Added(A)/Deleted(D) following books

 M  1000_solved_Problems_in_Fluid_Mechanics_includes_Hydraulic_machines_by_K.Subramanya/README.txt
M  1000_solved_Problems_in_Fluid_Mechanics_includes_Hydraulic_machines_by_K.Subramanya/chapter10_2.ipynb
M  1000_solved_Problems_in_Fluid_Mechanics_includes_Hydraulic_machines_by_K.Subramanya/chapter10_3.ipynb
M  1000_solved_Problems_in_Fluid_Mechanics_includes_Hydraulic_machines_by_K.Subramanya/chapter11.ipynb
M  1000_solved_Problems_in_Fluid_Mechanics_includes_Hydraulic_machines_by_K.Subramanya/chapter11_1.ipynb
M  1000_solved_Problems_in_Fluid_Mechanics_includes_Hydraulic_machines_by_K.Subramanya/chapter12_2.ipynb
M  1000_solved_Problems_in_Fluid_Mechanics_includes_Hydraulic_machines_by_K.Subramanya/chapter12_3.ipynb
M  1000_solved_Problems_in_Fluid_Mechanics_includes_Hydraulic_machines_by_K.Subramanya/chapter13_2.ipynb
M  1000_solved_Problems_in_Fluid_Mechanics_includes_Hydraulic_machines_by_K.Subramanya/chapter13_3.ipynb
M  1000_solved_Problems_in_Fluid_Mechanics_includes_Hydraulic_machines_by_K.Subramanya/chapter14_2.ipynb
M  1000_solved_Problems_in_Fluid_Mechanics_includes_Hydraulic_machines_by_K.Subramanya/chapter14_3.ipynb
M  1000_solved_Problems_in_Fluid_Mechanics_includes_Hydraulic_machines_by_K.Subramanya/chapter15_2.ipynb
M  1000_solved_Problems_in_Fluid_Mechanics_includes_Hydraulic_machines_by_K.Subramanya/chapter15_3.ipynb
M  1000_solved_Problems_in_Fluid_Mechanics_includes_Hydraulic_machines_by_K.Subramanya/chapter16_2.ipynb
M  1000_solved_Problems_in_Fluid_Mechanics_includes_Hydraulic_machines_by_K.Subramanya/chapter16_3.ipynb
M  1000_solved_Problems_in_Fluid_Mechanics_includes_Hydraulic_machines_by_K.Subramanya/chapter1_2.ipynb
M  1000_solved_Problems_in_Fluid_Mechanics_includes_Hydraulic_machines_by_K.Subramanya/chapter1_3.ipynb
M  1000_solved_Problems_in_Fluid_Mechanics_includes_Hydraulic_machines_by_K.Subramanya/chapter2_2.ipynb
M  1000_solved_Problems_in_Fluid_Mechanics_includes_Hydraulic_machines_by_K.Subramanya/chapter2_3.ipynb
M  1000_solved_Problems_in_Fluid_Mechanics_includes_Hydraulic_machines_by_K.Subramanya/chapter3.ipynb
M  1000_solved_Problems_in_Fluid_Mechanics_includes_Hydraulic_machines_by_K.Subramanya/chapter3_1.ipynb
M  1000_solved_Problems_in_Fluid_Mechanics_includes_Hydraulic_machines_by_K.Subramanya/chapter4.ipynb
M  1000_solved_Problems_in_Fluid_Mechanics_includes_Hydraulic_machines_by_K.Subramanya/chapter4_1.ipynb
M  1000_solved_Problems_in_Fluid_Mechanics_includes_Hydraulic_machines_by_K.Subramanya/chapter5.ipynb
M  1000_solved_Problems_in_Fluid_Mechanics_includes_Hydraulic_machines_by_K.Subramanya/chapter5_1.ipynb
M  1000_solved_Problems_in_Fluid_Mechanics_includes_Hydraulic_machines_by_K.Subramanya/chapter6_2.ipynb
M  1000_solved_Problems_in_Fluid_Mechanics_includes_Hydraulic_machines_by_K.Subramanya/chapter6_3.ipynb
M  1000_solved_Problems_in_Fluid_Mechanics_includes_Hydraulic_machines_by_K.Subramanya/chapter7_2.ipynb
M  1000_solved_Problems_in_Fluid_Mechanics_includes_Hydraulic_machines_by_K.Subramanya/chapter7_3.ipynb
M  1000_solved_Problems_in_Fluid_Mechanics_includes_Hydraulic_machines_by_K.Subramanya/chapter8_2.ipynb
M  1000_solved_Problems_in_Fluid_Mechanics_includes_Hydraulic_machines_by_K.Subramanya/chapter8_3.ipynb
M  1000_solved_Problems_in_Fluid_Mechanics_includes_Hydraulic_machines_by_K.Subramanya/chapter9_2.ipynb
M  1000_solved_Problems_in_Fluid_Mechanics_includes_Hydraulic_machines_by_K.Subramanya/chapter9_3.ipynb
M  1000_solved_Problems_in_Fluid_Mechanics_includes_Hydraulic_machines_by_K.Subramanya/screenshots/Screenshot_from_2016-01-14_17_01_00.png
M  1000_solved_Problems_in_Fluid_Mechanics_includes_Hydraulic_machines_by_K.Subramanya/screenshots/Screenshot_from_2016-01-14_17_01_00_1.png
M  1000_solved_Problems_in_Fluid_Mechanics_includes_Hydraulic_machines_by_K.Subramanya/screenshots/Screenshot_from_2016-01-14_17_01_25.png
M  1000_solved_Problems_in_Fluid_Mechanics_includes_Hydraulic_machines_by_K.Subramanya/screenshots/Screenshot_from_2016-01-14_17_01_25_1.png
M  1000_solved_Problems_in_Fluid_Mechanics_includes_Hydraulic_machines_by_K.Subramanya/screenshots/Screenshot_from_2016-01-14_17_02_44.png
M  1000_solved_Problems_in_Fluid_Mechanics_includes_Hydraulic_machines_by_K.Subramanya/screenshots/Screenshot_from_2016-01-14_17_02_44_1.png
M  A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter25_4.ipynb
M  A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter25_5.ipynb
M  A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter25_6.ipynb
M  A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter26_4.ipynb
M  A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter26_5.ipynb
M  A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter26_6.ipynb
M  A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter27_4.ipynb
M  A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter27_5.ipynb
M  A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter27_6.ipynb
M  A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter28_4.ipynb
M  A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter28_5.ipynb
M  A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter28_6.ipynb
M  A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter29_4.ipynb
M  A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter29_5.ipynb
M  A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter29_6.ipynb
M  A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter30_4.ipynb
M  A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter30_5.ipynb
M  A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter30_6.ipynb
M  A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter31_4.ipynb
M  A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter31_5.ipynb
M  A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter31_6.ipynb
M  A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter32_4.ipynb
M  A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter32_5.ipynb
M  A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter32_6.ipynb
M  A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter33_4.ipynb
M  A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter33_5.ipynb
M  A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter33_6.ipynb
M  A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter34_4.ipynb
M  A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter34_5.ipynb
M  A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter34_6.ipynb
M  A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter35_4.ipynb
M  A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter35_5.ipynb
M  A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter35_6.ipynb
M  A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter36_4.ipynb
M  A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter36_5.ipynb
M  A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter36_6.ipynb
M  A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter37_4.ipynb
M  A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter37_5.ipynb
M  A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter37_6.ipynb
M  A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter38_4.ipynb
M  A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter38_5.ipynb
M  A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter38_6.ipynb
M  A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter39_4.ipynb
M  A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter39_5.ipynb
M  A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/chapter39_6.ipynb
M  A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/screenshots/chapter29example32_4.png
M  A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/screenshots/chapter29example32_5.png
M  A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/screenshots/chapter29example32_6.png
M  A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/screenshots/chapter29example33_4.png
M  A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/screenshots/chapter29example33_5.png
M  A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/screenshots/chapter29example33_6.png
M  A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/screenshots/chapter32example30_4.png
M  A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/screenshots/chapter32example30_5.png
M  A_Textbook_of_Electrical_Technology_:_AC_and_DC_Machines_(Volume_-_2)_by_A_K_Theraja_B_L_Thereja/screenshots/chapter32example30_6.png
M  A_Textbook_of_Electronic_Circuits_by_R._S._Sedha/Chap10_2.ipynb
M  A_Textbook_of_Electronic_Circuits_by_R._S._Sedha/Chap11_2.ipynb
M  A_Textbook_of_Electronic_Circuits_by_R._S._Sedha/Chap12_2.ipynb
M  A_Textbook_of_Electronic_Circuits_by_R._S._Sedha/Chap13_2.ipynb
M  A_Textbook_of_Electronic_Circuits_by_R._S._Sedha/Chap16_2.ipynb
M  A_Textbook_of_Electronic_Circuits_by_R._S._Sedha/Chap17_2.ipynb
M  A_Textbook_of_Electronic_Circuits_by_R._S._Sedha/Chap18_2.ipynb
M  A_Textbook_of_Electronic_Circuits_by_R._S._Sedha/Chap19_2.ipynb
M  A_Textbook_of_Electronic_Circuits_by_R._S._Sedha/Chap20_2.ipynb
M  A_Textbook_of_Electronic_Circuits_by_R._S._Sedha/Chap21_2.ipynb
M  A_Textbook_of_Electronic_Circuits_by_R._S._Sedha/Chap22_2.ipynb
M  A_Textbook_of_Electronic_Circuits_by_R._S._Sedha/Chap23_2.ipynb
M  A_Textbook_of_Electronic_Circuits_by_R._S._Sedha/Chap24_2.ipynb
M  A_Textbook_of_Electronic_Circuits_by_R._S._Sedha/Chap25_2.ipynb
M  A_Textbook_of_Electronic_Circuits_by_R._S._Sedha/Chap26_2.ipynb
M  A_Textbook_of_Electronic_Circuits_by_R._S._Sedha/Chap27_2.ipynb
M  A_Textbook_of_Electronic_Circuits_by_R._S._Sedha/Chap28_2.ipynb
M  A_Textbook_of_Electronic_Circuits_by_R._S._Sedha/Chap29_2.ipynb
M  A_Textbook_of_Electronic_Circuits_by_R._S._Sedha/Chap30_2.ipynb
M  A_Textbook_of_Electronic_Circuits_by_R._S._Sedha/Chap31_2.ipynb
M  A_Textbook_of_Electronic_Circuits_by_R._S._Sedha/Chap32_2.ipynb
M  A_Textbook_of_Electronic_Circuits_by_R._S._Sedha/Chap33_2.ipynb
M  A_Textbook_of_Electronic_Circuits_by_R._S._Sedha/Chap34_2.ipynb
