energy transformation --
2.2 The heat engine --
2.3 The process of transforming thermal energy into mechanical in heat engines --
2.3.1 Internal combustion engines (in the broad sense) --
2.3.2 External combustion engines --
2.4 Basic concepts and definitions --
2.4.1 Introduction --
2.4.2 The pure substance and its molecules --
2.4.3 Intermolecular forces --
2.4.4 The ideal and real gas subphases --
2.4.5 The thermodynamic system (the system) --
2.4.5.1 Introduction --
2.4.5.2 Types of thermodynamic systems --
2.4.6 Introduction to the kinetic-molecular theory --
2.4.7 The state of a gas --
2.4.7.1 The definition of the state of a system --
2.4.7.2 The equilibrium state --
2.4.7.3 Some state properties --
2.4.8 Modes of work --
2.4.9 The simple compressible substance and the simple compressible system --
2.4.10 The state change processes of a system (gas) --
2.4.11 The thermodynamic cycle --
2.4.12 The equilibrium process and the conditions to realize it --
2.4.12.1 The equilibrium process --
2.4.12.2 The conditions for achieving an equilibrium (quasi-equilibrium) process --
2.4.12.3 The minimum required number of MRs to achieve an equilibrium (quasi-equilibrium) WF state change process --
2.4.13 The reversible process and the conditions to realize it --
2.4.13.1 The definitions of the reversible process --
2.4.13.2 The practiced in thermodynamics conditions for achieving a reversible process --
2.4.13.3 Irreversible processes --
2.4.13.4 The internally reversible processes --
2.5 Ideal-gas laws --
2.5.1 Introduction --
2.5.2 Ideal-gas equation of state (Clapeyron equation) ABR --
2.5.3 Avogadro's law --
2.5.3.1 Others' statements (OSs) --
2.6 Ideal-gas mixtures --
2.6.1 The laws of ideal-gas mixtures that can be derived on the basis of the kinetic molecular theory --
2.6.1.1 Dalton's law --
2.6.1.2 Amagat's law --
2.6.2 Gas mixture composition --
2.7 The boundary work calculation --
2.8 Recognizing thermodynamic properties --
2.9 A brief overview of the properties of real gases --
Conclusions --
2.10 Summary --
Chapter endnotes 3. The first law of thermodynamics --
3.1 Heat transfer calculations during gas state change processes --
3.1.1 The specific transferred heat and the specific heat --
3.1.1.1 Basic definitions and relations --
3.1.2 The caloric intensive properties --
3.1.2.1 Internal energy --
3.1.2.2 Enthalpy --
3.1.2.3 Ideal gas entropy --
3.1.3 The graphical representation of the gas state and of the gas state change processes --
3.1.4 General form equations for calculating the boundary work and transferred heat --
3.1.5 Some of the rules, definitions, and notes, mainly used in this book, that simplify the graphical calculations and discussions --
3.1.6 The determination of the specific heats of gases --
3.1.6.1 The experimental determination of the specific heats of ideal gases --
3.1.6.2 The theoretical determination of the specific heats of ideal gases --
3.1.7 Calculating the transferred heat during physical ideal gas state change processes --
3.1.7.1 The pure analytical calculations of the transferred heat during physical ideal gas state change processes --
3.1.7.2 About the bad effect of abbreviating the calculating equations by cutting off their higher-degree terms --
3.1.7.3 Some additional analyses on equations (3-36) --
3.1.7.4 The tabular calculations of the transferred heat during physical ideal gas state change processes --
3.1.7.5 The almost exact (highly accurate) calculation of the transferred heat --
3.1.7.6 The approximate calculations of the transferred heat during physical ideal gas state change processes --
3.1.8 The specific heat of a mixture --
3.2 About heat transfer calculations for chemical state change processes of a gas --
3.3 The zeroth law of thermodynamics --
3.4 The conservation of energy principle. The first law of thermodynamics --
3.4.1 Introduction --
3.4.2 The first law forms --
3.5 The analytical expression for the first law of thermodynamics --
3.6 Summary --
Chapter endnotes 4. Calculations of ideal gas physical state change processes in closed systems (part I) --
4.1 Introduction --
4.2 The special cases of the gas state change processes and their representation on property diagrams --
4.3 The special cases of the first law of thermodynamics for any gas --
4.3.1 The first law of thermodynamics for the isochoric process --
4.3.2 The first law of thermodynamics for the isobaric process --
4.3.3 The first law of thermodynamics for the adiabatic process --
