�ݺ�ߣshows by User: shonejohn1

�ݺ�ߣshows by User: shonejohn1 / http://www.slideshare.net/images/logo.gif �ݺ�ߣshows by User: shonejohn1 / Thu, 30 Aug 2018 16:31:12 GMT �ݺ�ߣShare feed for �ݺ�ߣshows by User: shonejohn1 shone john resume /slideshow/shone-john-resume-112276990/112276990 futureresume4-180830163112
shone john resume/ cv]]>
shone john resume/ cv]]> Thu, 30 Aug 2018 16:31:12 GMT /slideshow/shone-john-resume-112276990/112276990 shonejohn1@slideshare.net(shonejohn1) shone john resume shonejohn1 shone john resume/ cv <img style="border:1px solid #C3E6D8;float:right;" alt="" src="https://cdn.slidesharecdn.com/ss_thumbnails/futureresume4-180830163112-thumbnail.jpg?width=120&height=120&fit=bounds" /> shone john resume/ cv

shone john resume from shone john

]]> 401 3 https://cdn.slidesharecdn.com/ss_thumbnails/futureresume4-180830163112-thumbnail.jpg?width=120&height=120&fit=bounds document Black http://activitystrea.ms/schema/1.0/post

http://activitystrea.ms/schema/1.0/posted

0 shone john resume /slideshow/shone-john-resume-102530818/102530818 futureresume-180616105517
resume, cv,saintgits,mechanical engineer, fresher engineer]]>
resume, cv,saintgits,mechanical engineer, fresher engineer]]> Sat, 16 Jun 2018 10:55:17 GMT /slideshow/shone-john-resume-102530818/102530818 shonejohn1@slideshare.net(shonejohn1) shone john resume shonejohn1 resume, cv,saintgits,mechanical engineer, fresher engineer <img style="border:1px solid #C3E6D8;float:right;" alt="" src="https://cdn.slidesharecdn.com/ss_thumbnails/futureresume-180616105517-thumbnail.jpg?width=120&height=120&fit=bounds" /> resume, cv,saintgits,mechanical engineer, fresher engineer

shone john resume from shone john

]]> 220 4 https://cdn.slidesharecdn.com/ss_thumbnails/futureresume-180616105517-thumbnail.jpg?width=120&height=120&fit=bounds document Black http://activitystrea.ms/schema/1.0/post

http://activitystrea.ms/schema/1.0/posted

0 INTERNSHIP/ INDUSTRIAL TRAINING REPORT /slideshow/internship-industrial-training-report/99079636 downloadfile-180527193822
COCHIN SHIPYARD, KSRTC MAVELIKARA, TRAVANCORE SUGARS AND CHEMICALS INDUSTRIAL TRAINING/ INTERNSHIP REPORT]]>
COCHIN SHIPYARD, KSRTC MAVELIKARA, TRAVANCORE SUGARS AND CHEMICALS INDUSTRIAL TRAINING/ INTERNSHIP REPORT]]> Sun, 27 May 2018 19:38:22 GMT /slideshow/internship-industrial-training-report/99079636 shonejohn1@slideshare.net(shonejohn1) INTERNSHIP/ INDUSTRIAL TRAINING REPORT shonejohn1 COCHIN SHIPYARD, KSRTC MAVELIKARA, TRAVANCORE SUGARS AND CHEMICALS INDUSTRIAL TRAINING/ INTERNSHIP REPORT <img style="border:1px solid #C3E6D8;float:right;" alt="" src="https://cdn.slidesharecdn.com/ss_thumbnails/downloadfile-180527193822-thumbnail.jpg?width=120&height=120&fit=bounds" /> COCHIN SHIPYARD, KSRTC MAVELIKARA, TRAVANCORE SUGARS AND CHEMICALS INDUSTRIAL TRAINING/ INTERNSHIP REPORT

INTERNSHIP/ INDUSTRIAL TRAINING REPORT from shone john

]]> 10536 9 https://cdn.slidesharecdn.com/ss_thumbnails/downloadfile-180527193822-thumbnail.jpg?width=120&height=120&fit=bounds document Black http://activitystrea.ms/schema/1.0/post