M  A_Textbook_of_Electronic_Circuits_by_R._S._Sedha/Chap3_2.ipynb
M  A_Textbook_of_Electronic_Circuits_by_R._S._Sedha/Chap5_2.ipynb
M  A_Textbook_of_Electronic_Circuits_by_R._S._Sedha/Chap7_2.ipynb
M  A_Textbook_of_Electronic_Circuits_by_R._S._Sedha/Chap8_2.ipynb
M  A_Textbook_of_Electronic_Circuits_by_R._S._Sedha/Chap9_2.ipynb
M  A_Textbook_of_Electronic_Circuits_by_R._S._Sedha/README.txt
M  A_Textbook_of_Electronic_Circuits_by_R._S._Sedha/screenshots/11DrainCurrentGraph.png
M  A_Textbook_of_Electronic_Circuits_by_R._S._Sedha/screenshots/18VceVsIce.png
M  A_Textbook_of_Electronic_Circuits_by_R._S._Sedha/screenshots/24GainGraph.png
M  Analog_Electronics_by_U._A._Bakshi_And_A._P._Godse/README.txt
M  Applied_Thermodynamics_and_Engineering_by_T._D._Eastop_and_A._Mcconkey/README.txt
A  Basic_And_Applied_Thermodynamics_by_P._K._Nag/Chapter01.ipynb
A  Basic_And_Applied_Thermodynamics_by_P._K._Nag/Chapter02.ipynb
A  Basic_And_Applied_Thermodynamics_by_P._K._Nag/Chapter03.ipynb
A  Basic_And_Applied_Thermodynamics_by_P._K._Nag/Chapter04.ipynb
A  Basic_And_Applied_Thermodynamics_by_P._K._Nag/Chapter05.ipynb
A  Basic_And_Applied_Thermodynamics_by_P._K._Nag/Chapter10.ipynb
A  Basic_And_Applied_Thermodynamics_by_P._K._Nag/Chapter11.ipynb
A  Basic_And_Applied_Thermodynamics_by_P._K._Nag/Chapter12.ipynb
A  Basic_And_Applied_Thermodynamics_by_P._K._Nag/Chapter13.ipynb
A  Basic_And_Applied_Thermodynamics_by_P._K._Nag/Chapter14.ipynb
A  Basic_And_Applied_Thermodynamics_by_P._K._Nag/Chapter15.ipynb
A  Basic_And_Applied_Thermodynamics_by_P._K._Nag/Chapter16.ipynb
A  Basic_And_Applied_Thermodynamics_by_P._K._Nag/Chapter17.ipynb
A  Basic_And_Applied_Thermodynamics_by_P._K._Nag/Chapter18.ipynb
A  Basic_And_Applied_Thermodynamics_by_P._K._Nag/Chapter19.ipynb
A  Basic_And_Applied_Thermodynamics_by_P._K._Nag/Chapter20.ipynb
A  Basic_And_Applied_Thermodynamics_by_P._K._Nag/Chapter21.ipynb
A  Basic_And_Applied_Thermodynamics_by_P._K._Nag/Chapter22.ipynb
A  Basic_And_Applied_Thermodynamics_by_P._K._Nag/Chapter6.ipynb
A  Basic_And_Applied_Thermodynamics_by_P._K._Nag/Chapter7.ipynb
A  Basic_And_Applied_Thermodynamics_by_P._K._Nag/Chapter8.ipynb
A  Basic_And_Applied_Thermodynamics_by_P._K._Nag/Chapter9.ipynb
A  Basic_And_Applied_Thermodynamics_by_P._K._Nag/screenshots/16.11.png
A  Basic_And_Applied_Thermodynamics_by_P._K._Nag/screenshots/3.3.png
A  Basic_And_Applied_Thermodynamics_by_P._K._Nag/screenshots/7.10.png
R  Basic_Electronics_(Electronics_Engineering)_by_J.B.Gupta/chapter1.ipynb -> Basic_Electronics_(Electronics_Engineering)_by_J_B_Gupta/chapter1.ipynb
R  Basic_Electronics_(Electronics_Engineering)_by_J.B.Gupta/chapter10.ipynb -> Basic_Electronics_(Electronics_Engineering)_by_J_B_Gupta/chapter10.ipynb
R  Basic_Electronics_(Electronics_Engineering)_by_J.B.Gupta/chapter13.ipynb -> Basic_Electronics_(Electronics_Engineering)_by_J_B_Gupta/chapter13.ipynb
R  Basic_Electronics_(Electronics_Engineering)_by_J.B.Gupta/chapter14.ipynb -> Basic_Electronics_(Electronics_Engineering)_by_J_B_Gupta/chapter14.ipynb
R  Basic_Electronics_(Electronics_Engineering)_by_J.B.Gupta/chapter15.ipynb -> Basic_Electronics_(Electronics_Engineering)_by_J_B_Gupta/chapter15.ipynb
R  Basic_Electronics_(Electronics_Engineering)_by_J.B.Gupta/chapter2.ipynb -> Basic_Electronics_(Electronics_Engineering)_by_J_B_Gupta/chapter2.ipynb
R  Basic_Electronics_(Electronics_Engineering)_by_J.B.Gupta/chapter3.ipynb -> Basic_Electronics_(Electronics_Engineering)_by_J_B_Gupta/chapter3.ipynb
R  Basic_Electronics_(Electronics_Engineering)_by_J.B.Gupta/chapter4.ipynb -> Basic_Electronics_(Electronics_Engineering)_by_J_B_Gupta/chapter4.ipynb
R  Basic_Electronics_(Electronics_Engineering)_by_J.B.Gupta/chapter5.ipynb -> Basic_Electronics_(Electronics_Engineering)_by_J_B_Gupta/chapter5.ipynb
R  Basic_Electronics_(Electronics_Engineering)_by_J.B.Gupta/chapter6.ipynb -> Basic_Electronics_(Electronics_Engineering)_by_J_B_Gupta/chapter6.ipynb
R  Basic_Electronics_(Electronics_Engineering)_by_J.B.Gupta/chapter7.ipynb -> Basic_Electronics_(Electronics_Engineering)_by_J_B_Gupta/chapter7.ipynb
R  Basic_Electronics_(Electronics_Engineering)_by_J.B.Gupta/chapter8.ipynb -> Basic_Electronics_(Electronics_Engineering)_by_J_B_Gupta/chapter8.ipynb
R  Basic_Electronics_(Electronics_Engineering)_by_J.B.Gupta/chapter9.ipynb -> Basic_Electronics_(Electronics_Engineering)_by_J_B_Gupta/chapter9.ipynb
R  Basic_Electronics_(Electronics_Engineering)_by_J.B.Gupta/screenshots/Screenshot_(88).png -> Basic_Electronics_(Electronics_Engineering)_by_J_B_Gupta/screenshots/Screenshot_(88).png
R  Basic_Electronics_(Electronics_Engineering)_by_J.B.Gupta/screenshots/Screenshot_(89).png -> Basic_Electronics_(Electronics_Engineering)_by_J_B_Gupta/screenshots/Screenshot_(89).png
R  Basic_Electronics_(Electronics_Engineering)_by_J.B.Gupta/screenshots/Screenshot_(90).png -> Basic_Electronics_(Electronics_Engineering)_by_J_B_Gupta/screenshots/Screenshot_(90).png
M  Coulson_And_Richardsons_Chemical_Engineering,_Volume_2_by_J._M._Coulson,_J._F._Richardson,_J._R._Backhurst_And_J._H._Harker/README.txt
M  Digital_Communications_by_S._Haykin/Chapter1.ipynb
M  Digital_Communications_by_S._Haykin/Chapter2.ipynb
M  Digital_Communications_by_S._Haykin/Chapter3.ipynb
M  Digital_Communications_by_S._Haykin/Chapter4.ipynb
M  Digital_Communications_by_S._Haykin/Chapter5.ipynb
M  Digital_Communications_by_S._Haykin/Chapter6.ipynb
M  Digital_Communications_by_S._Haykin/Chapter7.ipynb
M  Digital_Communications_by_S._Haykin/Chapter8.ipynb
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M  Electrical_Engineering_-_Principles_And_Applications_by_Allan._R._Hambley/chapter16_1.ipynb
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M  Electronic_Communication_by_D._Roddy/Chapter10_Angle_Modulation_1.ipynb
M  Electronic_Communication_by_D._Roddy/Chapter11_Pulse_Modulation_1.ipynb
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M  Electronic_Communication_by_D._Roddy/Chapter13_Transmission_Lines_And_Cables_1.ipynb
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M  Electronics_Devices_And_Circuits_by_S._Salivahanan,_N._S._Kumar_And_A._Vallavaraj/Ch11_1.ipynb
M  Electronics_Devices_And_Circuits_by_S._Salivahanan,_N._S._Kumar_And_A._Vallavaraj/Ch12_1.ipynb
M  Electronics_Devices_And_Circuits_by_S._Salivahanan,_N._S._Kumar_And_A._Vallavaraj/Ch14_1.ipynb
M  Electronics_Devices_And_Circuits_by_S._Salivahanan,_N._S._Kumar_And_A._Vallavaraj/Ch15_1.ipynb
M  Electronics_Devices_And_Circuits_by_S._Salivahanan,_N._S._Kumar_And_A._Vallavaraj/Ch16_1.ipynb
M  Electronics_Devices_And_Circuits_by_S._Salivahanan,_N._S._Kumar_And_A._Vallavaraj/Ch17_1.ipynb
M  Electronics_Devices_And_Circuits_by_S._Salivahanan,_N._S._Kumar_And_A._Vallavaraj/Ch18_1.ipynb
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M  Electronics_Devices_And_Circuits_by_S._Salivahanan,_N._S._Kumar_And_A._Vallavaraj/Ch20_1.ipynb
M  Electronics_Devices_And_Circuits_by_S._Salivahanan,_N._S._Kumar_And_A._Vallavaraj/Ch21_1.ipynb
M  Electronics_Devices_And_Circuits_by_S._Salivahanan,_N._S._Kumar_And_A._Vallavaraj/Ch24_1.ipynb
M  Electronics_Devices_And_Circuits_by_S._Salivahanan,_N._S._Kumar_And_A._Vallavaraj/Ch3_1.ipynb
M  Electronics_Devices_And_Circuits_by_S._Salivahanan,_N._S._Kumar_And_A._Vallavaraj/Ch4_1.ipynb
M  Electronics_Devices_And_Circuits_by_S._Salivahanan,_N._S._Kumar_And_A._Vallavaraj/Ch5_1.ipynb
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M  Electronics_Devices_And_Circuits_by_S._Salivahanan,_N._S._Kumar_And_A._Vallavaraj/Ch7_1.ipynb
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M  Engineering_Mechanics_of_Solids_by_Popov_E_P/chapter12_7.ipynb
M  Engineering_Mechanics_of_Solids_by_Popov_E_P/chapter12_8.ipynb
M  Engineering_Mechanics_of_Solids_by_Popov_E_P/chapter13_6.ipynb
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M  Engineering_Mechanics_of_Solids_by_Popov_E_P/chapter4_7.ipynb
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M  Engineering_Mechanics_of_Solids_by_Popov_E_P/chapter5_7.ipynb
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M  Fiber_Optic_Communications:_Fundamentals_and_Applications_by_S._Kumar_and_M._J._Deen/Chapter3_1.ipynb
M  Fiber_Optic_Communications:_Fundamentals_and_Applications_by_S._Kumar_and_M._J._Deen/Chapter4_1.ipynb
M  Fiber_Optic_Communications:_Fundamentals_and_Applications_by_S._Kumar_and_M._J._Deen/Chapter5_1.ipynb
M  Fiber_Optic_Communications:_Fundamentals_and_Applications_by_S._Kumar_and_M._J._Deen/Chapter6_1.ipynb
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M  Fiber_Optic_Communications:_Fundamentals_and_Applications_by_S._Kumar_and_M._J._Deen/Chapter8_1.ipynb
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M  Linear_Algebra_by_K._Hoffman_and_R._Kunze/Chapter1.ipynb
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M  Linear_Algebra_by_K._Hoffman_and_R._Kunze/Chapter2.ipynb
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M  Linear_Algebra_by_K._Hoffman_and_R._Kunze/Chapter3.ipynb
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M  Linear_Algebra_by_K._Hoffman_and_R._Kunze/Chapter4.ipynb
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M  Material_Science_by_S._L._Kakani_and_A._Kakani/README.txt
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M  Material_Science_by_S._L._Kakani_and_A._Kakani/ch11.ipynb
M  Material_Science_by_S._L._Kakani_and_A._Kakani/ch12.ipynb
M  Material_Science_by_S._L._Kakani_and_A._Kakani/ch13.ipynb
M  Material_Science_by_S._L._Kakani_and_A._Kakani/ch14.ipynb
M  Material_Science_by_S._L._Kakani_and_A._Kakani/ch15.ipynb
M  Material_Science_by_S._L._Kakani_and_A._Kakani/ch16.ipynb
M  Material_Science_by_S._L._Kakani_and_A._Kakani/ch18.ipynb
M  Material_Science_by_S._L._Kakani_and_A._Kakani/ch2.ipynb
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M  Material_Science_by_S._L._Kakani_and_A._Kakani/ch6.ipynb
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M  Material_Science_by_S._L._Kakani_and_A._Kakani/ch8.ipynb
M  Material_Science_by_S._L._Kakani_and_A._Kakani/ch9.ipynb