4.3.4 The first law of thermodynamics for the isothermal process --
4.3.5 The first law of thermodynamics for the closed process --
4.4 Calculating the ideal gas internal energy and enthalpy changes --
4.4.1 Calculating the ideal gas internal energy change --
4.4.2 Calculating the ideal gas enthalpy change --
4.5 The first law of thermodynamics for ideal gases --
4.5.1 The first law of thermodynamics for ideal gas isothermal process --
4.6 The Meyer equation --
4.7 Summary 5. The second law of thermodynamics --
5.1 Introduction --
5.2 The observed phenomena associated with the thermal-mechanical transformations --
5.2.1 Phenomena associated with the transformation of heat energy into mechanical energy --
5.2.1.1 Types of heat engines in terms of their ability to operate continuously --
5.2.1.2 The cyclic (periodical) operating engine --
5.2.1.3 The no-COE --
5.2.2 Phenomena associated with the transformation of mechanical energy into thermal energy --
5.2.3 Phenomena associated with the heat transfer when two objects (hot and cold) are contacted --
5.3 The second law of thermodynamics --
5.4 The thermodynamic cycle --
5.4.1 The direct thermodynamic (power) cycle --
5.4.2 The reverse thermodynamic cycle --
5.4.3 Notes about thermodynamic cycles and cyclic operating machines --
5.4.4 Evaluating thermodynamic cycles --
5.4.4.1 Evaluating engine cycles (the direct cycles) --
5.4.5 The equipollent thermodynamic cycles --
5.5 The Carnot cycle --
5.6 The reverse Carnot cycle --
5.7 Introduction to Carnot theorem (existing formulations of Carnot theory) --
5.8 Entropy --
5.9 Heat regeneration --
5.9.1 Basic concepts and definitions --
5.9.1.1 The regeneratable cycle --
5.9.1.2 The fully reversible regeneratable --
Cycle --
5.9.1.3 The regenerative cycle --
5.9.1.4 The nonregenerative cycle --
5.9.1.5 The nonregeneratable cycle --
5.9.2 The heat regenerator --
5.9.3 About cycle's ability for heat regeneration --
5.9.3.1 The regeneratability condition --
5.9.3.2 Discussing the regeneratability of some direct thermodynamic cycles --
5.10 About the theoretical realization of reversible gas state change processes: in brief (the full analysis in the second volume) --
5.10.1 Introduction --
5.10.2 About the imaginary models in thermodynamics --
5.10.3 The traditional/classical model/method for realizing a reversible process --
5.11 Summary --
Chapter endnotes About the author --
Index.
Series Title: Thermal science and energy engineering collection.
Responsibility: Moufid I. Helal.

Abstract:

In this book, an almost new approach to modern thermodynamics has been applied. One or more useful qualitative discussion statements have been extracted from each equation. These and other important statements were numbered and their titles were situated in an index entitled "Helal and Others' statements, definitions and rules." This ensures very quick obtaining of the required (for discussing and solving problems) statements, rules, definitions, equations, and their theoretical base that much eases reader's qualitative discussions and calculations. Almost all ideal gas closed system thermodynamic topics are either discussed in depth or deeply abbreviated. The topics discussed in depth are either new original ones or valuable classical ones that increase reader's ability for better understanding but are overlooked or deeply abbreviated in modern thermodynamic books. In both cases, they are significantly improved. The main five new ideas that are discussed in depth in this book are: (1) The ideal gas polytropic process for Cv = f(T) and its analysis (Chapter 6, Part I), (2) The theoretical realization of reversible gas state change processes ( 5-10), (3) Helal cycle (s 7-5-2), (4) Helal graphical method for comparing and discussing power cycles ( 7-5-4), and (5) the imperfection in the classical proof of Carnot's efficiency (theorem) and its exclusion (Chapter 7, final section). The deeply abbreviated topics are rigorously discussed in depth in the majority of modern thermodynamic books. To dissipate any misunderstanding, the equations and statements that can be misunderstood are followed by explanatory sentences (see equation 1-38 and the paragraph following it).

Reviews

User-contributed reviews
Retrieving GoodReads reviews...
Retrieving DOGObooks reviews...

Tags

Be the first.
Confirm this request

You may have already requested this item. Please select Ok if you would like to proceed with this request anyway.