http://activitystrea.ms/schema/1.0/posted

0 INDUSTRIAL SAFETY /slideshow/industrial-safety-99062680/99062680 module15filesmerged-180527162539
Module-I (12 Hours) Development of safety movement: - Need for safety-safety and productivity-planning for safetyplanning procedure-safety policy-formulation of safety policy-safety budget-role and qualification of safety professional-safety committees-need, types and functions of committeessafety organizations. Module II (12 Hours) Accident prevention: - Basic philosophy of accident prevention-nature and causes of accidentsaccident proneness-cost of accidents-accident prevention methods-Domino theory-safety education and training-training methods-motivation and communicating safety-personal protective equipments. Module III (12 Hours) Safety management techniques: - Safety inspection-Safety sampling technique-Safety audit- Safety survey-Incident recall technique-Job safety analysis-Damage control-Risk management. Involvement in safety: - Role of management-role of supervisors-role of workmen- role of unions-role of government Module IV (12 Hours) Occupational health and hygiene: - Functional units and activities of occupational health and hygiene-types of industrial hazards-physical, chemical, mechanical, electrical, social, biological, ergonomic and environmental hazards-factors impeding safety-house keeping-hearing conservation programme Module V (12 Hours) Industrial fire protection: - Fire chemistry-classification of fires-fire prevention activities-fire risks-fire load -contributing factors to industrial fires-fire detection-industrial fire protection systems.]]>
Module-I (12 Hours) Development of safety movement: - Need for safety-safety and productivity-planning for safetyplanning procedure-safety policy-formulation of safety policy-safety budget-role and qualification of safety professional-safety committees-need, types and functions of committeessafety organizations. Module II (12 Hours) Accident prevention: - Basic philosophy of accident prevention-nature and causes of accidentsaccident proneness-cost of accidents-accident prevention methods-Domino theory-safety education and training-training methods-motivation and communicating safety-personal protective equipments. Module III (12 Hours) Safety management techniques: - Safety inspection-Safety sampling technique-Safety audit- Safety survey-Incident recall technique-Job safety analysis-Damage control-Risk management. Involvement in safety: - Role of management-role of supervisors-role of workmen- role of unions-role of government Module IV (12 Hours) Occupational health and hygiene: - Functional units and activities of occupational health and hygiene-types of industrial hazards-physical, chemical, mechanical, electrical, social, biological, ergonomic and environmental hazards-factors impeding safety-house keeping-hearing conservation programme Module V (12 Hours) Industrial fire protection: - Fire chemistry-classification of fires-fire prevention activities-fire risks-fire load -contributing factors to industrial fires-fire detection-industrial fire protection systems.]]> Sun, 27 May 2018 16:25:39 GMT /slideshow/industrial-safety-99062680/99062680 shonejohn1@slideshare.net(shonejohn1) INDUSTRIAL SAFETY shonejohn1 Module-I (12 Hours) Development of safety movement: - Need for safety-safety and productivity-planning for safetyplanning procedure-safety policy-formulation of safety policy-safety budget-role and qualification of safety professional-safety committees-need, types and functions of committeessafety organizations. Module II (12 Hours) Accident prevention: - Basic philosophy of accident prevention-nature and causes of accidentsaccident proneness-cost of accidents-accident prevention methods-Domino theory-safety education and training-training methods-motivation and communicating safety-personal protective equipments. Module III (12 Hours) Safety management techniques: - Safety inspection-Safety sampling technique-Safety audit- Safety survey-Incident recall technique-Job safety analysis-Damage control-Risk management. Involvement in safety: - Role of management-role of supervisors-role of workmen- role of unions-role of government Module IV (12 Hours) Occupational health and hygiene: - Functional units and activities of occupational health and hygiene-types of industrial hazards-physical, chemical, mechanical, electrical, social, biological, ergonomic and environmental hazards-factors impeding safety-house keeping-hearing conservation programme Module V (12 Hours) Industrial fire protection: - Fire chemistry-classification of fires-fire prevention activities-fire risks-fire load -contributing factors to industrial fires-fire detection-industrial fire protection systems. <img style="border:1px solid #C3E6D8;float:right;" alt="" src="https://cdn.slidesharecdn.com/ss_thumbnails/module15filesmerged-180527162539-thumbnail.jpg?width=120&height=120&fit=bounds" /> Module-I (12 Hours) Development of safety movement: - Need for safety-safety and productivity-planning for safetyplanning procedure-safety policy-formulation of safety policy-safety budget-role and qualification of safety professional-safety committees-need, types and functions of committeessafety organizations. Module II (12 Hours) Accident prevention: - Basic philosophy of accident prevention-nature and causes of accidentsaccident proneness-cost of accidents-accident prevention methods-Domino theory-safety education and training-training methods-motivation and communicating safety-personal protective equipments. Module III (12 Hours) Safety management techniques: - Safety inspection-Safety sampling technique-Safety audit- Safety survey-Incident recall technique-Job safety analysis-Damage control-Risk management. Involvement in safety: - Role of management-role of supervisors-role of workmen- role of unions-role of government Module IV (12 Hours) Occupational health and hygiene: - Functional units and activities of occupational health and hygiene-types of industrial hazards-physical, chemical, mechanical, electrical, social, biological, ergonomic and environmental hazards-factors impeding safety-house keeping-hearing conservation programme Module V (12 Hours) Industrial fire protection: - Fire chemistry-classification of fires-fire prevention activities-fire risks-fire load -contributing factors to industrial fires-fire detection-industrial fire protection systems.

INDUSTRIAL SAFETY from shone john

]]> 11524 14 https://cdn.slidesharecdn.com/ss_thumbnails/module15filesmerged-180527162539-thumbnail.jpg?width=120&height=120&fit=bounds presentation Black http://activitystrea.ms/schema/1.0/post

http://activitystrea.ms/schema/1.0/posted

0 SOCIAL SERVICE /slideshow/social-service-99059115/99059115 ilovepdfmerged1-180527154638
EMMANUEL CHILDREN'S HOME]]>
EMMANUEL CHILDREN'S HOME]]> Sun, 27 May 2018 15:46:38 GMT /slideshow/social-service-99059115/99059115 shonejohn1@slideshare.net(shonejohn1) SOCIAL SERVICE shonejohn1 EMMANUEL CHILDREN'S HOME <img style="border:1px solid #C3E6D8;float:right;" alt="" src="https://cdn.slidesharecdn.com/ss_thumbnails/ilovepdfmerged1-180527154638-thumbnail.jpg?width=120&height=120&fit=bounds" /> EMMANUEL CHILDREN'S HOME

SOCIAL SERVICE from shone john

]]> 381 3 https://cdn.slidesharecdn.com/ss_thumbnails/ilovepdfmerged1-180527154638-thumbnail.jpg?width=120&height=120&fit=bounds document Black http://activitystrea.ms/schema/1.0/post

http://activitystrea.ms/schema/1.0/posted

0 Non ferrous alloys /slideshow/non-ferrous-alloys-97268502/97268502 shonecopperseminar-180516090200
Non ferrous alloys]]>
Non ferrous alloys]]> Wed, 16 May 2018 09:02:00 GMT /slideshow/non-ferrous-alloys-97268502/97268502 shonejohn1@slideshare.net(shonejohn1) Non ferrous alloys shonejohn1 Non ferrous alloys <img style="border:1px solid #C3E6D8;float:right;" alt="" src="https://cdn.slidesharecdn.com/ss_thumbnails/shonecopperseminar-180516090200-thumbnail.jpg?width=120&height=120&fit=bounds" /> Non ferrous alloys

Non ferrous alloys from shone john

]]> 447 1 https://cdn.slidesharecdn.com/ss_thumbnails/shonecopperseminar-180516090200-thumbnail.jpg?width=120&height=120&fit=bounds presentation Black http://activitystrea.ms/schema/1.0/post

http://activitystrea.ms/schema/1.0/posted

0 DESIGN AND DEVELOPMENT OF A HYBRID MACHINE COMBINING RAPID PROTOTYPING AND CNC MILLING OPERATION /slideshow/design-and-development-of-a-hybrid-machine-combining-rapid-prototyping-and-cnc-milling-operation/97267958 report-180516085450
Seminar report saintgits college of engineering]]>
Seminar report saintgits college of engineering]]> Wed, 16 May 2018 08:54:50 GMT /slideshow/design-and-development-of-a-hybrid-machine-combining-rapid-prototyping-and-cnc-milling-operation/97267958 shonejohn1@slideshare.net(shonejohn1) DESIGN AND DEVELOPMENT OF A HYBRID MACHINE COMBINING RAPID PROTOTYPING AND CNC MILLING OPERATION shonejohn1 Seminar report saintgits college of engineering <img style="border:1px solid #C3E6D8;float:right;" alt="" src="https://cdn.slidesharecdn.com/ss_thumbnails/report-180516085450-thumbnail.jpg?width=120&height=120&fit=bounds" /> Seminar report saintgits college of engineering