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M  Microwave_engineering__by_D.M.Pozar_/Chapter_10_ACTIVE_MICROWAVE_CIRCUITS_2.ipynb
M  Microwave_engineering__by_D.M.Pozar_/Chapter_10_ACTIVE_MICROWAVE_CIRCUITS_3.ipynb
M  Microwave_engineering__by_D.M.Pozar_/Chapter_10_ACTIVE_MICROWAVE_CIRCUITS_4.ipynb
M  Microwave_engineering__by_D.M.Pozar_/Chapter_12_INTRODUCTION_TO_MICROWAVE_SYSTEMS_2.ipynb
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M  Microwave_engineering__by_D.M.Pozar_/Chapter_12_INTRODUCTION_TO_MICROWAVE_SYSTEMS_4.ipynb
M  Microwave_engineering__by_D.M.Pozar_/Chapter_1_ELECTROMAGNETIC_THEORY_2.ipynb
M  Microwave_engineering__by_D.M.Pozar_/Chapter_1_ELECTROMAGNETIC_THEORY_3.ipynb
M  Microwave_engineering__by_D.M.Pozar_/Chapter_1_ELECTROMAGNETIC_THEORY_4.ipynb
M  Microwave_engineering__by_D.M.Pozar_/Chapter_2_TRANSMISSION_LINE_THEORY_2.ipynb
M  Microwave_engineering__by_D.M.Pozar_/Chapter_2_TRANSMISSION_LINE_THEORY_3.ipynb
M  Microwave_engineering__by_D.M.Pozar_/Chapter_2_TRANSMISSION_LINE_THEORY_4.ipynb
M  Microwave_engineering__by_D.M.Pozar_/Chapter_3_TRANSMISSION_LINE_AND_WAVEGUIDES_2.ipynb
M  Microwave_engineering__by_D.M.Pozar_/Chapter_3_TRANSMISSION_LINE_AND_WAVEGUIDES_3.ipynb
M  Microwave_engineering__by_D.M.Pozar_/Chapter_3_TRANSMISSION_LINE_AND_WAVEGUIDES_4.ipynb
M  Microwave_engineering__by_D.M.Pozar_/Chapter_4_MICROWAVE_NETWORK_ANALYSIS_2.ipynb
M  Microwave_engineering__by_D.M.Pozar_/Chapter_4_MICROWAVE_NETWORK_ANALYSIS_3.ipynb
M  Microwave_engineering__by_D.M.Pozar_/Chapter_4_MICROWAVE_NETWORK_ANALYSIS_4.ipynb
M  Microwave_engineering__by_D.M.Pozar_/Chapter_5_IMPEDENCE_MATCHING_AND_TUNNING_2.ipynb
M  Microwave_engineering__by_D.M.Pozar_/Chapter_5_IMPEDENCE_MATCHING_AND_TUNNING_3.ipynb
M  Microwave_engineering__by_D.M.Pozar_/Chapter_5_IMPEDENCE_MATCHING_AND_TUNNING_4.ipynb
M  Microwave_engineering__by_D.M.Pozar_/Chapter_6_MICROWAVE_RESONATORS_2.ipynb
M  Microwave_engineering__by_D.M.Pozar_/Chapter_6_MICROWAVE_RESONATORS_3.ipynb
M  Microwave_engineering__by_D.M.Pozar_/Chapter_6_MICROWAVE_RESONATORS_4.ipynb
M  Microwave_engineering__by_D.M.Pozar_/Chapter_7_POWER_DIVIDERS_DIRECTIONAL_COUPLERS_AND_HYBRIDS_2.ipynb
M  Microwave_engineering__by_D.M.Pozar_/Chapter_7_POWER_DIVIDERS_DIRECTIONAL_COUPLERS_AND_HYBRIDS_3.ipynb
M  Microwave_engineering__by_D.M.Pozar_/Chapter_7_POWER_DIVIDERS_DIRECTIONAL_COUPLERS_AND_HYBRIDS_4.ipynb
M  Microwave_engineering__by_D.M.Pozar_/Chapter_8_MICROWAVE_FILTERS_2.ipynb
M  Microwave_engineering__by_D.M.Pozar_/Chapter_8_MICROWAVE_FILTERS_3.ipynb
M  Microwave_engineering__by_D.M.Pozar_/Chapter_8_MICROWAVE_FILTERS_4.ipynb
M  Microwave_engineering__by_D.M.Pozar_/Chapter_9_THEORY_AND_DESIGN_OF_FERRIMAGNETIC_COMPONENTS_2.ipynb
M  Microwave_engineering__by_D.M.Pozar_/Chapter_9_THEORY_AND_DESIGN_OF_FERRIMAGNETIC_COMPONENTS_3.ipynb
M  Microwave_engineering__by_D.M.Pozar_/Chapter_9_THEORY_AND_DESIGN_OF_FERRIMAGNETIC_COMPONENTS_4.ipynb
M  Microwave_engineering__by_D.M.Pozar_/README.txt
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M  Microwave_engineering__by_D.M.Pozar_/screenshots/Screen_Shot_2016-06-29_at_6.35.29_pm.png
M  Microwave_engineering__by_D.M.Pozar_/screenshots/Screen_Shot_2016-06-29_at_6.36.09_pm.png
M  Microwave_engineering__by_D.M.Pozar_/screenshots/chap_1.png
M  Microwave_engineering__by_D.M.Pozar_/screenshots/chap_1_1.png
M  Microwave_engineering__by_D.M.Pozar_/screenshots/chap_2.png
M  Microwave_engineering__by_D.M.Pozar_/screenshots/chap_2_1.png
M  Microwave_engineering__by_D.M.Pozar_/screenshots/chap_3.png
M  Microwave_engineering__by_D.M.Pozar_/screenshots/chap_3_1.png
M  Numerical_Methods_For_Engineers_by_S._C._Chapra_And_R._P._Canale/Chapter10_2.ipynb
M  Numerical_Methods_For_Engineers_by_S._C._Chapra_And_R._P._Canale/Chapter11_2.ipynb
M  Numerical_Methods_For_Engineers_by_S._C._Chapra_And_R._P._Canale/Chapter13_2.ipynb
M  Numerical_Methods_For_Engineers_by_S._C._Chapra_And_R._P._Canale/Chapter14_2.ipynb
M  Numerical_Methods_For_Engineers_by_S._C._Chapra_And_R._P._Canale/Chapter15_2.ipynb
M  Numerical_Methods_For_Engineers_by_S._C._Chapra_And_R._P._Canale/Chapter17_2.ipynb
M  Numerical_Methods_For_Engineers_by_S._C._Chapra_And_R._P._Canale/Chapter18_2.ipynb
M  Numerical_Methods_For_Engineers_by_S._C._Chapra_And_R._P._Canale/Chapter19_2.ipynb
M  Numerical_Methods_For_Engineers_by_S._C._Chapra_And_R._P._Canale/Chapter1_2.ipynb
M  Numerical_Methods_For_Engineers_by_S._C._Chapra_And_R._P._Canale/Chapter21_2.ipynb
M  Numerical_Methods_For_Engineers_by_S._C._Chapra_And_R._P._Canale/Chapter22_2.ipynb
M  Numerical_Methods_For_Engineers_by_S._C._Chapra_And_R._P._Canale/Chapter23_2.ipynb
M  Numerical_Methods_For_Engineers_by_S._C._Chapra_And_R._P._Canale/Chapter25_2.ipynb
M  Numerical_Methods_For_Engineers_by_S._C._Chapra_And_R._P._Canale/Chapter26_2.ipynb
M  Numerical_Methods_For_Engineers_by_S._C._Chapra_And_R._P._Canale/Chapter3_2.ipynb
M  Numerical_Methods_For_Engineers_by_S._C._Chapra_And_R._P._Canale/Chapter4_2.ipynb
M  Numerical_Methods_For_Engineers_by_S._C._Chapra_And_R._P._Canale/Chapter5_2.ipynb
M  Numerical_Methods_For_Engineers_by_S._C._Chapra_And_R._P._Canale/Chapter6_2.ipynb
M  Numerical_Methods_For_Engineers_by_S._C._Chapra_And_R._P._Canale/Chapter7_2.ipynb
M  Numerical_Methods_For_Engineers_by_S._C._Chapra_And_R._P._Canale/Chapter9_2.ipynb
M  Numerical_Methods_For_Engineers_by_S._C._Chapra_And_R._P._Canale/README.txt
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M  Numerical_Methods_For_Engineers_by_S._C._Chapra_And_R._P._Canale/screenshots/image3.png
M  Optical_Fiber_Communication_System_by_Dr._M.K._Raina/README.txt
M  PRINCIPLES_OF_MASS_TRANSFER_AND_SEPARATION_PROCESS_by_Binay_K._Dutta/Chapter-2.ipynb
M  PRINCIPLES_OF_MASS_TRANSFER_AND_SEPARATION_PROCESS_by_Binay_K._Dutta/Chapter-3.ipynb
M  PRINCIPLES_OF_MASS_TRANSFER_AND_SEPARATION_PROCESS_by_Binay_K._Dutta/Chapter-4.ipynb
M  PRINCIPLES_OF_MASS_TRANSFER_AND_SEPARATION_PROCESS_by_Binay_K._Dutta/Chapter-5.ipynb
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M  PRINCIPLES_OF_MASS_TRANSFER_AND_SEPARATION_PROCESS_by_Binay_K._Dutta/screenshots/chapter2_example_2.4_plot_2.png
M  PRINCIPLES_OF_MASS_TRANSFER_AND_SEPARATION_PROCESS_by_Binay_K._Dutta/screenshots/chapter4_example_4.5_plot_2.png
M  Physics-_For_Students_Of_Science_And_Engineering(Part_2)_by_D._Halliday_and_R._Resnick/Chapter26.ipynb
M  Physics-_For_Students_Of_Science_And_Engineering(Part_2)_by_D._Halliday_and_R._Resnick/Chapter27.ipynb
M  Physics-_For_Students_Of_Science_And_Engineering(Part_2)_by_D._Halliday_and_R._Resnick/Chapter28.ipynb
M  Physics-_For_Students_Of_Science_And_Engineering(Part_2)_by_D._Halliday_and_R._Resnick/Chapter29.ipynb
M  Physics-_For_Students_Of_Science_And_Engineering(Part_2)_by_D._Halliday_and_R._Resnick/Chapter30.ipynb
M  Physics-_For_Students_Of_Science_And_Engineering(Part_2)_by_D._Halliday_and_R._Resnick/Chapter31.ipynb
M  Physics-_For_Students_Of_Science_And_Engineering(Part_2)_by_D._Halliday_and_R._Resnick/Chapter33.ipynb
M  Physics-_For_Students_Of_Science_And_Engineering(Part_2)_by_D._Halliday_and_R._Resnick/Chapter34.ipynb
M  Physics-_For_Students_Of_Science_And_Engineering(Part_2)_by_D._Halliday_and_R._Resnick/Chapter35.ipynb
M  Physics-_For_Students_Of_Science_And_Engineering(Part_2)_by_D._Halliday_and_R._Resnick/Chapter36.ipynb
M  Physics-_For_Students_Of_Science_And_Engineering(Part_2)_by_D._Halliday_and_R._Resnick/Chapter37.ipynb
M  Physics-_For_Students_Of_Science_And_Engineering(Part_2)_by_D._Halliday_and_R._Resnick/Chapter38.ipynb
M  Physics-_For_Students_Of_Science_And_Engineering(Part_2)_by_D._Halliday_and_R._Resnick/Chapter39.ipynb
M  Physics-_For_Students_Of_Science_And_Engineering(Part_2)_by_D._Halliday_and_R._Resnick/Chapter40.ipynb
M  Physics-_For_Students_Of_Science_And_Engineering(Part_2)_by_D._Halliday_and_R._Resnick/Chapter41.ipynb
M  Physics-_For_Students_Of_Science_And_Engineering(Part_2)_by_D._Halliday_and_R._Resnick/Chapter42.ipynb
M  Physics-_For_Students_Of_Science_And_Engineering(Part_2)_by_D._Halliday_and_R._Resnick/Chapter43.ipynb
M  Physics-_For_Students_Of_Science_And_Engineering(Part_2)_by_D._Halliday_and_R._Resnick/Chapter44.ipynb
M  Physics-_For_Students_Of_Science_And_Engineering(Part_2)_by_D._Halliday_and_R._Resnick/Chapter45.ipynb
M  Physics-_For_Students_Of_Science_And_Engineering(Part_2)_by_D._Halliday_and_R._Resnick/Chapter46.ipynb
M  Physics-_For_Students_Of_Science_And_Engineering(Part_2)_by_D._Halliday_and_R._Resnick/Chapter47.ipynb
M  Physics-_For_Students_Of_Science_And_Engineering(Part_2)_by_D._Halliday_and_R._Resnick/Chapter48.ipynb
M  Physics-_For_Students_Of_Science_And_Engineering(Part_2)_by_D._Halliday_and_R._Resnick/screenshots/Chapter_37.png
M  Physics-_For_Students_Of_Science_And_Engineering(Part_2)_by_D._Halliday_and_R._Resnick/screenshots/Chapter_38.png
M  Physics-_For_Students_Of_Science_And_Engineering(Part_2)_by_D._Halliday_and_R._Resnick/screenshots/Chapter_39.png
M  Power_Electronics:_Principles_&_Applications_by_J_M_Jacob/Chapter1.ipynb
M  Power_Electronics:_Principles_&_Applications_by_J_M_Jacob/Chapter2.ipynb
M  Power_Electronics:_Principles_&_Applications_by_J_M_Jacob/Chapter3.ipynb
M  Power_Electronics:_Principles_&_Applications_by_J_M_Jacob/Chapter4.ipynb
M  Power_Electronics:_Principles_&_Applications_by_J_M_Jacob/Chapter5.ipynb
M  Power_Electronics:_Principles_&_Applications_by_J_M_Jacob/Chapter6.ipynb
M  Power_Electronics:_Principles_&_Applications_by_J_M_Jacob/Chapter7.ipynb
M  Power_Electronics:_Principles_&_Applications_by_J_M_Jacob/Chapter8.ipynb
M  Power_Electronics:_Principles_&_Applications_by_J_M_Jacob/Chapter9.ipynb
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diff --git a/Basic_And_Applied_Thermodynamics_by_P._K._Nag/Chapter19.ipynb b/Basic_And_Applied_Thermodynamics_by_P._K._Nag/Chapter19.ipynb
new file mode 100644
index 00000000..df2b3868
--- /dev/null
+++ b/Basic_And_Applied_Thermodynamics_by_P._K._Nag/Chapter19.ipynb
@@ -0,0 +1,1383 @@
+{