Linked Data


\n\n

Primary Entity<\/h3>\n
<http:\/\/www.worldcat.org\/oclc\/1000560268<\/a>> # Graphical thermodynamics and ideal gas power cycles : ideal gas thermodynamics in brief<\/span>\n\u00A0\u00A0\u00A0\u00A0a \nschema:MediaObject<\/a>, schema:CreativeWork<\/a>, schema:Book<\/a> ;\u00A0\u00A0\u00A0\nlibrary:oclcnum<\/a> \"1000560268<\/span>\" ;\u00A0\u00A0\u00A0\nlibrary:placeOfPublication<\/a> <http:\/\/id.loc.gov\/vocabulary\/countries\/nyu<\/a>> ;\u00A0\u00A0\u00A0\nschema:about<\/a> <http:\/\/experiment.worldcat.org\/entity\/work\/data\/4458763346#Thing\/polytropic_state_change_process<\/a>> ; # polytropic state change process<\/span>\n\u00A0\u00A0\u00A0\nschema:about<\/a> <http:\/\/experiment.worldcat.org\/entity\/work\/data\/4458763346#Thing\/the_regeneratability_condition<\/a>> ; # the regeneratability condition<\/span>\n\u00A0\u00A0\u00A0\nschema:about<\/a> <http:\/\/experiment.worldcat.org\/entity\/work\/data\/4458763346#Thing\/cycle_s_ability_for_heat_regeneration<\/a>> ; # cycle\'s ability for heat regeneration<\/span>\n\u00A0\u00A0\u00A0\nschema:about<\/a> <http:\/\/experiment.worldcat.org\/entity\/work\/data\/4458763346#Thing\/carnot<\/a>> ; # Carnot<\/span>\n\u00A0\u00A0\u00A0\nschema:about<\/a> <http:\/\/experiment.worldcat.org\/entity\/work\/data\/4458763346#Thing\/helal_method<\/a>> ; # Helal method<\/span>\n\u00A0\u00A0\u00A0\nschema:about<\/a> <http:\/\/experiment.worldcat.org\/entity\/work\/data\/4458763346#Thing\/closed_thermodynamic_system<\/a>> ; # closed thermodynamic system<\/span>\n\u00A0\u00A0\u00A0\nschema:about<\/a> <http:\/\/experiment.worldcat.org\/entity\/work\/data\/4458763346#Topic\/science_history<\/a>> ; # SCIENCE \/ History<\/span>\n\u00A0\u00A0\u00A0\nschema:about<\/a> <http:\/\/experiment.worldcat.org\/entity\/work\/data\/4458763346#Thing\/reversible_cycle_recognizing_thermodynamic_properties<\/a>> ; # reversible cycle recognizing thermodynamic properties<\/span>\n\u00A0\u00A0\u00A0\nschema:about<\/a> <http:\/\/experiment.worldcat.org\/entity\/work\/data\/4458763346#Thing\/carnot_s_efficiency<\/a>> ; # Carnot\'s efficiency<\/span>\n\u00A0\u00A0\u00A0\nschema:about<\/a> <http:\/\/experiment.worldcat.org\/entity\/work\/data\/4458763346#Thing\/ericsson_and_dual_cycles<\/a>> ; # Ericsson and Dual cycles<\/span>\n\u00A0\u00A0\u00A0\nschema:about<\/a> <http:\/\/experiment.worldcat.org\/entity\/work\/data\/4458763346#Thing\/the_imperfection_in_the_classical_proof_of_carnot_s_efficiency_theorem_and_its_exclusion<\/a>> ; # the imperfection in the classical proof of Carnot\'s efficiency (theorem) and its exclusion<\/span>\n\u00A0\u00A0\u00A0\nschema:about<\/a> <http:\/\/dewey.info\/class\/509.4209032\/e23\/<\/a>> ;\u00A0\u00A0\u00A0\nschema:about<\/a> <http:\/\/experiment.worldcat.org\/entity\/work\/data\/4458763346#Thing\/absolutely_reversible_cycle<\/a>> ; # absolutely reversible cycle<\/span>\n\u00A0\u00A0\u00A0\nschema:about<\/a> <http:\/\/experiment.worldcat.org\/entity\/work\/data\/4458763346#Topic\/thermodynamics<\/a>> ; # Thermodynamics<\/span>\n\u00A0\u00A0\u00A0\nschema:about<\/a> <http:\/\/experiment.worldcat.org\/entity\/work\/data\/4458763346#Thing\/thermal_efficiency<\/a>> ; # thermal efficiency<\/span>\n\u00A0\u00A0\u00A0\nschema:about<\/a> <http:\/\/experiment.worldcat.org\/entity\/work\/data\/4458763346#Thing\/second_law_of_thermodynamics<\/a>> ; # second law of