DESIGN AND DEVELOPMENT OF A HYBRID MACHINE COMBINING RAPID PROTOTYPING AND CNC MILLING OPERATION from shone john

]]> 365 5 https://cdn.slidesharecdn.com/ss_thumbnails/report-180516085450-thumbnail.jpg?width=120&height=120&fit=bounds document Black http://activitystrea.ms/schema/1.0/post

http://activitystrea.ms/schema/1.0/posted

0 Design of transmission elements /slideshow/design-of-transmission-elements/97267731 dtefull-180516085203
ME010 801 Design of Transmission Elements (Common with AU010 801) Teaching scheme Credits: 4 2 hours lecture, 2 hour tutorial and 1 hour drawing per week Objectives To provide basic design skill with regard to various transmission elements like clutches, brakes, bearings and gears. Module I (20 Hrs) Clutches - friction clutches- design considerations-multiple disc clutches-cone clutch- centrifugal clutch - Brakes- Block brake- band brake- band and block brake-internal expanding shoe brake. Module II (17 Hrs) Design of bearings - Types - Selection of a bearing type - bearing life - Rolling contact bearings - static and dynamic load capacity - axial and radial loads - selection of bearings - dynamic equivalent load - lubrication and lubricants - viscosity - Journal bearings - hydrodynamic theory - design considerations - heat balance - bearing characteristic number - hydrostatic bearings. Module III (19 Hrs) Gears- classification- Gear nomenclature - Tooth profiles - Materials of gears - design of spur, helical, bevel gears and worm & worm wheel - Law of gearing - virtual or formative number of teeth- gear tooth failures- Beam strength - Lewis equation- Buckingham’s equation for dynamic load- wear loadendurance strength of tooth- surface durability- heat dissipation - lubrication of gears - Merits and demerits of each type of gears. Module IV (16 Hrs) Design of Internal Combustion Engine parts- Piston, Cylinder, Connecting rod, Flywheel Design recommendations for Forgings- castings and welded products- rolled sections- turned parts, screw machined products- Parts produced on milling machines. Design for manufacturing - preparation of working drawings - working drawings for manufacture of parts with complete specifications including manufacturing details. Note: Any one of the following data book is permitted for reference in the final University examination: 1. Machine Design Data hand book by K. Lingaiah, Suma Publishers, Bangalore/ Tata Mc Graw Hill 2. PSG Design Data, DPV Printers, Coimbatore. Text Books 1. C.S,Sarma, Kamlesh Purohit, Design of Machine Elements Prentice Hall of India Ltd NewDelhi 2. V.B.Bhandari, Design of Machine Elements McGraw Hill Book Company 3. M. F. Spotts, T. E. Shoup, Design of Machine Elements, Pearson Education. Reference Books 1. J. E. Shigley, Mechanical Engineering Design, McGraw Hill Book Company. 2. Juvinall R.C & Marshek K.M., Fundamentals of Machine Component Design, John Wiley 3. Doughtie V.L., & Vallance A.V., Design of Machine Elements, McGraw Hill Book Company. 4. Siegel, Maleev & Hartman, Mechanical Design of Machines, International Book Company]]>
ME010 801 Design of Transmission Elements (Common with AU010 801) Teaching scheme Credits: 4 2 hours lecture, 2 hour tutorial and 1 hour drawing per week Objectives To provide basic design skill with regard to various transmission elements like clutches, brakes, bearings and gears. Module I (20 Hrs) Clutches - friction clutches- design considerations-multiple disc clutches-cone clutch- centrifugal clutch - Brakes- Block brake- band brake- band and block brake-internal expanding shoe brake. Module II (17 Hrs) Design of bearings - Types - Selection of a bearing type - bearing life - Rolling contact bearings - static and dynamic load capacity - axial and radial loads - selection of bearings - dynamic equivalent load - lubrication and lubricants - viscosity - Journal bearings - hydrodynamic theory - design considerations - heat balance - bearing characteristic number - hydrostatic bearings. Module III (19 Hrs) Gears- classification- Gear nomenclature - Tooth profiles - Materials of gears - design of spur, helical, bevel gears and worm & worm wheel - Law of gearing - virtual or formative number of teeth- gear tooth failures- Beam strength - Lewis equation- Buckingham’s equation for dynamic load- wear loadendurance strength of tooth- surface durability- heat dissipation - lubrication of gears - Merits and demerits of each type of gears. Module IV (16 Hrs) Design of Internal Combustion Engine parts- Piston, Cylinder, Connecting rod, Flywheel Design recommendations for Forgings- castings and welded products- rolled sections- turned parts, screw machined products- Parts produced on milling machines. Design for manufacturing - preparation of working drawings - working drawings for manufacture of parts with complete specifications including manufacturing details. Note: Any one of the following data book is permitted for reference in the final University examination: 1. Machine Design Data hand book by K. Lingaiah, Suma Publishers, Bangalore/ Tata Mc Graw Hill 2. PSG Design Data, DPV Printers, Coimbatore. Text Books 1. C.S,Sarma, Kamlesh Purohit, Design of Machine Elements Prentice Hall of India Ltd NewDelhi 2. V.B.Bhandari, Design of Machine Elements McGraw Hill Book Company 3. M. F. Spotts, T. E. Shoup, Design of Machine Elements, Pearson Education. Reference Books 1. J. E. Shigley, Mechanical Engineering Design, McGraw Hill Book Company. 2. Juvinall R.C & Marshek K.M., Fundamentals of Machine Component Design, John Wiley 3. Doughtie V.L., & Vallance A.V., Design of Machine Elements, McGraw Hill Book Company. 