+ "metadata": {


+  "name": "",


+  "signature": "sha256:1db2f35b9b69d7f4ae51f4ee8d24e65751baf82a587616cfcfd52d79c1796d33"


+ },


+ "nbformat": 3,


+ "nbformat_minor": 0,


+ "worksheets": [


+  {


+   "cells": [


+    {


+     "cell_type": "heading",


+     "level": 1,


+     "metadata": {},


+     "source": [


+      "Chapter 19: Gas Compressors"


+     ]


+    },


+    {


+     "cell_type": "heading",


+     "level": 2,


+     "metadata": {},


+     "source": [


+      "Ex19.1:pg-818"


+     ]


+    },


+    {


+     "cell_type": "code",


+     "collapsed": false,


+     "input": [


+      "T2 = 488.0 \n",


+      "T1 = 298.0 \n",


+      "n = 1.3 \n",


+      "R =8314.0/44.0\n",


+      "rp = (T2/T1)**(n/(n-1))\n",


+      "\n",


+      "b = 0.12 # Bore of compressor\n",


+      "L = 0.15 # Stroke of compressor\n",


+      "V1 = (math.pi/4)*(b)**2*L  \n",


+      "P1 = 120e03 # in kPa\n",


+      "W = ((n*P1*V1)/(n-1))*(((rp)**((n-1)/n))-1)\n",


+      "P = (W*1200*0.001)/60  \n",


+      "\n",


+      "V1_dot = V1*(1200.0/60.0)\n",


+      "m_dot = (P1*V1_dot)/(R*T1)\n",


+      "\n",


+      "rp_1 = rp**2\n",


+      "V2 = (1/rp)**(1/n)*V1\n",


+      "d = sqrt((V2*4)/(L*math.pi))\n",


+      "print \"\\n Example 19.1\\n\"\n",


+      "print \"\\n Pressure ratio is \",rp\n",


+      "print \"\\n Indicated power is \",P ,\" kW\"\n",


+      "print \"\\n Shaft power is \",P/0.8 ,\" kW\"\n",


+      "print \"\\n Mass flow rate is \",m_dot ,\" kg/s\"\n",


+      "print \"\\n Pressure ratio when second stage is added is \",rp_1\n",


+      "print \"\\n Volume derived per cycle is V2 \",V2 ,\" m**3\"\n",


+      "print \"\\n Second stage bore would be \",d*1000 ,\" mm\"\n",


+      "#The answers vary due to round off error\n"


+     ],


+     "language": "python",


+     "metadata": {},


+     "outputs": [


+      {


+       "output_type": "stream",


+       "stream": "stdout",


+       "text": [


+        "\n",


+        " Example 19.1\n",


+        "\n",


+        "\n",


+        " Pressure ratio is  8.4764775804\n",


+        "\n",


+        " Indicated power is  11.2490101513  kW\n",


+        "\n",


+        " Shaft power is  14.0612626891  kW\n",


+        "\n",


+        " Mass flow rate is  0.0723071537289  kg/s\n",


+        "\n",


+        " Pressure ratio when second stage is added is  71.8506721711\n",


+        "\n",


+        " Volume derived per cycle is V2  0.000327741753347  m**3\n",


+        "\n",


+        " Second stage bore would be  52.7442736748  mm\n"


+       ]


+      }


+     ],


+     "prompt_number": 1


+    },


+    {


+     "cell_type": "heading",


+     "level": 2,


+     "metadata": {},


+     "source": [


+      "Ex19.2:pg-819"


+     ]


+    },


+    {


+     "cell_type": "code",


+     "collapsed": false,


+     "input": [


+      "\n",


+      "c = 0.05 # Clearance volume\n",


+      "p1 = 96.0 # Inlet ressure in bar\n",


+      "p2 = 725.0 # Outlet pressure in bar\n",


+      "pa = 101.3 # Atmospheric pressure\n",


+      "Ta = 292.0 # Atmospheric temperature in kelvin\n",


+      "T1 = 305.0 # Inlet temperature in Kelvin\n",


+      "n = 1.3 # polytropic index\n",


+      "print \"\\n Example 19.2 \\n \"\n",


+      "n_v = (1+c-c*((p2/p1)**(1/n)))*(p1/pa)*(Ta/T1)\n",


+      "print \"\\n Volumetric efficiency of system is \",n_v*100 ,\" percent\"\n",


+      "# Answer is not mentioned in book\n"


+     ],


+     "language": "python",


+     "metadata": {},


+     "outputs": [


+      {


+       "output_type": "stream",


+       "stream": "stdout",


+       "text": [


+        "\n",


+        " Example 19.2 \n",


+        " \n",


+        "\n",


+        " Volumetric efficiency of system is  73.7793963433  percent\n"


+       ]


+      }


+     ],


+     "prompt_number": 2


+    },


+    {


+     "cell_type": "heading",


+     "level": 2,


+     "metadata": {},


+     "source": [


+      "Ex19.3:pg-819"


+     ]


+    },


+    {


+     "cell_type": "code",


+     "collapsed": false,


+     "input": [


+      "P1 = 101.3e03 \n",


+      "P4 = P1 # in Pa\n",


+      "P2 = 8*P1  \n",


+      "P3 = P2\n",


+      "T1 = 288 \n",


+      "Vs = 2000\n",


+      "V3 = 100 \n",


+      "Vc = V3\n",


+      "V1 = Vs + Vc \n",


+      "n = 1.25 \n",


+      "R = 287\n",


+      "V4 = ((P3/P4)**(1/n))*V3\n",


+      "W = ((n*P1*(V1-V4)*1e-06)/(n-1))*(((P2/P1)**((n-1)/n))-1)\n",


+      "P = (W*800*0.001)/60  \n",


+      "\n",


+      "m = (P1*(V1-V4)*1e-06)/(R*T1)\n",


+      "m_dot = m*800\n",


+      "\n",


+      "FAD = (V1-V4)*1e-06*800\n",


+      "\n",


+      "Wt = P1*(V1-V4)*1e-06*log(P2/P1)\n",


+      "n_isothermal = (Wt*800*0.001)/(P*60)\n",


+      "\n",


+      "Pi = P/0.85\n",


+      "n_v =100*(V1-V4)/Vs\n",


+      "print \"\\n Example 19.3\\n\"\n",


+      "print \"\\n Indicated poer is \",P ,\" kW\"\n",


+      "print \"\\n Volumetric efficiency is \",n_v ,\" percent\"\n",


+      "print \"\\n Mass flow rate is \",m_dot ,\" kg/min\"\n",


+      "print \"\\n Free air delivery is \",FAD ,\" m**3/min\"\n",


+      "print \"\\n Isothermal efficiency is \",100*n_isothermal ,\" percent\"\n",


+      "print \"\\n Input power is \",Pi ,\" kW\"\n",


+      "\n",


+      "#The answers vary due to round off error\n",


+      "\n"


+     ],


+     "language": "python",


+     "metadata": {},


+     "outputs": [


+      {


+       "output_type": "stream",


+       "stream": "stdout",


+       "text": [


+        " \n",


+        " Example 19.3\n",


+        "\n",


+        "\n",


+        " Indicated poer is  5.47565638255  kW\n",


+        "\n",


+        " Volumetric efficiency is  78.6098417845  percent\n",


+        "\n",


+        " Mass flow rate is  1.54145895718  kg/min\n",


+        "\n",


+        " Free air delivery is  1.25775746855  m**3/min\n",


+        "\n",


+        " Isothermal efficiency is  80.6428056306  percent\n",


+        "\n",


+        " Input power is  6.44194868535  kW\n"


+       ]


+      }


+     ],


+     "prompt_number": 4


+    },


+    {


+     "cell_type": "heading",


+     "level": 2,


+     "metadata": {},


+     "source": [


+      "Ex19.4:pg-819"


+     ]


+    },


+    {


+     "cell_type": "code",


+     "collapsed": false,


+     "input": [


+      "# Given that\n",


+      "m = 3.0 # Mass flow rate in kg/min\n",


+      "p1 = 1.0 # Initial pressure in bar\n",


+      "T1 = 300.0 # Initial temperature in K\n",


+      "p3 = 6.0 # Pressure after compression in bar\n",


+      "p5 = 15.0 # Maximum pressure in bar\n",


+      "N = 300.0 # Rpm of compressure\n",


+      "n = 1.3 # Index of compression and expansion \n",


+      "r = 1.5 # Stroke to bore ratio\n",


+      "R = 287.0 # Gas constant of air\n",


+      "t = 15.0 # Temperature in degree centigrade\n",


+      "print \"\\n Example 19.4\\n\"\n",


+      "T = t+273\n",


+      "Wc = (n/(n-1))*(m/60)*(R*(1e-3)*T1)*(((p3/p1)**((n-1)/n))-1)\n",


+      "r1 = (p5/p1)**(1.0/n)# Where r1 = V1/Vc\n",


+      "r2 = r1-1 # Where r2 = Vs/Vc\n",


+      "r3 = (p3/p1)**(1.0/n)\n",


+      "n_vol = (r1-r3)*(T/T1)/r2\n",


+      "V = m*R*T/(2*(1e5)*N)\n",


+      "Vs = V/n_vol\n",


+      "d = (Vs*4/(math.pi*r))**(1.0/3.0)\n",


+      "l = r*d\n",


+      "print \"\\n Power input is \",Wc ,\" kW, \\n Volumetric efficiency is \",n_vol*100 ,\" percent, \\n Bore of the cylinder is \",d ,\" m, \\n Stroke of the cylinder is \",l ,\" m\"\n",