thermodynamics<\/span>\n\u00A0\u00A0\u00A0\nschema:about<\/a> <http:\/\/experiment.worldcat.org\/entity\/work\/data\/4458763346#Thing\/the_equivalent_thermodynamic_cycles<\/a>> ; # the equivalent thermodynamic cycles<\/span>\n\u00A0\u00A0\u00A0\nschema:about<\/a> <http:\/\/experiment.worldcat.org\/entity\/work\/data\/4458763346#Thing\/the_theoretical_realization_of_reversible_gas_state_change_processes<\/a>> ; # the theoretical realization of reversible gas state change processes<\/span>\n\u00A0\u00A0\u00A0\nschema:about<\/a> <http:\/\/experiment.worldcat.org\/entity\/work\/data\/4458763346#Thing\/heat_regeneration_ideal_gas_property_tables<\/a>> ; # heat regeneration; ideal gas property tables<\/span>\n\u00A0\u00A0\u00A0\nschema:about<\/a> <http:\/\/experiment.worldcat.org\/entity\/work\/data\/4458763346#Topic\/ideal_gas_law<\/a>> ; # Ideal gas law<\/span>\n\u00A0\u00A0\u00A0\nschema:about<\/a> <http:\/\/experiment.worldcat.org\/entity\/work\/data\/4458763346#Thing\/a_new_polytropic_ideal_gas_state_change_process<\/a>> ; # a new, polytropic ideal gas state change process<\/span>\n\u00A0\u00A0\u00A0\nschema:about<\/a> <http:\/\/experiment.worldcat.org\/entity\/work\/data\/4458763346#Thing\/stirling_cycle<\/a>> ; # Stirling cycle<\/span>\n\u00A0\u00A0\u00A0\nschema:about<\/a> <http:\/\/experiment.worldcat.org\/entity\/work\/data\/4458763346#Thing\/helal_air_standard_cycle<\/a>> ; # Helal air standard cycle<\/span>\n\u00A0\u00A0\u00A0\nschema:author<\/a> <http:\/\/experiment.worldcat.org\/entity\/work\/data\/4458763346#Person\/helal_moufid_i<\/a>> ; # Moufid I. Helal<\/span>\n\u00A0\u00A0\u00A0\nschema:bookFormat<\/a> schema:EBook<\/a> ;\u00A0\u00A0\u00A0\nschema:datePublished<\/a> \"2017<\/span>\" ;\u00A0\u00A0\u00A0\nschema:description<\/a> \"In this book, an almost new approach to modern thermodynamics has been applied. One or more useful qualitative discussion statements have been extracted from each equation. These and other important statements were numbered and their titles were situated in an index entitled \"Helal and Others\' statements, definitions and rules.\" This ensures very quick obtaining of the required (for discussing and solving problems) statements, rules, definitions, equations, and their theoretical base that much eases reader\'s qualitative discussions and calculations. Almost all ideal gas closed system thermodynamic topics are either discussed in depth or deeply abbreviated. The topics discussed in depth are either new original ones or valuable classical ones that increase reader\'s ability for better understanding but are overlooked or deeply abbreviated in modern thermodynamic books. In both cases, they are significantly improved. The main five new ideas that are discussed in depth in this book are: (1) The ideal gas polytropic process for Cv = f(T) and its analysis (Chapter 6, Part I), (2) The theoretical realization of reversible gas state change processes ( 5-10), (3) Helal cycle (s 7-5-2), (4) Helal graphical method for comparing and discussing power cycles ( 7-5-4), and (5) the imperfection in the classical proof of Carnot\'s efficiency (theorem) and its exclusion (Chapter 7, final section). The deeply abbreviated topics are rigorously discussed in depth in the majority of modern thermodynamic books. To dissipate any misunderstanding, the equations and statements that can be misunderstood are followed by explanatory sentences (see equation 1-38 and the paragraph following it).