4. Siegel, Maleev & Hartman, Mechanical Design of Machines, International Book Company]]> Wed, 16 May 2018 08:52:03 GMT /slideshow/design-of-transmission-elements/97267731 shonejohn1@slideshare.net(shonejohn1) Design of transmission elements shonejohn1 ME010 801 Design of Transmission Elements (Common with AU010 801) Teaching scheme Credits: 4 2 hours lecture, 2 hour tutorial and 1 hour drawing per week Objectives To provide basic design skill with regard to various transmission elements like clutches, brakes, bearings and gears. Module I (20 Hrs) Clutches - friction clutches- design considerations-multiple disc clutches-cone clutch- centrifugal clutch - Brakes- Block brake- band brake- band and block brake-internal expanding shoe brake. Module II (17 Hrs) Design of bearings - Types - Selection of a bearing type - bearing life - Rolling contact bearings - static and dynamic load capacity - axial and radial loads - selection of bearings - dynamic equivalent load - lubrication and lubricants - viscosity - Journal bearings - hydrodynamic theory - design considerations - heat balance - bearing characteristic number - hydrostatic bearings. Module III (19 Hrs) Gears- classification- Gear nomenclature - Tooth profiles - Materials of gears - design of spur, helical, bevel gears and worm & worm wheel - Law of gearing - virtual or formative number of teeth- gear tooth failures- Beam strength - Lewis equation- Buckingham’s equation for dynamic load- wear load�endurance strength of tooth- surface durability- heat dissipation - lubrication of gears - Merits and demerits of each type of gears. Module IV (16 Hrs) Design of Internal Combustion Engine parts- Piston, Cylinder, Connecting rod, Flywheel Design recommendations for Forgings- castings and welded products- rolled sections- turned parts, screw machined products- Parts produced on milling machines. Design for manufacturing - preparation of working drawings - working drawings for manufacture of parts with complete specifications including manufacturing details. Note: Any one of the following data book is permitted for reference in the final University examination: 1. Machine Design Data hand book by K. Lingaiah, Suma Publishers, Bangalore/ Tata Mc Graw Hill 2. PSG Design Data, DPV Printers, Coimbatore. Text Books 1. C.S,Sarma, Kamlesh Purohit, Design of Machine Elements Prentice Hall of India Ltd NewDelhi 2. V.B.Bhandari, Design of Machine Elements McGraw Hill Book Company 3. M. F. Spotts, T. E. Shoup, Design of Machine Elements, Pearson Education. Reference Books 1. J. E. Shigley, Mechanical Engineering Design, McGraw Hill Book Company. 2. Juvinall R.C & Marshek K.M., Fundamentals of Machine Component Design, John Wiley 3. Doughtie V.L., & Vallance A.V., Design of Machine Elements, McGraw Hill Book Company. 4. Siegel, Maleev & Hartman, Mechanical Design of Machines, International Book Company <img style="border:1px solid #C3E6D8;float:right;" alt="" src="https://cdn.slidesharecdn.com/ss_thumbnails/dtefull-180516085203-thumbnail.jpg?width=120&height=120&fit=bounds" /> ME010 801 Design of Transmission Elements (Common with AU010 801) Teaching scheme Credits: 4 2 hours lecture, 2 hour tutorial and 1 hour drawing per week Objectives To provide basic design skill with regard to various transmission elements like clutches, brakes, bearings and gears. Module I (20 Hrs) Clutches - friction clutches- design considerations-multiple disc clutches-cone clutch- centrifugal clutch - Brakes- Block brake- band brake- band and block brake-internal expanding shoe brake. Module II (17 Hrs) Design of bearings - Types - Selection of a bearing type - bearing life - Rolling contact bearings - static and dynamic load capacity - axial and radial loads - selection of bearings - dynamic equivalent load - lubrication and lubricants - viscosity - Journal bearings - hydrodynamic theory - design considerations - heat balance - bearing characteristic number - hydrostatic bearings. Module III (19 Hrs) Gears- classification- Gear nomenclature - Tooth profiles - Materials of gears - design of spur, helical, bevel gears and worm & worm wheel - Law of gearing - virtual or formative number of teeth- gear tooth failures- Beam strength - Lewis equation- Buckingham’s equation for dynamic load- wear load�endurance strength of tooth- surface durability- heat dissipation - lubrication of gears - Merits and demerits of each type of gears. Module IV (16 Hrs) Design of Internal Combustion Engine parts- Piston, Cylinder, Connecting rod, Flywheel Design recommendations for Forgings- castings and welded products- rolled sections- turned parts, screw machined products- Parts produced on milling machines. Design for manufacturing - preparation of working drawings - working drawings for manufacture of parts with complete specifications including manufacturing details. Note: Any one of the following data book is permitted for reference in the final University examination: 1. Machine Design Data hand book by K. Lingaiah, Suma Publishers, Bangalore/ Tata Mc Graw Hill 2. PSG Design Data, DPV Printers, Coimbatore. Text Books 1. C.S,Sarma, Kamlesh Purohit, Design of Machine Elements Prentice Hall of India Ltd NewDelhi 2. V.B.Bhandari, Design of Machine Elements McGraw Hill Book Company 3. M. F. Spotts, T. E. Shoup, Design of Machine Elements, Pearson Education. Reference Books 1. J. E. Shigley, Mechanical Engineering Design, McGraw Hill Book Company. 2. Juvinall R.C & Marshek K.M., Fundamentals of Machine Component Design, John Wiley 3. Doughtie V.L., & Vallance A.V., Design of Machine Elements, McGraw Hill Book Company. 4. Siegel, Maleev & Hartman, Mechanical Design of Machines, International Book Company