+      "#The answers vary due to round off error"


+     ],


+     "language": "python",


+     "metadata": {},


+     "outputs": [


+      {


+       "output_type": "stream",


+       "stream": "stdout",


+       "text": [


+        "\n",


+        " Example 19.4\n",


+        "\n",


+        "\n",


+        " Power input is  9.55276123312  kW, \n",


+        " Volumetric efficiency is  55.4657309635  percent, \n",


+        " Bore of the cylinder is  0.184932327621  m, \n",


+        " Stroke of the cylinder is  0.277398491431  m\n"


+       ]


+      }


+     ],


+     "prompt_number": 8


+    },


+    {


+     "cell_type": "heading",


+     "level": 2,


+     "metadata": {},


+     "source": [


+      "Ex19.5:pg-820"


+     ]


+    },


+    {


+     "cell_type": "code",


+     "collapsed": false,


+     "input": [


+      "# Given that\n",


+      "d = 15.0 # Diameter in cm\n",


+      "l = 18.0 # Stroke in cm\n",


+      "C = 0.04 # Ratio of clearance volume and sweft volume\n",


+      "p1 = 1.0 # Pressure in bar\n",


+      "t1 = 25.0 # Temperature in degree centigrade\n",


+      "p2 = 8.0# Pressure in bar\n",


+      "N = 1200.0 # Rpm of compressure \n",


+      "W = 18.0 # Actual power input in kW\n",


+      "m = 4.0 # Mass flow rate in kg/min\n",


+      "R = 0.287\n",


+      "print \"\\n Example 19.5\\n\"\n",


+      "T1 = t1+273\n",


+      "v = R*T1/(p1*100)\n",


+      "V = m*v\n",


+      "Vs = (math.pi/4)*((d*(1e-2))**2)*(l*1e-2)*N\n",


+      "n_vol = V/Vs\n",


+      "n = (log(p2/p1))/(log((1+C-n_vol)/C))\n",


+      "# The value of n given in the example is wrong\n",


+      "n = 1.573\n",


+      "T2 = T1*(p2/p1)**((n-1)/n)\n",


+      "Wc = (n/(n-1))*(m*R/60)*(T2-T1)\n",


+      "n_mech = Wc/W\n",


+      "W_isothermal = m*R*T1*log(p2/p1)/60\n",


+      "n_iso = W_isothermal/W\n",


+      "print \"\\n Power required to drive the unit is \",Wc ,\" kW,\\n Isothermal efficiency is \",n_iso*100 ,\" percent,\\n Mechanical efficiency is \",n_mech*100 ,\" percent\"\n",


+      "#The answers vary due to round off error"


+     ],


+     "language": "python",


+     "metadata": {},


+     "outputs": [


+      {


+       "output_type": "stream",


+       "stream": "stdout",


+       "text": [


+        "\n",


+        " Example 19.5\n",


+        "\n",


+        "\n",


+        " Power required to drive the unit is  17.7326053799  kW,\n",


+        " Isothermal efficiency is  65.8690064051  percent,\n",


+        " Mechanical efficiency is  98.5144743328  percent\n"


+       ]


+      }


+     ],


+     "prompt_number": 9


+    },


+    {


+     "cell_type": "heading",


+     "level": 2,


+     "metadata": {},


+     "source": [


+      "Ex19.6:pg-820"


+     ]


+    },


+    {


+     "cell_type": "code",


+     "collapsed": false,


+     "input": [


+      "\n",


+      "# Given that\n",


+      "d = 40.0 # Diameter in cm\n",


+      "l = 50.0 # Stroke in cm\n",


+      "D = 5.0 # Piston rod diameter in cm\n",


+      "C = 0.04 # Ratio of clearance volume and sweft volume\n",


+      "p1 = 1.0 # Pressure in bar\n",


+      "t1 = 15.0 # Temperature in degree centigrade\n",


+      "p2 = 7.5# Pressure in bar\n",


+      "N = 300.0 # Rpm of compressure \n",


+      "n_vol = 0.8 # Volumetric efficiency\n",


+      "n_mech = 0.95 # Mechanical efficiency\n",


+      "n_iso = .7 # Isothermal efficiency\n",


+      "R = 0.287\n",


+      "print \"\\n Example 19.6\\n\"\n",


+      "Vs = (math.pi/4)*((d*(1e-2))**2)*(l*(1e-2))\n",


+      "Vs_ = (math.pi/4)*(((d*(1e-2))**2)-(D*(1e-2))**2)*(l*1e-2)\n",


+      "Vs_min = (Vs+Vs_)*2*N\n",


+      "V1 = Vs_min*n_vol\n",


+      "W_iso = p1*V1*(log(p2/p1))\n",


+      "Win = W_iso/n_iso\n",


+      "Wc = Win/n_mech\n",


+      "print \"\\n Power required to drive the compressure is \",Wc ,\" kW\"\n",


+      "#The answers vary due to round off error\n",


+      "\n"


+     ],


+     "language": "python",


+     "metadata": {},


+     "outputs": [


+      {


+       "output_type": "stream",


+       "stream": "stdout",


+       "text": [


+        "\n",


+        " Example 19.6\n",


+        "\n",


+        "\n",


+        " Power required to drive the compressure is  181.333212391  kW\n"


+       ]


+      }


+     ],


+     "prompt_number": 11


+    },


+    {


+     "cell_type": "heading",


+     "level": 2,


+     "metadata": {},


+     "source": [


+      "Ex19.7:pg-820"


+     ]


+    },


+    {


+     "cell_type": "code",


+     "collapsed": false,


+     "input": [


+      "# Given that\n",


+      "p1 = 1.0 # Pressure in bar\n",


+      "t1 = 27.0 # Temperature in degree centigrade\n",


+      "n = 1.3 # Index of the compression process\n",


+      "p3 = 9.0# Pressure in bar\n",


+      "R = 0.287\n",


+      "print \"\\n Example 19.7\\n\"\n",


+      "T1 = t1+273\n",


+      "p2 = sqrt(p1*p3)\n",


+      "Wc = ((2*n*R*T1)/(n-1))*(((p2/p1)**((n-1)/n))-1)\n",


+      "T2 = T1*((p2/p1)**((n-1)/n))\n",


+      "H = 1.005*(T2-T1)\n",


+      "print \"\\n Minimum work done is \",Wc ,\" kJ/kg,\\n Heat rejected to intercooler is \",H ,\" kJ/kg\"\n",


+      "#The answers vary due to round off error"


+     ],


+     "language": "python",


+     "metadata": {},


+     "outputs": [


+      {


+       "output_type": "stream",


+       "stream": "stdout",


+       "text": [


+        "\n",


+        " Example 19.7\n",


+        "\n",


+        "\n",


+        " Minimum work done is  215.324046  kJ/kg,\n",


+        " Heat rejected to intercooler is  87.0010719231  kJ/kg\n"


+       ]


+      }


+     ],


+     "prompt_number": 12


+    },


+    {


+     "cell_type": "heading",


+     "level": 2,


+     "metadata": {},


+     "source": [


+      "Ex19.8:pg-820"


+     ]


+    },


+    {


+     "cell_type": "code",


+     "collapsed": false,


+     "input": [


+      "\n",


+      "# Given that\n",


+      "V = 4.0 # Volume flow rate in m**3/min\n",


+      "p1 = 1.013 # Pressure in bar\n",


+      "t1 = 15.0 # Temperature in degree centigrade\n",


+      "N = 250.0 # Speed in RPM\n",


+      "p4 = 80.0# Delivery pressure in bar\n",


+      "v = 3.0 #Speed of piston in m/sec\n",


+      "n_mech = .75 # Mechanical efficiency \n",


+      "n_vol = .8 # Volumetric efficiency\n",


+      "n = 1.25 # Polytropic index\n",


+      "print \"\\n Example 19.8\\n\"\n",


+      "T1 = t1+273\n",


+      "p2 = sqrt(p1*p4)\n",


+      "W = (2*n/(n-1))*(p1*100/n_mech)*(V/60)*((p2/p1)**((n-1)/n) - 1)\n",


+      "L = v*60/(N*2)\n",


+      "Vs = V/N\n",


+      "D_LP = sqrt(Vs*V/(math.pi*L*n_vol))\n",


+      "D_HP = D_LP*sqrt(p1/p2)\n",


+      "print \"\\n Minimum power required by the compressure is \",W ,\" kW,\\n Bore of the compressure in low pressure side is \",D_LP*100 ,\" cm,\\n Bore of the compressure in high pressure side is \",D_HP*100 ,\" cm,\\n Stroke of the compressure is \",L*100 ,\" cm\"\n",


+      "#The answers vary due to round off error\n",


+      "\n"


+     ],


+     "language": "python",


+     "metadata": {},


+     "outputs": [


+      {


+       "output_type": "stream",


+       "stream": "stdout",


+       "text": [


+        "\n",


+        " Example 19.8\n",


+        "\n",


+        "\n",


+        " Minimum power required by the compressure is  49.3370051888  kW,\n",


+        " Bore of the compressure in low pressure side is  26.5961520268  cm,\n",


+        " Bore of the compressure in high pressure side is  8.92172168806  cm,\n",


+        " Stroke of the compressure is  36.0  cm\n"


+       ]


+      }


+     ],


+     "prompt_number": 13


+    },


+    {


+     "cell_type": "heading",


+     "level": 2,


+     "metadata": {},


+     "source": [


+      "Ex19.9:pg-820"


+     ]


+    },


+    {


+     "cell_type": "code",


+     "collapsed": false,


+     "input": [


+      "# Given that\n",


+      "p1 = 1.0 # Pressure in bar\n",


+      "T1 = 300.0 # Temperature in K\n",


+      "p4 = 9.0# Compressed pressure in bar\n",


+      "n = 1.3 # Polytropic index\n",


+      "R = 0.287 # Gas constant in kJ/kgK\n",


+      "cp = 1.042 # Heat capapcity in kJ/kgK\n",


+      "print \"\\n Example 19.9\\n\"\n",


+      "p2 = sqrt(p1*p4)\n",


+      "T2 =T1*((p2/p1)**((n-1)/n))\n",


+      "Wc = (2*n/(n-1))*R*1*(T2-T1)\n",


+      "Wc_ = Wc/2\n",


+      "Q = 1*cp*(T2-T1)\n",


+      "Q_ = cp*(T1-T2)+Wc_\n",


+      "H = Q+2*Q_\n",


+      "print \"\\n Compressor work = \",Wc_ ,\" kJ/kg,\\n Total heat transfer to the surrounding = \",H ,\" kJ/kg\"\n",


+      "#The answers given in the book contain calculation error\n",


+      "\n"


+     ],


+     "language": "python",


+     "metadata": {},


+     "outputs": [


+      {


+       "output_type": "stream",


+       "stream": "stdout",


+       "text": [


+        "\n",


+        " Example 19.9\n",


+        "\n",


+        "\n",


+        " Compressor work =  107.662023  kJ/kg,\n",


+        " Total heat transfer to the surrounding =  125.119949539  kJ/kg\n"


+       ]