<\/span>\"@en<\/a> ;\u00A0\u00A0\u00A0\nschema:description<\/a> \"1. Basic concepts and definitions -- 1.1 Unit systems -- 1.1.1 Introduction -- 1.1.2 The international system of units -- 1.1.2.1 Deriving some secondary units from the primary ones -- 1.1.3 The U.S. customary system (also known as the English system) -- 1.1.4 The technical unit system -- 1.1.5 Force and mass main units\' conversions -- 1.1.6 Weight of a body -- 1.1.7 Pressure units -- 1.1.8 Others\' definitions -- 1.1.9 Energy units -- 1.1.10 Temperature units -- 1.1.11 About dimensions\' units in the calculating equations -- 1.2 Calculations and discussions in thermodynamics -- 1.2.1 Calculating the area under a plane curve -- 1.2.1.1 Graphical calculation of the area under y = f(x) curve -- 1.2.1.2 Analytical calculation of the area under y = f(x) curve -- 1.2.1.3 Tabular calculation of the area under y = f(x) curve -- 1.2.2 Tabular determination of y-value versus a given x-value -- 1.2.3 Difference between two functions of the same variable -- 1.3 Summary -- Chapter endnotes<\/span>\"@en<\/a> ;\u00A0\u00A0\u00A0\nschema:exampleOfWork<\/a> <http:\/\/worldcat.org\/entity\/work\/id\/4458763346<\/a>> ;\u00A0\u00A0\u00A0\nschema:genre<\/a> \"Electronic books<\/span>\"@en<\/a> ;\u00A0\u00A0\u00A0\nschema:inLanguage<\/a> \"en<\/span>\" ;\u00A0\u00A0\u00A0\nschema:isPartOf<\/a> <http:\/\/experiment.worldcat.org\/entity\/work\/data\/4458763346#Series\/thermal_science_and_energy_engineering_collection<\/a>> ; # Thermal science and energy engineering collection.<\/span>\n\u00A0\u00A0\u00A0\nschema:isSimilarTo<\/a> <http:\/\/worldcat.org\/entity\/work\/data\/4458763346#CreativeWork\/<\/a>> ;\u00A0\u00A0\u00A0\nschema:name<\/a> \"Graphical thermodynamics and ideal gas power cycles : ideal gas thermodynamics in brief<\/span>\"@en<\/a> ;\u00A0\u00A0\u00A0\nschema:productID<\/a> \"1000560268<\/span>\" ;\u00A0\u00A0\u00A0\nschema:url<\/a> <http:\/\/www.momentumpress.net\/books\/graphical-thermodynamics-and-ideal-gas-power-cycles-ideal-gas-thermodynamics-brief<\/a>> ;\u00A0\u00A0\u00A0\nschema:url<\/a> <https:\/\/login.gbcprx01.georgebrown.ca\/login?url=http:\/\/search.ebscohost.com\/login.aspx?direct=true&scope=site&db=e000xna&AN=1569214<\/a>> ;\u00A0\u00A0\u00A0\nschema:url<\/a> <http:\/\/search.ebscohost.com\/login.aspx?direct=true&scope=site&db=nlebk&db=nlabk&AN=1569214<\/a>> ;\u00A0\u00A0\u00A0\nschema:url<\/a> <http:\/\/www.vlebooks.com\/vleweb\/product\/openreader?id=none&isbn=9781606505076<\/a>> ;\u00A0\u00A0\u00A0\nschema:url<\/a> <http:\/\/search.ebscohost.com\/login.aspx?direct=true&scope=site&db=nlebk&AN=1569214<\/a>> ;\u00A0\u00A0\u00A0\nschema:url<\/a> <https:\/\/nl.idm.oclc.org\/login?url=http:\/\/search.ebscohost.com\/login.aspx?direct=true&scope=site&db=nlebk&AN=1569214<\/a>> ;\u00A0\u00A0\u00A0\nschema:url<\/a> <http:\/\/lib.myilibrary.com?id=1025167<\/a>> ;\u00A0\u00A0\u00A0\nschema:workExample<\/a> <http:\/\/worldcat.org\/isbn\/9781606505076<\/a>> ;\u00A0\u00A0\u00A0\nwdrs:describedby<\/a> <http:\/\/www.worldcat.org\/title\/-\/oclc\/1000560268<\/a>> ;\u00A0\u00A0\u00A0\u00A0.\n\n\n<\/div>\n\n

Related Entities<\/h3>\n
<http:\/\/dewey.info\/class\/509.4209032\/e23\/<\/a>>\u00A0\u00A0\u00A0\u00A0a \nschema:Intangible<\/a> ;\u00A0\u00A0\u00A0\u00A0.\n\n\n<\/div>\n