Design of transmission elements from shone john

]]> 18300 11 https://cdn.slidesharecdn.com/ss_thumbnails/dtefull-180516085203-thumbnail.jpg?width=120&height=120&fit=bounds document Black http://activitystrea.ms/schema/1.0/post

http://activitystrea.ms/schema/1.0/posted

0 Refrigeration and air conditioning (full note) /slideshow/refrigeration-and-air-conditioning-full-note/97267441 refrigerationandairconditioningfullnote-180516084818
Principles of refrigeration: Thermodynamics of refrigeration - Carnot cycle, reversed carnot cycle, heat pump, and refrigerating machine- coefficient of performance - unit of refrigeration - refrigeration methods- conventional refrigeration systems. Air refrigeration system- Bell Coleman cycle - C.O.P. capacity work and refrigerant flow requirements in Bell - Coleman cycle. Module 2 Vapour compression system: simple cycle -comparison with Carnot cycle - theoretical, actual and reactive - COP effect of operating parameters on COP - wet, dry and superheated compression - under cooling - actual cycle representation on TS and PH diagrams simple problems. Advanced vapour compression systems - multistage vapour compression systems - flash chamber multiple compression and evaporation systems cascading - simple problems. Module 3 Vapour absorption systems: simple, cycles - actual cycle - ammonia water and lithium bromide water systems - COP - electrolux system. Refrigerant and their properties: Nomenclature - suitability of refrigerants for various applications - unconventional refrigeration methods- Vortex tube, steamjet, magnetic (cryogenics) refrigeration and thermoelectric refrigeration - applied refrigeration house hold refrigerators - unit air conditioners andModule 4 Refrigeration system components: condensers - water and air cooled condensers - evaporative condensers - expansion devises - capillary tubeconstant pressure expansion valve - thermostatic expansion valve - float valve and solenoid valve - evaporators - natural convection coils - flooded evaporators - direct expansion coils. Reciprocating compressors: single stage and multistage compressors - work done optimum pressure ratioeffect of interfolding - volumetric efficiency -effect of clearance - isothermal and adiabatic efficiency - compressed air motors. Rotodynamic compressors: Screw and vane type compressors - principle of operation - hermetic, semihermetic and open type refrigeration compressors. Module 5 Principles of air conditioning: Psychrometry and psychrometric chart thermodynamics of human comfort - effective temperature - comfort chart applied psychrometry - sensible heat factor - psychometric processproblems. Winter air conditioning: heating load calculations humidifiers and humidistat. Summer air conditioning: cooling load calculations - year round air conditioning - unitary and central systems - principles of air distribution - design of air duct systems. References 1. Refrigeration and air conditioning - Ballaney P. L. 2. Refrigeration and air conditioning - Stocker W. F. 3. Refrigeration and air conditioning - Jordan and Protester 4. Principles of Refrigeration - Roy J. Dossat]]>
Principles of refrigeration: Thermodynamics of refrigeration - Carnot cycle, reversed carnot cycle, heat pump, and refrigerating machine- coefficient of performance - unit of refrigeration - refrigeration methods- conventional refrigeration systems. Air refrigeration system- Bell Coleman cycle - C.O.P. capacity work and refrigerant flow requirements in Bell - Coleman cycle. Module 2 Vapour compression system: simple cycle -comparison with Carnot cycle - theoretical, actual and reactive - COP effect of operating parameters on COP - wet, dry and superheated compression - under cooling - actual cycle representation on TS and PH diagrams simple problems. Advanced vapour compression systems - multistage vapour compression systems - flash chamber multiple compression and evaporation systems cascading - simple problems. Module 3 Vapour absorption systems: simple, cycles - actual cycle - ammonia water and lithium bromide water systems - COP - electrolux system. Refrigerant and their properties: Nomenclature - suitability of refrigerants for various applications - unconventional refrigeration methods- Vortex tube, steamjet, magnetic (cryogenics) refrigeration and thermoelectric refrigeration - applied refrigeration house hold refrigerators - unit air conditioners andModule 4 Refrigeration system components: condensers - water and air cooled condensers - evaporative condensers - expansion devises - capillary tubeconstant pressure expansion valve - thermostatic expansion valve - float valve and solenoid valve - evaporators - natural convection coils - flooded evaporators - direct expansion coils. Reciprocating compressors: single stage and multistage compressors - work done optimum pressure ratioeffect of interfolding - volumetric efficiency -effect of clearance - isothermal and adiabatic efficiency - compressed air motors. Rotodynamic compressors: Screw and vane type compressors - principle of operation - hermetic, semihermetic and open type refrigeration compressors. Module 5 Principles of air conditioning: Psychrometry and psychrometric chart thermodynamics of human comfort - effective temperature - comfort chart applied psychrometry - sensible heat factor - psychometric processproblems. Winter air conditioning: heating load calculations humidifiers and humidistat. Summer air conditioning: cooling load calculations - year round air conditioning - unitary and central systems - principles of air distribution - design of air duct systems. References 1. Refrigeration and air conditioning - Ballaney P. L. 2. Refrigeration and air conditioning - Stocker W. F. 3. Refrigeration and air conditioning - Jordan and Protester 4. Principles of Refrigeration - Roy J. Dossat]]> Wed, 16 May 2018 08:48:18 GMT /slideshow/refrigeration-and-air-conditioning-full-note/97267441 shonejohn1@slideshare.net(shonejohn1) Refrigeration and air conditioning (full note) shonejohn1 Principles of refrigeration: Thermodynamics of refrigeration - Carnot cycle, reversed carnot cycle, heat pump, and refrigerating machine- coefficient of performance - unit of refrigeration - refrigeration methods- conventional refrigeration systems. Air refrigeration system- Bell Coleman cycle - C.O.P. capacity work and refrigerant flow requirements in Bell - Coleman cycle. Module 2 Vapour compression system: simple cycle -comparison with Carnot cycle - theoretical, actual and reactive - COP effect of operating parameters on COP - wet, dry and superheated compression - under cooling - actual cycle representation on TS and PH diagrams simple problems. Advanced vapour compression systems - multistage vapour compression systems - flash chamber multiple compression and evaporation systems cascading - simple problems. Module 3 Vapour absorption systems: simple, cycles - actual cycle - ammonia water and lithium bromide water systems - COP - electrolux system. Refrigerant and their properties: Nomenclature - suitability of refrigerants for various applications - unconventional refrigeration methods- Vortex tube, steam�jet, magnetic (cryogenics) refrigeration and thermoelectric refrigeration - applied refrigeration house hold refrigerators - unit air conditioners andModule 4 Refrigeration system components: condensers - water and air cooled condensers - evaporative condensers - expansion devises - capillary tube�constant pressure expansion valve - thermostatic expansion valve - float valve and solenoid valve - evaporators - natural convection coils - flooded evaporators - direct expansion coils. Reciprocating compressors: single stage and multistage compressors - work done optimum pressure ratio�effect of interfolding - volumetric efficiency -effect of clearance - isothermal and adiabatic efficiency - compressed air motors. Rotodynamic compressors: Screw and vane type compressors - principle of operation - hermetic, semihermetic and open type refrigeration compressors. Module 5 Principles of air conditioning: Psychrometry and psychrometric chart thermodynamics of human comfort - effective temperature - comfort chart applied psychrometry - sensible heat factor - psychometric process�problems. Winter air conditioning: heating load calculations humidifiers and humidistat. Summer air conditioning: cooling load calculations - year round air conditioning - unitary and central systems - principles of air distribution - design of air duct systems. References 1. Refrigeration and air conditioning - Ballaney P. L. 2. Refrigeration and air conditioning - Stocker W. F. 3. Refrigeration and air conditioning - Jordan and Protester 4. Principles of Refrigeration - Roy J. Dossat <img style="border:1px solid #C3E6D8;float:right;" alt="" src="https://cdn.slidesharecdn.com/ss_thumbnails/refrigerationandairconditioningfullnote-180516084818-thumbnail.jpg?width=120&height=120&fit=bounds" /> Principles of refrigeration: Thermodynamics of refrigeration - Carnot cycle, reversed carnot cycle, heat pump, and refrigerating machine- coefficient of performance - unit of refrigeration - refrigeration methods- conventional refrigeration systems. Air refrigeration system- Bell Coleman cycle - C.O.P. capacity work and refrigerant flow requirements in Bell - Coleman cycle. Module 2 Vapour compression system: simple cycle -comparison with Carnot cycle - theoretical, actual and reactive - COP effect of operating parameters on COP - wet, dry and superheated compression - under cooling - actual cycle representation on TS and PH diagrams simple problems. Advanced vapour compression systems - multistage vapour compression systems - flash chamber multiple compression and evaporation systems cascading - simple problems. Module 3 Vapour absorption systems: simple, cycles - actual cycle - ammonia water and lithium bromide water systems - COP - electrolux system. Refrigerant and their properties: Nomenclature - suitability of refrigerants for various applications - unconventional refrigeration methods- Vortex tube, steam�jet, magnetic (cryogenics) refrigeration and thermoelectric refrigeration - applied refrigeration house hold refrigerators - unit air conditioners andModule 4 Refrigeration system components: condensers - water and air cooled condensers - evaporative condensers - expansion devises - capillary tube�constant pressure expansion valve - thermostatic expansion valve - float valve and solenoid valve - evaporators - natural convection coils - flooded evaporators - direct expansion coils. Reciprocating compressors: single stage and multistage compressors - work done optimum pressure ratio�effect of interfolding - volumetric efficiency -effect of clearance - isothermal and adiabatic efficiency - compressed air motors. Rotodynamic compressors: Screw and vane type compressors - principle of operation - hermetic, semihermetic and open type refrigeration compressors. Module 5 Principles of air conditioning: Psychrometry and psychrometric chart thermodynamics of human comfort - effective temperature - comfort chart applied psychrometry - sensible heat factor - psychometric process�problems. Winter air conditioning: heating load calculations humidifiers and humidistat. Summer air conditioning: cooling load calculations - year round air conditioning - unitary and central systems - principles of air distribution - design of air duct systems. References 1. Refrigeration and air conditioning - Ballaney P. L. 2. Refrigeration and air conditioning - Stocker W. F. 3. Refrigeration and air conditioning - Jordan and Protester 4. Principles of Refrigeration - Roy J. Dossat