+      }


+     ],


+     "prompt_number": 14


+    },


+    {


+     "cell_type": "heading",


+     "level": 2,


+     "metadata": {},


+     "source": [


+      "Ex19.10:pg-820"


+     ]


+    },


+    {


+     "cell_type": "code",


+     "collapsed": false,


+     "input": [


+      "\n",


+      "# Given that\n",


+      "N = 300.0 # Speed in RPM\n",


+      "# Intake condition of compressor\n",


+      "p1 = 0.98 # Pressure in bar\n",


+      "T1 = 305.0 # Temperature in K\n",


+      "\n",


+      "p6 = 20.0# Delivery pressure in bar\n",


+      "p3 = 5.0 # Intermediate pressure in bar\n",


+      "C = .04 # Ratio of clearance volume to the stroke volume\n",


+      "v = 3.0 # Volume flow rate of compressure in m**3/min\n",


+      "p = 1.0 # pressure in bar\n",


+      "t = 25.0 # Temperautre in degree centigrade\n",


+      "n = 1.3 # Polytropic index\n",


+      "R = 0.287 # Gas constant in kJ/kgK\n",


+      "print \"\\n Example 19.10\\n\"\n",


+      "T = t+273\n",


+      "r0 = 1+C # Where r0 = v1/vs\n",


+      "r1 = C*(p3/p1)**(1/n)# Where r1 = v4/vs\n",


+      "r2=r0-r1#Where r2 is the ratio of volume of air taken at 0.98 bar,305 k and vs\n",


+      "r3 = r2*(T/T1)*p1/p # Where r3 is the ratio of volume of air taken at free air conditions and vs\n",


+      "n_vol = r3\n",


+      "m = p*(1e5)*(v/60)/(R*1000*T)\n",


+      "T2 = T1*((p3/p1)**((n-1)/n))\n",


+      "# For perfect intercooling\n",


+      "T5 = T1\n",


+      "p5 = p3\n",


+      "T6 = T5*((p6/p5)**((n-1)/n))\n",


+      "Wc = (n/(n-1))*m*R*((T2-T1)+(T6-T5))\n",


+      "m_a_s = m*60/N\n",


+      "v_fa_s = m_a_s *(R*1000)*T/(p*1e5)\n",


+      "d = ((v_fa_s/n_vol)*(4/math.pi))**(1.0/3.0)\n",


+      "l = d # As given in the question\n",


+      "P_iso = m*R*T1*(log(p6/p1))\n",


+      "n_iso = P_iso/Wc\n",


+      "print \"\\n Diameter of cylinder = \",Wc,d*100 ,\" cm, \\n Storke of the cylinder = \",l*100 ,\" cm,\\n Isothermal efficiency = \",n_iso*100 ,\" percent\"\n",


+      "#The answers given in the book contain calculation error\n",


+      "\n"


+     ],


+     "language": "python",


+     "metadata": {},


+     "outputs": [


+      {


+       "output_type": "stream",


+       "stream": "stdout",


+       "text": [


+        "\n",


+        " Example 19.10\n",


+        "\n",


+        "\n",


+        " Diameter of cylinder =  18.484702902 24.5391705107  cm, \n",


+        " Storke of the cylinder =  24.5391705107  cm,\n",


+        " Isothermal efficiency =  83.4955018622  percent\n"


+       ]


+      }


+     ],


+     "prompt_number": 16


+    },


+    {


+     "cell_type": "heading",


+     "level": 2,


+     "metadata": {},


+     "source": [


+      "Ex19.11:pg-820"


+     ]


+    },


+    {


+     "cell_type": "code",


+     "collapsed": false,


+     "input": [


+      "# Given that\n",


+      "p1 = 1 # Intake pressure of compressor in bar\n",


+      "T1 = 298 # Intake temperature in K\n",


+      "p_d = 36 # Delivery pressure in bar\n",


+      "T2 = 390 # Maximum temperature in any stage in K\n",


+      "n = 1.3 # Polytropic index\n",


+      "R = 0.287\n",


+      "print \"\\n Example 19.11\\n\"\n",


+      "r = (T2/T1)**(n/(n-1))\n",


+      "N = math. ceil(r)\n",


+      "p2 = (p_d/p1)**(1/N)\n",


+      "p3 = (p_d/p1)**(2/N)\n",


+      "p4 = (p_d/p1)**(3/N)\n",


+      "Wc = (N*n*R*T1/(n-1))*((p_d/p1)**((n-1)/(N*n))-1)\n",


+      "Wc_ = (n/(n-1))*(1*R*T1)*((p_d/p1)**((n-1)/n)- 1)\n",


+      "T = T1*((p2/p1)**((n-1)/n))\n",


+      "print \"\\n No of stages for min power input = \",N ,\",\\n Power required = \",Wc ,\" kW/kg air,\\n The power required for a single stage compressor = \",Wc_ ,\" kW,\\n Maximum temperature in any stage = \",T ,\" K\"\n",


+      "#The answers given in the book contain round off error"


+     ],


+     "language": "python",


+     "metadata": {},


+     "outputs": [


+      {


+       "output_type": "stream",


+       "stream": "stdout",


+       "text": [


+        "\n",


+        " Example 19.11\n",


+        "\n",


+        "\n",


+        " No of stages for min power input =  1.0 ,\n",


+        " Power required =  476.74544125  kW/kg air,\n",


+        " The power required for a single stage compressor =  476.74544125  kW,\n",


+        " Maximum temperature in any stage =  681.338601917  K\n"


+       ]


+      }


+     ],


+     "prompt_number": 17


+    },


+    {


+     "cell_type": "heading",


+     "level": 2,


+     "metadata": {},


+     "source": [


+      "Ex19.12:pg-820"


+     ]


+    },


+    {


+     "cell_type": "code",


+     "collapsed": false,


+     "input": [


+      "\n",


+      "# Given that\n",


+      "p1 = 700.0 # Intake pressure of compressor in kPa\n",


+      "t1 = 38.0 # Intake temperature in degree centigrade\n",


+      "c = 0.4 # Ratio of cutoff volume to stroke volume\n",


+      "p3 = 112.0 # Back pressure in kPa\n",


+      "r = 0.85 # Ratio of area of actual indicator diagram to the outlined in the question\n",


+      "n = 1.3 # Polytropic index\n",


+      "R = 0.287\n",


+      "m = 1.25 # Air mass in kg\n",


+      "print \"\\n Example 19.12\\n\"\n",


+      "T1 = t1+273\n",


+      "T2 = T1/((1/c)**(n-1))\n",


+      "p2 = p1*(c**n)\n",


+      "V2 = m*R*T2/p2\n",


+      "v2 = V2/m\n",


+      "A = R*T1 + R*(T1-T2)/(n-1) - p3*v2\n",


+      "Io = A*r*m\n",


+      "print \"\\n Indicated output = \",Io ,\" kJ\"\n",


+      "# The answer given in the book vary due to round off error\n",


+      " \n"


+     ],


+     "language": "python",


+     "metadata": {},


+     "outputs": [


+      {


+       "output_type": "stream",


+       "stream": "stdout",


+       "text": [


+        "\n",


+        " Example 19.12\n",


+        "\n",


+        "\n",


+        " Indicated output =  132.877965499  kJ\n"


+       ]


+      }


+     ],


+     "prompt_number": 18


+    },


+    {


+     "cell_type": "heading",


+     "level": 2,


+     "metadata": {},


+     "source": [


+      "Ex19.13:pg-820"


+     ]


+    },


+    {


+     "cell_type": "code",


+     "collapsed": false,


+     "input": [


+      "# Given that\n",


+      "d = 450.0 # Bore of low pressure cylinder in mm\n",


+      "l = 300.0 # Stroke in mm\n",


+      "c = 0.05 # Ratio of clearance volume to sweft volume\n",


+      "p1 = 1.0 # Intake pressure in bar\n",


+      "t1 = 18.0 # Intake temperature in degree centigrade\n",


+      "p4 = 15.0 # Delivery pressure in bar\n",


+      "n = 1.3 # Compression and expansion index\n",


+      "R = 0.29 # Gas constant in kJ/kgK\n",


+      "print \"\\n Example 19.13\\n\"\n",


+      "T1 = t1+273\n",


+      "r = (p4/p1)**(1.0/3.0)\n",


+      "p2 = p1*r\n",


+      "p3 = p2*r\n",


+      "Vs = (math.pi/4)*((d*1e-3)**2)*(l*1e-3)\n",


+      "V11 = c*Vs\n",


+      "V1 = Vs +V11\n",


+      "V12 = V11*((r)**(1.0/n))\n",


+      "Vs_e = V1 - V12\n",


+      "T3 = T1\n",


+      "T5 = T3\n",


+      "T6 = T1*(r**((n-1)/n))\n",


+      "t6 = T6-273\n",


+      "V6_7 = (p1/p4)*(T6/T1)*(V1 - V12)\n",


+      "W = (3*n*R*T1/(n-1))*((p2/p1)**((n-1)/n)-1)\n",


+      "print \"\\n The intermediate pressure are - \\n p2 = \",p2 ,\" bar,\\n p3 = \",p3 ,\" bar,\\n The effective sweft volume = \",Vs ,\" m**3,\\n Temperature of air delivered per stroke at 15 bar = \",t6 ,\" degree centigrade,\\n The work done per kg of air = \",W ,\" kJ\"\n",


+      "# The answers given in the book vary due to round off error"


+     ],


+     "language": "python",


+     "metadata": {},


+     "outputs": [


+      {


+       "output_type": "stream",


+       "stream": "stdout",


+       "text": [


+        "\n",


+        " Example 19.13\n",


+        "\n",


+        "\n",


+        " The intermediate pressure are - \n",


+        " p2 =  2.46621207433  bar,\n",


+        " p3 =  6.08220199557  bar,\n",


+        " The effective sweft volume =  0.0477129384264  m**3,\n",


+        " Temperature of air delivered per stroke at 15 bar =  85.3946742162  degree centigrade,\n",


+        " The work done per kg of air =  254.077921795  kJ\n"


+       ]


+      }


+     ],


+     "prompt_number": 20


+    },


+    {


+     "cell_type": "heading",


+     "level": 2,


+     "metadata": {},


+     "source": [


+      "Ex19.14:pg-820"


+     ]


+    },


+    {


+     "cell_type": "code",


+     "collapsed": false,


+     "input": [


+      "\n",


+      "# Given that\n",


+      "p1 = 1.013 # Inlet pressure in bar\n",


+      "r = 1.5 # Pressure ratio\n",


+      "Vs = 0.03 # Induce volume of air in m**3/rev\n",


+      "gama = 1.4 \n",


+      "print \"\\n Example 19.14\\n\"\n",


+      "p2 = p1*r\n",


+      "W = (p2-p1)*Vs*100\n",


+      "pi = (p1+p2)/2\n",


+      "A_A = (gama/(gama-1))*(p1*Vs)*((pi/p1)**((gama-1)/gama)-1)*100\n",


+      "Vb = Vs *((p1/pi)**(1/gama))\n",


+      "A_B = (p2-pi)*Vb*100\n",


+      "Wr = A_A + A_B\n",


+      "print \"\\n Work input = \",W ,\" kJ/rev,\\n Work input for a vane-type compressor = \",Wr ,\" kJ/rev\"\n",


+      "# The answers given in the book vary due to round off error\n",


+      " \n"


+     ],


+     "language": "python",


+     "metadata": {},


+     "outputs": [


+      {


+       "output_type": "stream",


+       "stream": "stdout",


+       "text": [


+        "\n",


+        " Example 19.14\n",


+        "\n",


+        "\n",


+        " Work input =  1.5195  kJ/rev,\n",


+        " Work input for a vane-type compressor =  1.34802979062  kJ/rev\n"


+       ]


+      }


+     ],


+     "prompt_number": 21


+    },


+    {


+     "cell_type": "heading",


+     "level": 2,


+     "metadata": {},


+     "source": [


+      "Ex19.15:pg-820"


+     ]