<http:\/\/experiment.worldcat.org\/entity\/work\/data\/4458763346#Person\/helal_moufid_i<\/a>> # Moufid I. Helal<\/span>\n\u00A0\u00A0\u00A0\u00A0a \nschema:Person<\/a> ;\u00A0\u00A0\u00A0\nschema:familyName<\/a> \"Helal<\/span>\" ;\u00A0\u00A0\u00A0\nschema:givenName<\/a> \"Moufid I.<\/span>\" ;\u00A0\u00A0\u00A0\nschema:name<\/a> \"Moufid I. Helal<\/span>\" ;\u00A0\u00A0\u00A0\u00A0.\n\n\n<\/div>\n
<http:\/\/experiment.worldcat.org\/entity\/work\/data\/4458763346#Series\/thermal_science_and_energy_engineering_collection<\/a>> # Thermal science and energy engineering collection.<\/span>\n\u00A0\u00A0\u00A0\u00A0a \nbgn:PublicationSeries<\/a> ;\u00A0\u00A0\u00A0\nschema:hasPart<\/a> <http:\/\/www.worldcat.org\/oclc\/1000560268<\/a>> ; # Graphical thermodynamics and ideal gas power cycles : ideal gas thermodynamics in brief<\/span>\n\u00A0\u00A0\u00A0\nschema:name<\/a> \"Thermal science and energy engineering collection.<\/span>\" ;\u00A0\u00A0\u00A0\nschema:name<\/a> \"Thermal science and energy engineering collection<\/span>\" ;\u00A0\u00A0\u00A0\u00A0.\n\n\n<\/div>\n
<http:\/\/experiment.worldcat.org\/entity\/work\/data\/4458763346#Thing\/a_new_polytropic_ideal_gas_state_change_process<\/a>> # a new, polytropic ideal gas state change process<\/span>\n\u00A0\u00A0\u00A0\u00A0a \nschema:Thing<\/a> ;\u00A0\u00A0\u00A0\nschema:name<\/a> \"a new, polytropic ideal gas state change process<\/span>\" ;\u00A0\u00A0\u00A0\u00A0.\n\n\n<\/div>\n
<http:\/\/experiment.worldcat.org\/entity\/work\/data\/4458763346#Thing\/absolutely_reversible_cycle<\/a>> # absolutely reversible cycle<\/span>\n\u00A0\u00A0\u00A0\u00A0a \nschema:Thing<\/a> ;\u00A0\u00A0\u00A0\nschema:name<\/a> \"absolutely reversible cycle<\/span>\" ;\u00A0\u00A0\u00A0\u00A0.\n\n\n<\/div>\n
<http:\/\/experiment.worldcat.org\/entity\/work\/data\/4458763346#Thing\/carnot<\/a>> # Carnot<\/span>\n\u00A0\u00A0\u00A0\u00A0a \nschema:Thing<\/a> ;\u00A0\u00A0\u00A0\nschema:name<\/a> \"Carnot<\/span>\" ;\u00A0\u00A0\u00A0\u00A0.\n\n\n<\/div>\n
<http:\/\/experiment.worldcat.org\/entity\/work\/data\/4458763346#Thing\/carnot_s_efficiency<\/a>> # Carnot\'s efficiency<\/span>\n\u00A0\u00A0\u00A0\u00A0a \nschema:Thing<\/a> ;\u00A0\u00A0\u00A0\nschema:name<\/a> \"Carnot\'s efficiency<\/span>\" ;\u00A0\u00A0\u00A0\u00A0.\n\n\n<\/div>\n
<http:\/\/experiment.worldcat.org\/entity\/work\/data\/4458763346#Thing\/closed_thermodynamic_system<\/a>> # closed thermodynamic system<\/span>\n\u00A0\u00A0\u00A0\u00A0a \nschema:Thing<\/a> ;\u00A0\u00A0\u00A0\nschema:name<\/a> \"closed thermodynamic system<\/span>\" ;\u00A0\u00A0\u00A0\u00A0.\n\n\n<\/div>\n
<http:\/\/experiment.worldcat.org\/entity\/work\/data\/4458763346#Thing\/cycle_s_ability_for_heat_regeneration<\/a>> # cycle\'s ability for heat regeneration<\/span>\n\u00A0\u00A0\u00A0\u00A0a \nschema:Thing<\/a> ;\u00A0\u00A0\u00A0\nschema:name<\/a> \"cycle\'s ability for heat regeneration<\/span>\" ;\u00A0\u00A0\u00A0\u00A0.\n\n\n<\/div>\n
<http:\/\/experiment.worldcat.org\/entity\/work\/data\/4458763346#Thing\/ericsson_and_dual_cycles<\/a>> # Ericsson and Dual cycles<\/span>\n\u00A0\u00A0\u00A0\u00A0a \nschema:Thing<\/a> ;\u00A0\u00A0\u00A0\nschema:name<\/a> \"Ericsson and Dual cycles<\/span>\" ;\u00A0\u00A0\u00A0\u00A0.\n\n\n<\/div>\n