Refrigeration and air conditioning (full note) from shone john

]]> 4985 4 https://cdn.slidesharecdn.com/ss_thumbnails/refrigerationandairconditioningfullnote-180516084818-thumbnail.jpg?width=120&height=120&fit=bounds document Black http://activitystrea.ms/schema/1.0/post

http://activitystrea.ms/schema/1.0/posted

0 thermal systems and applications /slideshow/thermal-systems-and-applications/97267046 ts12345-180516084330
Module 1 Steam Engineering: Properties of steam - wet, dry and superheated steam - dryness fraction - enthalpy and internal energy - entropy of steam - temperature entropy diagram - process - Mollier chart - Rankine cycle for wet, dry and superheated steam. Steam Generators - classification - modern steam generators - boiler mountings and accessories. Module 2 Steam nozzles - Mass flow rate - throat pressure for maximum discharge - throat area - effect of friction - super saturated flow. Steam turbines: velocity triangles, work done, governing, and efficiencies. Module 3 Gas turbine Plants - Open and closed cycles - thermodynamics cycles - regeneration, re heating - inter cooling - efficiency and performance of gas turbines. Rotary Compressors - Analysis of rotary compressors - centrifugal and axial compressors. Combustion - combustion chambers of gas turbines - cylindrical, annular and industrial type combustion chamber - combustion intensity - combustion chambers efficiency - pressure loss combustion process and stability loop. Module 4 Introduction to solar energy - solar collectors - Liquid flat plate collectors - principle - thermal losses and efficiency - characteristics - overall loss coefficient - thermal analysis - useful heat gained by fluid - mean plate temperature - performance - focussing type solar collectors - solar concentrators and receivers - sun tracking system - characteristics - optical losses - thermal performance - solar pond - solar water heating - solar thermal power generation Module 5 Thermal power plants: layout and operation of steam and diesel power plants - coal burners - stockers - cooling ponds & towers - chimneys - draught - dust collectors - precipitators - feed water heaters - evaporators - steam condensers - coal handling - ash handling]]>
Module 1 Steam Engineering: Properties of steam - wet, dry and superheated steam - dryness fraction - enthalpy and internal energy - entropy of steam - temperature entropy diagram - process - Mollier chart - Rankine cycle for wet, dry and superheated steam. Steam Generators - classification - modern steam generators - boiler mountings and accessories. Module 2 Steam nozzles - Mass flow rate - throat pressure for maximum discharge - throat area - effect of friction - super saturated flow. Steam turbines: velocity triangles, work done, governing, and efficiencies. Module 3 Gas turbine Plants - Open and closed cycles - thermodynamics cycles - regeneration, re heating - inter cooling - efficiency and performance of gas turbines. Rotary Compressors - Analysis of rotary compressors - centrifugal and axial compressors. Combustion - combustion chambers of gas turbines - cylindrical, annular and industrial type combustion chamber - combustion intensity - combustion chambers efficiency - pressure loss combustion process and stability loop. Module 4 Introduction to solar energy - solar collectors - Liquid flat plate collectors - principle - thermal losses and efficiency - characteristics - overall loss coefficient - thermal analysis - useful heat gained by fluid - mean plate temperature - performance - focussing type solar collectors - solar concentrators and receivers - sun tracking system - characteristics - optical losses - thermal performance - solar pond - solar water heating - solar thermal power generation Module 5 Thermal power plants: layout and operation of steam and diesel power plants - coal burners - stockers - cooling ponds & towers - chimneys - draught - dust collectors - precipitators - feed water heaters - evaporators - steam condensers - coal handling - ash handling]]> Wed, 16 May 2018 08:43:30 GMT /slideshow/thermal-systems-and-applications/97267046 shonejohn1@slideshare.net(shonejohn1) thermal systems and applications shonejohn1 Module 1 Steam Engineering: Properties of steam - wet, dry and superheated steam - dryness fraction - enthalpy and internal energy - entropy of steam - temperature entropy diagram - process - Mollier chart - Rankine cycle for wet, dry and superheated steam. Steam Generators - classification - modern steam generators - boiler mountings and accessories. Module 2 Steam nozzles - Mass flow rate - throat pressure for maximum discharge - throat area - effect of friction - super saturated flow. Steam turbines: velocity triangles, work done, governing, and efficiencies. Module 3 Gas turbine Plants - Open and closed cycles - thermodynamics cycles - regeneration, re heating - inter cooling - efficiency and performance of gas turbines. Rotary Compressors - Analysis of rotary compressors - centrifugal and axial compressors. Combustion - combustion chambers of gas turbines - cylindrical, annular and industrial type combustion chamber - combustion intensity - combustion chambers efficiency - pressure loss combustion process and stability loop. Module 4 Introduction to solar energy - solar collectors - Liquid flat plate collectors - principle - thermal losses and efficiency - characteristics - overall loss coefficient - thermal analysis - useful heat gained by fluid - mean plate temperature - performance - focussing type solar collectors - solar concentrators and receivers - sun tracking system - characteristics - optical losses - thermal performance - solar pond - solar water heating - solar thermal power generation Module 5 Thermal power plants: layout and operation of steam and diesel power plants - coal burners - stockers - cooling ponds & towers - chimneys - draught - dust collectors - precipitators - feed water heaters - evaporators - steam condensers - coal handling - ash handling <img style="border:1px solid #C3E6D8;float:right;" alt="" src="https://cdn.slidesharecdn.com/ss_thumbnails/ts12345-180516084330-thumbnail.jpg?width=120&height=120&fit=bounds" /> Module 1 Steam Engineering: Properties of steam - wet, dry and superheated steam - dryness fraction - enthalpy and internal energy - entropy of steam - temperature entropy diagram - process - Mollier chart - Rankine cycle for wet, dry and superheated steam. Steam Generators - classification - modern steam generators - boiler mountings and accessories. Module 2 Steam nozzles - Mass flow rate - throat pressure for maximum discharge - throat area - effect of friction - super saturated flow. Steam turbines: velocity triangles, work done, governing, and efficiencies. Module 3 Gas turbine Plants - Open and closed cycles - thermodynamics cycles - regeneration, re heating - inter cooling - efficiency and performance of gas turbines. Rotary Compressors - Analysis of rotary compressors - centrifugal and axial compressors. Combustion - combustion chambers of gas turbines - cylindrical, annular and industrial type combustion chamber - combustion intensity - combustion chambers efficiency - pressure loss combustion process and stability loop. Module 4 Introduction to solar energy - solar collectors - Liquid flat plate collectors - principle - thermal losses and efficiency - characteristics - overall loss coefficient - thermal analysis - useful heat gained by fluid - mean plate temperature - performance - focussing type solar collectors - solar concentrators and receivers - sun tracking system - characteristics - optical losses - thermal performance - solar pond - solar water heating - solar thermal power generation Module 5 Thermal power plants: layout and operation of steam and diesel power plants - coal burners - stockers - cooling ponds & towers - chimneys - draught - dust collectors - precipitators - feed water heaters - evaporators - steam condensers - coal handling - ash handling

thermal systems and applications from shone john

]]> 1374 4 https://cdn.slidesharecdn.com/ss_thumbnails/ts12345-180516084330-thumbnail.jpg?width=120&height=120&fit=bounds document Black http://activitystrea.ms/schema/1.0/post