+    },


+    {


+     "cell_type": "code",


+     "collapsed": false,


+     "input": [


+      "\n",


+      "# Given that\n",


+      "m = 1.0 # Mass flow rate in kg/s\n",


+      "r = 2.0 # Prssure ratio of blower \n",


+      "t1 = 70.0 # Inlet temperature in degree centigrade\n",


+      "p1 = 1.0 # Inlet pressure in bar\n",


+      "R = 0.29 # Gas constant in kJ/kgK\n",


+      "x = 0.7 # Reduction in pressure ratio and intake volume \n",


+      "gama = 1.4\n",


+      "print \"\\n Example 19.15\\n\"\n",


+      "T1 = t1+273\n",


+      "V = m*R*T1/(p1*100)\n",


+      "P = V*(p1*r-p1)*100\n",


+      "p2 = p1*((1/x)**(gama))\n",


+      "V2 = x*V\n",


+      "P_ = (gama/(gama-1))*(p1*100*V)*((p2/p1)**((gama-1)/gama)-1) + V2*(p1*r-p2)*100\n",


+      "\n",


+      "print \"\\n Power required to drive the blower = \",P ,\" kW,\\n Power required = \",P_ ,\" kW\"\n",


+      "# The answers given in the book vary due to round off error\n",


+      " \n"


+     ],


+     "language": "python",


+     "metadata": {},


+     "outputs": [


+      {


+       "output_type": "stream",


+       "stream": "stdout",


+       "text": [


+        "\n",


+        " Example 19.15\n",


+        "\n",


+        "\n",


+        " Power required to drive the blower =  99.47  kW,\n",


+        " Power required =  77.9220893777  kW\n"


+       ]


+      }


+     ],


+     "prompt_number": 22


+    },


+    {


+     "cell_type": "heading",


+     "level": 2,


+     "metadata": {},


+     "source": [


+      "Ex19.16:pg-820"


+     ]


+    },


+    {


+     "cell_type": "code",


+     "collapsed": false,


+     "input": [


+      "\n",


+      "# Given that\n",


+      "r1 = 2.5 # Pressure ratio of compressor for first stage\n",


+      "r2 = 2.1 # Pressure ratio of compressor for second stage\n",


+      "m = 5.0 # Mass flow rate of air in kg/s \n",


+      "t1 = 10.0 # Inlet temperature in degree centigrade\n",


+      "p1 = 1.013 # Inlet pressure in bar\n",


+      "td = 50.0 # Temperature drop in intercooler in degree centigreade\n",


+      "n_iso = .85 # Isentropic efficiency\n",


+      "cp = 1.005 # Heat capacity of air in kJ/kgK\n",


+      "x = 0.7 # Reduction in pressure ratio and intake volume \n",


+      "gama = 1.4 # Ratio of heat capacities for air\n",


+      "print \"\\n Example 19.16\\n\"\n",


+      "T1 = t1+273\n",


+      "T2s = T1*((r1)**((gama-1)/gama))\n",


+      "T2 = T1 + (T2s-T1)/n_iso\n",


+      "T3 = T2 - td\n",


+      "T4s = T3*((r2)**((gama-1)/gama))\n",


+      "T4 = T3 + (T4s-T3)/n_iso\n",


+      "P = m*cp*((T2-T1)+(T4-T3))\n",


+      "print \"\\n Actual temperature at the end of first stage = \",T2 ,\" K,\\n Actual temperature at the end of second stage = \",T4 ,\" K,\\n The total compressor power = \",P ,\" kW\"\n",


+      "# The answers given in the book vary due to round off error"


+     ],


+     "language": "python",


+     "metadata": {},


+     "outputs": [


+      {


+       "output_type": "stream",


+       "stream": "stdout",


+       "text": [


+        "\n",


+        " Example 19.16\n",


+        "\n",


+        "\n",


+        " Actual temperature at the end of first stage =  382.63704941  K,\n",


+        " Actual temperature at the end of second stage =  425.041961043  K,\n",


+        " The total compressor power =  965.01085424  kW\n"


+       ]


+      }


+     ],


+     "prompt_number": 23


+    },


+    {


+     "cell_type": "heading",


+     "level": 2,


+     "metadata": {},


+     "source": [


+      "Ex19.17:pg-821"


+     ]


+    },


+    {


+     "cell_type": "code",


+     "collapsed": false,


+     "input": [


+      "# Given that\n",


+      "r = 2.5 # Static pressure ratio of supercharger \n",


+      "p1 = 0.6 # Static inlet pressure in bar\n",


+      "t1 = 5 # Static inlet temperature in degree centigrade\n",


+      "A_r = 13.0 # Air-fuel ratio\n",


+      "m = 0.04 # The rate of fuel consumed by the engine in kg/s\n",


+      "gama= 1.39 # For air-fuel mixture \n",


+      "cp = 1.005 # Heat capacity for air-fuel mixture in kJ/kgk\n",


+      "n_iso = .84 # Isentropic efficiency of compressor \n",


+      "v = 120.0 # Exit velocity from the compressor in m/s\n",


+      "print \"\\n Example 19.17\\n\"\n",


+      "T1 = t1+273\n",


+      "T2s = T1*((r)**((gama-1)/gama))\n",


+      "T2 = T1 +(T2s-T1)/n_iso\n",


+      "m_g = m*(A_r+1)\n",


+      "P = m_g*cp*(T2-T1)\n",


+      "T02 = T2 + (v**2)/(2*cp*1000)\n",


+      "t02 = T02-273\n",


+      "p02 = p1*r*((T02/T2)**(gama/(gama-1)))*100\n",


+      "print \"\\n Power required to drive the compressor = \",P ,\" kW,\\n Stagnatio temperature = \",t02 ,\" degree centigrade,\\n Stagnation pressure = \",p02 ,\" kPa\"\n",


+      "# The answers given in the book vary due to round off error\n",


+      " \n"


+     ],


+     "language": "python",


+     "metadata": {},


+     "outputs": [


+      {


+       "output_type": "stream",


+       "stream": "stdout",


+       "text": [


+        "\n",


+        " Example 19.17\n",


+        "\n",


+        "\n",


+        " Power required to drive the compressor =  54.6039650117  kW,\n",


+        " Stagnatio temperature =  109.18614963  degree centigrade,\n",


+        " Stagnation pressure =  160.465577551  kPa\n"


+       ]


+      }


+     ],


+     "prompt_number": 24


+    },


+    {


+     "cell_type": "heading",


+     "level": 2,


+     "metadata": {},


+     "source": [


+      "Ex19.18:pg-821"


+     ]


+    },


+    {


+     "cell_type": "code",


+     "collapsed": false,


+     "input": [


+      "\n",


+      "# Given that\n",


+      "N = 10000 # Speed in RPM\n",


+      "V = 1.2 # Volume flow rate of free air in m**3/s\n",


+      "p1 = 1.0 # Inlet pressure in bar\n",


+      "t1 = 27.0 # Inlet temperature in degree centigrade\n",


+      "r = 5.0 # Pressure ratio\n",


+      "vf = 60.0 # Velocity flow rate in m/s\n",


+      "sigma = 0.9 # Slip factor\n",


+      "n_iso = 0.85 # Isentropic efficiency\n",


+      "gama = 1.4\n",


+      "R = 0.287\n",


+      "cp = 1.005\n",


+      "print \"\\n Example 19.18\\n\"\n",


+      "T1 = t1+273\n",


+      "T2s = T1*((r)**((gama-1)/gama))\n",


+      "T2 = T1 +(T2s-T1)/n_iso\n",


+      "m = p1*100*V/(R*288)\n",


+      "Wc = m*cp*(T2-T1)\n",


+      "Vb2 = (Wc*1000/(m*sigma))**(1.0/2.0)\n",


+      "D = Vb2*60/(math.pi*N)\n",


+      "Vb1 = Vb2/2\n",


+      "beta1 = math.atan(vf/Vb1)\n",


+      "alpha = math.atan(vf/(sigma*Vb2))\n",


+      "print \"\\n The temperature of air at outlet = \",T2-273 ,\" degree centigrade,\\n Power input = \",Wc ,\" kW,\\n Diameter of impeller = \",D ,\" m, \\n Blade inlet angle = \",beta1 ,\" degree,\\n Diffuser inlet angle = \",alpha ,\" degree \"\n",


+      "# The answers given in the book vary due to round off error\n",


+      " \n"


+     ],


+     "language": "python",


+     "metadata": {},


+     "outputs": [


+      {


+       "output_type": "stream",


+       "stream": "stdout",


+       "text": [


+        "\n",


+        " Example 19.18\n",


+        "\n",


+        "\n",


+        " The temperature of air at outlet =  233.053979565  degree centigrade,\n",


+        " Power input =  300.644961473  kW,\n",


+        " Diameter of impeller =  0.916122726914  m, \n",


+        " Blade inlet angle =  0.245135262084  degree,\n",


+        " Diffuser inlet angle =  0.138096713577  degree \n"


+       ]


+      }


+     ],


+     "prompt_number": 27


+    },


+    {


+     "cell_type": "heading",


+     "level": 2,


+     "metadata": {},


+     "source": [


+      "Ex19.19:pg-821"


+     ]


+    },


+    {


+     "cell_type": "code",


+     "collapsed": false,


+     "input": [


+      "\n",


+      "# Given that\n",


+      "N = 264 # Speed in RPS\n",


+      "sigma = 0.91 # Slip factor\n",


+      "d = 0.482 # Impeller diameter in m\n",


+      "D = 0.306 # Impeller eye diameter\n",


+      "D_ = 0.153 # Impeller root eye diameter in m\n",


+      "vf = 138 # Uniform axial inlet velocity in m/s\n",


+      "V = 1.2 # Volume flow rate of free air in m**3/s\n",


+      "m = 9.1 # Air mass flow rate in kg/s\n",


+      "T1 = 294 # Inlet air stagnation temperature in K\n",


+      "n_iso = 0.8 # Total head isentropic efficiency\n",


+      "n_mech = 0.98 # Mechanical efficiency\n",


+      "gama = 1.4 # Ratio of heat capacities\n",


+      "cp = 1.006 # Heat capacity in kJ/kgK\n",


+      "print \"\\n Example 19.19\\n\"\n",


+      "Wc = m*sigma*(2*math.pi*d*N/2)/1000\n",


+      "P_e = Wc/n_mech\n",


+      "delta_T = Wc/(m*cp)\n",


+      "delta_T_ideal = delta_T*n_iso\n",


+      "T2_i = delta_T_ideal + T1\n",


+      "r = (T2_i/T1)**(gama/(gama-1)) # Where r = p02/p01\n",


+      "Vb = 2*math.pi*N*D/2\n",


+      "V_er = (2*math.pi*N*D_/2)\n",


+      "beta1 = math.atan(vf/Vb)\n",


+      "beta2 = math.atan(vf/V_er)\n",


+      "beta1_ = (beta1 - floor(beta1))*60\n",


+      "beta2_ = (beta2 - floor(beta2))*60\n",


+      "print \"\\n Total head pressure ratio = \",r ,\", \\n The required power at input shaft = \",P_e ,\" kW,\\n Inlet angle at the root = \",floor(beta1) ,\" degree and \",beta1_ ,\" minute,\\n Inlet angle at the tip = \",floor(beta2) ,\" degree and \",beta2_ ,\" minute\"\n",


+      "# The answers given in the book for total head pressure ratio and required power at input shaft contain calculation error\n",


+      " \n"


+     ],


+     "language": "python",


+     "metadata": {},


+     "outputs": [


+      {


+       "output_type": "stream",


+       "stream": "stdout",


+       "text": [


+        "\n",


+        " Example 19.19\n",


+        "\n",


+        "\n",


+        " Total head pressure ratio =  1.00344817308 , \n",


+        " The required power at input shaft =  3.37798367776  kW,\n",


+        " Inlet angle at the root =  0.0  degree and  29.8821913183  minute,\n",