<http:\/\/experiment.worldcat.org\/entity\/work\/data\/4458763346#Thing\/heat_regeneration_ideal_gas_property_tables<\/a>> # heat regeneration; ideal gas property tables<\/span>\n\u00A0\u00A0\u00A0\u00A0a \nschema:Thing<\/a> ;\u00A0\u00A0\u00A0\nschema:name<\/a> \"heat regeneration; ideal gas property tables<\/span>\" ;\u00A0\u00A0\u00A0\u00A0.\n\n\n<\/div>\n
<http:\/\/experiment.worldcat.org\/entity\/work\/data\/4458763346#Thing\/helal_air_standard_cycle<\/a>> # Helal air standard cycle<\/span>\n\u00A0\u00A0\u00A0\u00A0a \nschema:Thing<\/a> ;\u00A0\u00A0\u00A0\nschema:name<\/a> \"Helal air standard cycle<\/span>\" ;\u00A0\u00A0\u00A0\u00A0.\n\n\n<\/div>\n
<http:\/\/experiment.worldcat.org\/entity\/work\/data\/4458763346#Thing\/helal_method<\/a>> # Helal method<\/span>\n\u00A0\u00A0\u00A0\u00A0a \nschema:Thing<\/a> ;\u00A0\u00A0\u00A0\nschema:name<\/a> \"Helal method<\/span>\" ;\u00A0\u00A0\u00A0\u00A0.\n\n\n<\/div>\n
<http:\/\/experiment.worldcat.org\/entity\/work\/data\/4458763346#Thing\/polytropic_state_change_process<\/a>> # polytropic state change process<\/span>\n\u00A0\u00A0\u00A0\u00A0a \nschema:Thing<\/a> ;\u00A0\u00A0\u00A0\nschema:name<\/a> \"polytropic state change process<\/span>\" ;\u00A0\u00A0\u00A0\u00A0.\n\n\n<\/div>\n
<http:\/\/experiment.worldcat.org\/entity\/work\/data\/4458763346#Thing\/reversible_cycle_recognizing_thermodynamic_properties<\/a>> # reversible cycle recognizing thermodynamic properties<\/span>\n\u00A0\u00A0\u00A0\u00A0a \nschema:Thing<\/a> ;\u00A0\u00A0\u00A0\nschema:name<\/a> \"reversible cycle recognizing thermodynamic properties<\/span>\" ;\u00A0\u00A0\u00A0\u00A0.\n\n\n<\/div>\n
<http:\/\/experiment.worldcat.org\/entity\/work\/data\/4458763346#Thing\/second_law_of_thermodynamics<\/a>> # second law of thermodynamics<\/span>\n\u00A0\u00A0\u00A0\u00A0a \nschema:Thing<\/a> ;\u00A0\u00A0\u00A0\nschema:name<\/a> \"second law of thermodynamics<\/span>\" ;\u00A0\u00A0\u00A0\u00A0.\n\n\n<\/div>\n
<http:\/\/experiment.worldcat.org\/entity\/work\/data\/4458763346#Thing\/stirling_cycle<\/a>> # Stirling cycle<\/span>\n\u00A0\u00A0\u00A0\u00A0a \nschema:Thing<\/a> ;\u00A0\u00A0\u00A0\nschema:name<\/a> \"Stirling cycle<\/span>\" ;\u00A0\u00A0\u00A0\u00A0.\n\n\n<\/div>\n
<http:\/\/experiment.worldcat.org\/entity\/work\/data\/4458763346#Thing\/the_equivalent_thermodynamic_cycles<\/a>> # the equivalent thermodynamic cycles<\/span>\n\u00A0\u00A0\u00A0\u00A0a \nschema:Thing<\/a> ;\u00A0\u00A0\u00A0\nschema:name<\/a> \"the equivalent thermodynamic cycles<\/span>\" ;\u00A0\u00A0\u00A0\u00A0.\n\n\n<\/div>\n
<http:\/\/experiment.worldcat.org\/entity\/work\/data\/4458763346#Thing\/the_imperfection_in_the_classical_proof_of_carnot_s_efficiency_theorem_and_its_exclusion<\/a>> # the imperfection in the classical proof of Carnot\'s efficiency (theorem) and its exclusion<\/span>\n\u00A0\u00A0\u00A0\u00A0a \nschema:Thing<\/a> ;\u00A0\u00A0\u00A0\nschema:name<\/a> \"the imperfection in the classical proof of Carnot\'s efficiency (theorem) and its exclusion<\/span>\" ;\u00A0\u00A0\u00A0\u00A0.\n\n\n<\/div>\n
<http:\/\/experiment.worldcat.org\/entity\/work\/data\/4458763346#Thing\/the_regeneratability_condition<\/a>> # the regeneratability condition<\/span>\n\u00A0\u00A0\u00A0\u00A0a \nschema:Thing<\/a> ;\u00A0\u00A0\u00A0\nschema:name<\/a> \"the regeneratability condition<\/span>\" ;\u00A0\u00A0\u00A0\u00A0.\n\n\n<\/div>\n