+        " Inlet angle at the tip =  0.0  degree and  49.6377044903  minute\n"


+       ]


+      }


+     ],


+     "prompt_number": 20


+    },


+    {


+     "cell_type": "heading",


+     "level": 2,


+     "metadata": {},


+     "source": [


+      "Ex19.20:pg-821"


+     ]


+    },


+    {


+     "cell_type": "code",


+     "collapsed": false,


+     "input": [


+      "# Given that\n",


+      "N = 16000.0 # Speed in RPM\n",


+      "t1 = 17.0 # Intake temperture of gas in degree centigrade\n",


+      "rp = 4.0 # Pressure ratio\n",


+      "sigma = 0.85# Slip factor\n",


+      "n_iso = 0.82 # Isentropic efficiency\n",


+      "alpha_wirl = 20.0 # Pre-wirl angle in degree\n",


+      "d1 = 200.0 # Mean diameter of impeller eye in mm\n",


+      "V1 = 120.0 #Absolute air velocity in m/s\n",


+      "gama = 1.4 # Ratio of heat capacities\n",


+      "cp = 1.005 # Heat capacity in kJ/kgK\n",


+      "print \"\\n Example 19.20\\n\"\n",


+      "T1 = t1 + 273\n",


+      "T2s = T1*((rp)**((gama-1)/gama))\n",


+      "delta_Ts = T2s-1\n",


+      "delta_T = delta_Ts/n_iso\n",


+      "Wc = 1 *cp*delta_T\n",


+      "Vb1 = (math.pi*d1*(1e-3)*N)/60\n",


+      "Vw1 = V1*sin(alpha_wirl)\n",


+      "Vb2 = 459.78 # By solving quadratic equation 172.81e3=0.85*Vb2**2-167.55*41.05\n",


+      "d2 = Vb2*60/(math.pi*N)\n",


+      "\n",


+      "print \"\\n Impeller tip diameter = \",d2*1000 ,\" mm\"\n",


+      "# The answer given in the book varies due to round off error\n",


+      " \n"


+     ],


+     "language": "python",


+     "metadata": {},


+     "outputs": [


+      {


+       "output_type": "stream",


+       "stream": "stdout",


+       "text": [


+        "\n",


+        " Example 19.20\n",


+        "\n",


+        "\n",


+        " Impeller tip diameter =  548.821948011  mm\n"


+       ]


+      }


+     ],


+     "prompt_number": 3


+    },


+    {


+     "cell_type": "heading",


+     "level": 2,


+     "metadata": {},


+     "source": [


+      "Ex19.21:pg-821"


+     ]


+    },


+    {


+     "cell_type": "code",


+     "collapsed": false,


+     "input": [


+      "# Given that\n",


+      "m = 2.5 # Mass flow rate in kg/s\n",


+      "p1 = 1.0 # Inlet pressure in bar\n",


+      "T1 = 300.0 # Inlet temperature in bar\n",


+      "n_s = 0.88 # Stage efficiency\n",


+      "Wc = 600.0 # Power input in kW\n",


+      "delta_t = 21.0 # Temperature rise in first stage in degree centigrade\n",


+      "gama = 1.4 # Ratio of heat capacities \n",


+      "cp = 1.005 # Heat capacity in kJ/kgK\n",


+      "print \"\\n Example 19.21\\n\"\n",


+      "x = n_s*gama/(gama-1)# Where x = (n/(n-1))\n",


+      "T = Wc/(m*cp)+T1\n",


+      "p = p1*((T/T1)**(x))\n",


+      "T2 = T1 + n_s*delta_t\n",


+      "r = ((T2/T1)**(gama/(gama-1)))# Where r = p2/p1\n",


+      "N = log(p/p1)/log(r)\n",


+      "N_ = math. ceil(N)\n",


+      "Ts = T1*(p/p1)**((gama-1)/gama)\n",


+      "n_inter = (Ts-T1)/(T-T1)\n",


+      "print \"\\n The delivery pressure = \",p ,\" bar,\\n The no of stages = \",N_ ,\",\\n The internal efficiency = \",n_inter ,\" \""


+     ],


+     "language": "python",


+     "metadata": {},


+     "outputs": [


+      {


+       "output_type": "stream",


+       "stream": "stdout",


+       "text": [


+        "\n",


+        " Example 19.21\n",


+        "\n",


+        "\n",


+        " The delivery pressure =  6.07125291521  bar,\n",


+        " The no of stages =  9.0 ,\n",


+        " The internal efficiency =  0.84689822539  \n"


+       ]


+      }


+     ],


+     "prompt_number": 1


+    },


+    {


+     "cell_type": "heading",


+     "level": 2,


+     "metadata": {},


+     "source": [


+      "Ex19.22:pg-821"


+     ]


+    },


+    {


+     "cell_type": "code",


+     "collapsed": false,


+     "input": [


+      "\n",


+      "# Given that\n",


+      "D = 0.5 # Mean diameter of impeller in m\n",


+      "N = 15000.0 # Speed in RPM\n",


+      "Vf = 230.0 # Velocity of flow in m/s\n",


+      "p1 = 1.0  # Inlet pressure in bar\n",


+      "T1 = 300.0 # Inlet temperature in K\n",


+      "Vw1 = 80.0 # Velocity of whirl at inlet in m/s\n",


+      "n_s = 0.88 # Stage efficiency\n",


+      "rp = 1.5 # Pressure ratio\n",


+      "gama = 1.4 \n",


+      "cp = 1.0005\n",


+      "print \"\\n Example 19.22\\n\"\n",


+      "Vb = (math.pi*D*N/60)\n",


+      "Ts = T1*((rp)**((gama-1)/gama))\n",


+      "T = T1 + (Ts-T1)/n_s\n",


+      "Wc = cp*(T-T1)\n",


+      "Vw2 = Vw1 + (Wc*1000)/(Vb)\n",


+      "beta1 = math.atan(Vf/(Vb-Vw1))\n",


+      "beta2 =  math.atan(Vf/(Vb-Vw2))\n",


+      "theta = beta2-beta1\n",


+      "R = 1-((Vw1+Vw2)/(2*Vb))\n",


+      "\n",


+      "print \"\\n Fluid deflection angle = \",theta ,\" degree,\\n Power input = \",Wc ,\" kJ/kg,\\n The degree of reaction = \",R*100 ,\" percent\"\n",


+      "# The answers given in the book vary because of round off error\n",


+      " \n"


+     ],


+     "language": "python",


+     "metadata": {},


+     "outputs": [


+      {


+       "output_type": "stream",


+       "stream": "stdout",


+       "text": [


+        "\n",


+        " Example 19.22\n",


+        "\n",


+        "\n",


+        " Fluid deflection angle =  0.206163966177  degree,\n",


+        " Power input =  41.8928434516  kJ/kg,\n",


+        " The degree of reaction =  66.0453433333  percent\n"


+       ]


+      }


+     ],


+     "prompt_number": 6


+    },


+    {


+     "cell_type": "heading",


+     "level": 2,


+     "metadata": {},


+     "source": [


+      "Ex19.23:pg-821"


+     ]


+    },


+    {


+     "cell_type": "code",


+     "collapsed": false,


+     "input": [


+      "\n",


+      "# Given that\n",


+      "v = 5.0 #olume flow rate in m**3/s\n",


+      "d = 1.0 #ean impeller diameter in m\n",


+      "D = 0.6 # Hub diameter in m\n",


+      "N = 600.0 #otational speed in RPM\n",


+      "h = 35.0 #heoratical head in mm\n",


+      "rho = 1.2 # Density of air in kg/m**3\n",


+      "rho_w = 1000.0 #ensity of water in kg/m**3\n",


+      "print \"\\n Example 19.23\\n\"\n",


+      "Vf = v*4/(math.pi*(d**2 - D**2))\n",


+      "Vb = (math.pi*d*N/60)\n",


+      "Vb_ = (math.pi*D*N/60)\n",


+      "H = h/rho\n",


+      "Vw2 = H*9.81/(Vb)\n",


+      "Vw2_ = H*9.81/(Vb_)\n",


+      "beta_tip = (Vf/(Vb_-Vw2))\n",


+      "beta_hub = (Vf/(Vb_-Vw2_))\n",


+      "print \"\\n Blade angle at the tip = \",beta_tip ,\" degree,\\n Blade angle at the hub = \",beta_hub ,\" degree\"\n",


+      "# The answers given in the book vary because of round off error\n",


+      " \n"


+     ],


+     "language": "python",


+     "metadata": {},


+     "outputs": [


+      {


+       "output_type": "stream",


+       "stream": "stdout",


+       "text": [


+        "\n",


+        " Example 19.23\n",


+        "\n",


+        "\n",


+        " Blade angle at the tip =  1.02107077046  degree,\n",


+        " Blade angle at the hub =  2.71029118833  degree\n"


+       ]


+      }


+     ],


+     "prompt_number": 16


+    },


+    {


+     "cell_type": "heading",


+     "level": 2,


+     "metadata": {},


+     "source": [


+      "Ex19.24:pg-821"


+     ]


+    },


+    {


+     "cell_type": "code",


+     "collapsed": false,


+     "input": [


+      "\n",


+      "# Given that\n",


+      "N0 = 9000.0 # Rotational speed in RPM\n",


+      "Q = 6.0 # Volume flow rate in m**3/s\n",


+      "p1 = 1.0 # Initial pressure in bar\n",


+      "t1 = 25.0 # Initial temperature in degree centigrade\n",


+      "p2 = 2.2 # Compressed pressure in bar\n",


+      "n = 1.33 # Compression index\n",


+      "Vf = 75.0 # Velocity of flow in m/s\n",


+      "beta1 = 30.0 # Blade angle at inlet in degree\n",


+      "beta2 = 55.0 # Blade angle at outlet in degree\n",


+      "d = 0.75 # Diameter of impeller in m\n",


+      "cp = 1.005 \n",


+      "print \"\\n Example 19.24\\n\"\n",


+      "T1 = t1+273\n",


+      "T2 = T1*(p2/p1)**((n-1)/n)\n",


+      "Wc = cp*(T2-T1)\n",


+      "x = Wc # Where x = Vw2*Vb2\n",


+      "y = Vf/tan(beta2)# Where y = Vb2-Vw2(Equation 1)\n",


+      "z = (y**2 +4*x*1000)**(0.5) # Where z = Vw2+Vb2(Equation 2)\n",


+      "# By solving Equation 1 and Equation 2\n",


+      "Vb2 = (y+z)/2\n",


+      "Vw2 = ((z-y)/2)\n",


+      "N = Vb2*60/(math.pi*d)\n",


+      "Vb1 = Vf/tan(beta1)\n",


+      "D1 = Vb1*60/(math.pi*N)\n",


+      "b1 = Q/(math.pi*D1*Vf)\n",


+      "Q_ = Q* (1/p2)*(T2/T1)\n",


+      "b2 = Q_/(math.pi*d*Vf)\n",


+      "print \"\\n Speed of impeller = \",N ,\" RPM,\\n Impeller width at inlet = \",b1*100 ,\" cm,\\n Impeller width at outlet = \",b2*100 ,\" cm,\"\n",


+      "# The answers given in the book vary because of round off error\n"


+     ],


+     "language": "python",


+     "metadata": {},


+     "outputs": [


+      {


+       "output_type": "stream",


+       "stream": "stdout",


+       "text": [


+        "\n",


+        " Example 19.24\n",


+        "\n",


+        "\n",


+        " Speed of impeller = "


+       ]


+      },


+      {


+       "output_type": "stream",


+       "stream": "stdout",


+       "text": [


+        " 6456.85894335  RPM,\n",


+        " Impeller width at inlet =  -73.5259022616  cm,\n",


+        " Impeller width at outlet =  1.87680083777  cm,\n"


+       ]


+      }


+     ],


+     "prompt_number": 18


+    }


+   ],


+   "metadata": {}


+  }


+ ]


+}
\ No newline at end of file