<http:\/\/experiment.worldcat.org\/entity\/work\/data\/4458763346#Thing\/the_theoretical_realization_of_reversible_gas_state_change_processes<\/a>> # the theoretical realization of reversible gas state change processes<\/span>\n\u00A0\u00A0\u00A0\u00A0a \nschema:Thing<\/a> ;\u00A0\u00A0\u00A0\nschema:name<\/a> \"the theoretical realization of reversible gas state change processes<\/span>\" ;\u00A0\u00A0\u00A0\u00A0.\n\n\n<\/div>\n
<http:\/\/experiment.worldcat.org\/entity\/work\/data\/4458763346#Thing\/thermal_efficiency<\/a>> # thermal efficiency<\/span>\n\u00A0\u00A0\u00A0\u00A0a \nschema:Thing<\/a> ;\u00A0\u00A0\u00A0\nschema:name<\/a> \"thermal efficiency<\/span>\" ;\u00A0\u00A0\u00A0\u00A0.\n\n\n<\/div>\n
<http:\/\/experiment.worldcat.org\/entity\/work\/data\/4458763346#Topic\/ideal_gas_law<\/a>> # Ideal gas law<\/span>\n\u00A0\u00A0\u00A0\u00A0a \nschema:Intangible<\/a> ;\u00A0\u00A0\u00A0\nschema:name<\/a> \"Ideal gas law<\/span>\"@en<\/a> ;\u00A0\u00A0\u00A0\u00A0.\n\n\n<\/div>\n
<http:\/\/experiment.worldcat.org\/entity\/work\/data\/4458763346#Topic\/science_history<\/a>> # SCIENCE \/ History<\/span>\n\u00A0\u00A0\u00A0\u00A0a \nschema:Intangible<\/a> ;\u00A0\u00A0\u00A0\nschema:name<\/a> \"SCIENCE \/ History<\/span>\"@en<\/a> ;\u00A0\u00A0\u00A0\u00A0.\n\n\n<\/div>\n
<http:\/\/experiment.worldcat.org\/entity\/work\/data\/4458763346#Topic\/thermodynamics<\/a>> # Thermodynamics<\/span>\n\u00A0\u00A0\u00A0\u00A0a \nschema:Intangible<\/a> ;\u00A0\u00A0\u00A0\nschema:name<\/a> \"Thermodynamics<\/span>\"@en<\/a> ;\u00A0\u00A0\u00A0\u00A0.\n\n\n<\/div>\n
<http:\/\/id.loc.gov\/vocabulary\/countries\/nyu<\/a>>\u00A0\u00A0\u00A0\u00A0a \nschema:Place<\/a> ;\u00A0\u00A0\u00A0\ndcterms:identifier<\/a> \"nyu<\/span>\" ;\u00A0\u00A0\u00A0\u00A0.\n\n\n<\/div>\n
<http:\/\/lib.myilibrary.com?id=1025167<\/a>>\u00A0\u00A0\u00A0\nrdfs:comment<\/a> \"Connect to MyiLibrary resource.<\/span>\" ;\u00A0\u00A0\u00A0\u00A0.\n\n\n<\/div>\n
<http:\/\/search.ebscohost.com\/login.aspx?direct=true&scope=site&db=nlebk&AN=1569214<\/a>>\u00A0\u00A0\u00A0\nrdfs:comment<\/a> \"Available to Stanford-affiliated users.<\/span>\" ;\u00A0\u00A0\u00A0\u00A0.\n\n\n<\/div>\n
<http:\/\/worldcat.org\/entity\/work\/data\/4458763346#CreativeWork\/<\/a>>\u00A0\u00A0\u00A0\u00A0a \nschema:CreativeWork<\/a> ;\u00A0\u00A0\u00A0\nschema:description<\/a> \"Print version:<\/span>\" ;\u00A0\u00A0\u00A0\nschema:isSimilarTo<\/a> <http:\/\/www.worldcat.org\/oclc\/1000560268<\/a>> ; # Graphical thermodynamics and ideal gas power cycles : ideal gas thermodynamics in brief<\/span>\n\u00A0\u00A0\u00A0\u00A0.\n\n\n<\/div>\n
<http:\/\/worldcat.org\/isbn\/9781606505076<\/a>>\u00A0\u00A0\u00A0\u00A0a \nschema:ProductModel<\/a> ;\u00A0\u00A0\u00A0\nschema:isbn<\/a> \"1606505076<\/span>\" ;\u00A0\u00A0\u00A0\nschema:isbn<\/a> \"9781606505076<\/span>\" ;\u00A0\u00A0\u00A0\u00A0.\n\n\n<\/div>\n
<http:\/\/www.worldcat.org\/title\/-\/oclc\/1000560268<\/a>>\u00A0\u00A0\u00A0\u00A0a \ngenont:InformationResource<\/a>, genont:ContentTypeGenericResource<\/a> ;\u00A0\u00A0\u00A0\nschema:about<\/a> <http:\/\/www.worldcat.org\/oclc\/1000560268<\/a>> ; # Graphical thermodynamics and ideal gas power cycles : ideal gas thermodynamics in brief<\/span>\n\u00A0\u00A0\u00A0\nschema:dateModified<\/a> \"2019-09-03<\/span>\" ;\u00A0\u00A0\u00A0\nvoid:inDataset<\/a> <http:\/\/purl.oclc.org\/dataset\/WorldCat<\/a>> ;\u00A0\u00A0\u00A0\u00A0.\n\n\n<\/div>\n\n

Content-negotiable representations<\/p>\n