http://activitystrea.ms/schema/1.0/posted

0 Fluid mechanics notes /slideshow/fluid-mechanics-notes-97266357/97266357 fluidmechanics-180516083512
B.TECH. DEGREE COURSE SCHEME AND SYLLABUS (2002-03 admission onwards) MAHATMA GANDHI UNIVERSITY,mg university, KTU KOTTAYAM KERALA Module 1 Introduction - Proprties of fluids - pressure, force, density, specific weight, compressibility, capillarity, surface tension, dynamic and kinematic viscosity-Pascal’s law-Newtonian and non-Newtonian fluids-fluid statics-measurement of pressure-variation of pressure-manometry-hydrostatic pressure on plane and curved surfaces-centre of pressure-buoyancy-floation-stability of submerged and floating bodies-metacentric height-period of oscillation. Module 2 Kinematics of fluid motion-Eulerian and Lagrangian approach-classification and representation of fluid flow- path line, stream line and streak line. Basic hydrodynamics-equation for acceleration-continuity equation-rotational and irrotational flow-velocity potential and stream function-circulation and vorticity-vortex flow-energy variation across stream lines-basic field flow such as uniform flow, spiral flow, source, sink, doublet, vortex pair, flow past a cylinder with a circulation, Magnus effect-Joukowski theorem-coefficient of lift. Module 3 Euler’s momentum equation-Bernoulli’s equation and its limitations-momentum and energy correction factors-pressure variation across uniform conduit and uniform bend-pressure distribution in irrotational flow and in curved boundaries-flow through orifices and mouthpieces, notches and weirs-time of emptying a tank-application of Bernoulli’s theorem-orifice meter, ventury meter, pitot tube, rotameter. Module 4 Navier-Stoke’s equation-body force-Hagen-Poiseullie equation-boundary layer flow theory-velocity variation- methods of controlling-applications-diffuser-boundary layer separation –wakes, drag force, coefficient of drag, skin friction, pressure, profile and total drag-stream lined body, bluff body-drag force on a rectangular plate-drag coefficient for flow around a cylinder-lift and drag force on an aerofoil-applications of aerofoil- characteristics-work done-aerofoil flow recorder-polar diagram-simple problems. Module 5 Flow of a real fluid-effect of viscosity on fluid flow-laminar and turbulent flow-boundary layer thickness-displacement, momentum and energy thickness-flow through pipes-laminar and turbulent flow in pipes-critical Reynolds number-Darcy-Weisback equation-hydraulic radius-Moody;s chart-pipes in series and parallel-siphon losses in pipes-power transmission through pipes-water hammer-equivalent pipe-open channel flow-Chezy’s equation-most economical cross section-hydraulic jump. ]]>
B.TECH. DEGREE COURSE SCHEME AND SYLLABUS (2002-03 admission onwards) MAHATMA GANDHI UNIVERSITY,mg university, KTU KOTTAYAM KERALA Module 1 Introduction - Proprties of fluids - pressure, force, density, specific weight, compressibility, capillarity, surface tension, dynamic and kinematic viscosity-Pascal’s law-Newtonian and non-Newtonian fluids-fluid statics-measurement of pressure-variation of pressure-manometry-hydrostatic pressure on plane and curved surfaces-centre of pressure-buoyancy-floation-stability of submerged and floating bodies-metacentric height-period of oscillation. Module 2 Kinematics of fluid motion-Eulerian and Lagrangian approach-classification and representation of fluid flow- path line, stream line and streak line. Basic hydrodynamics-equation for acceleration-continuity equation-rotational and irrotational flow-velocity potential and stream function-circulation and vorticity-vortex flow-energy variation across stream lines-basic field flow such as uniform flow, spiral flow, source, sink, doublet, vortex pair, flow past a cylinder with a circulation, Magnus effect-Joukowski theorem-coefficient of lift. Module 3 Euler’s momentum equation-Bernoulli’s equation and its limitations-momentum and energy correction factors-pressure variation across uniform conduit and uniform bend-pressure distribution in irrotational flow and in curved boundaries-flow through orifices and mouthpieces, notches and weirs-time of emptying a tank-application of Bernoulli’s theorem-orifice meter, ventury meter, pitot tube, rotameter. Module 4 Navier-Stoke’s equation-body force-Hagen-Poiseullie equation-boundary layer flow theory-velocity variation- methods of controlling-applications-diffuser-boundary layer separation –wakes, drag force, coefficient of drag, skin friction, pressure, profile and total drag-stream lined body, bluff body-drag force on a rectangular plate-drag coefficient for flow around a cylinder-lift and drag force on an aerofoil-applications of aerofoil- characteristics-work done-aerofoil flow recorder-polar diagram-simple problems. Module 5 Flow of a real fluid-effect of viscosity on fluid flow-laminar and turbulent flow-boundary layer thickness-displacement, momentum and energy thickness-flow through pipes-laminar and turbulent flow in pipes-critical Reynolds number-Darcy-Weisback equation-hydraulic radius-Moody;s chart-pipes in series and parallel-siphon losses in pipes-power transmission through pipes-water hammer-equivalent pipe-open channel flow-Chezy’s equation-most economical cross section-hydraulic jump. ]]> Wed, 16 May 2018 08:35:12 GMT /slideshow/fluid-mechanics-notes-97266357/97266357 shonejohn1@slideshare.net(shonejohn1) Fluid mechanics notes shonejohn1 B.TECH. DEGREE COURSE SCHEME AND SYLLABUS (2002-03 admission onwards) MAHATMA GANDHI UNIVERSITY,mg university, KTU KOTTAYAM KERALA Module 1 Introduction - Proprties of fluids - pressure, force, density, specific weight, compressibility, capillarity, surface tension, dynamic and kinematic viscosity-Pascal’s law-Newtonian and non-Newtonian fluids-fluid statics-measurement of pressure-variation of pressure-manometry-hydrostatic pressure on plane and curved surfaces-centre of pressure-buoyancy-floation-stability of submerged and floating bodies-metacentric height-period of oscillation. Module 2 Kinematics of fluid motion-Eulerian and Lagrangian approach-classification and representation of fluid flow- path line, stream line and streak line. Basic hydrodynamics-equation for acceleration-continuity equation-rotational and irrotational flow-velocity potential and stream function-circulation and vorticity-vortex flow-energy variation across stream lines-basic field flow such as uniform flow, spiral flow, source, sink, doublet, vortex pair, flow past a cylinder with a circulation, Magnus effect-Joukowski theorem-coefficient of lift. Module 3 Euler’s momentum equation-Bernoulli’s equation and its limitations-momentum and energy correction factors-pressure variation across uniform conduit and uniform bend-pressure distribution in irrotational flow and in curved boundaries-flow through orifices and mouthpieces, notches and weirs-time of emptying a tank-application of Bernoulli’s theorem-orifice meter, ventury meter, pitot tube, rotameter. Module 4 Navier-Stoke’s equation-body force-Hagen-Poiseullie equation-boundary layer flow theory-velocity variation- methods of controlling-applications-diffuser-boundary layer separation –wakes, drag force, coefficient of drag, skin friction, pressure, profile and total drag-stream lined body, bluff body-drag force on a rectangular plate-drag coefficient for flow around a cylinder-lift and drag force on an aerofoil-applications of aerofoil- characteristics-work done-aerofoil flow recorder-polar diagram-simple problems. Module 5 Flow of a real fluid-effect of viscosity on fluid flow-laminar and turbulent flow-boundary layer thickness-displacement, momentum and energy thickness-flow through pipes-laminar and turbulent flow in pipes-critical Reynolds number-Darcy-Weisback equation-hydraulic radius-Moody;s chart-pipes in series and parallel-siphon losses in pipes-power transmission through pipes-water hammer-equivalent pipe-open channel flow-Chezy’s equation-most economical cross section-hydraulic jump. <img style="border:1px solid #C3E6D8;float:right;" alt="" src="https://cdn.slidesharecdn.com/ss_thumbnails/fluidmechanics-180516083512-thumbnail.jpg?width=120&height=120&fit=bounds" /> B.TECH. DEGREE COURSE SCHEME AND SYLLABUS (2002-03 admission onwards) MAHATMA GANDHI UNIVERSITY,mg university, KTU KOTTAYAM KERALA Module 1 Introduction - Proprties of fluids - pressure, force, density, specific weight, compressibility, capillarity, surface tension, dynamic and kinematic viscosity-Pascal’s law-Newtonian and non-Newtonian fluids-fluid statics-measurement of pressure-variation of pressure-manometry-hydrostatic pressure on plane and curved surfaces-centre of pressure-buoyancy-floation-stability of submerged and floating bodies-metacentric height-period of oscillation. Module 2 Kinematics of fluid motion-Eulerian and Lagrangian approach-classification and representation of fluid flow- path line, stream line and streak line. Basic hydrodynamics-equation for acceleration-continuity equation-rotational and irrotational flow-velocity potential and stream function-circulation and vorticity-vortex flow-energy variation across stream lines-basic field flow such as uniform flow, spiral flow, source, sink, doublet, vortex pair, flow past a cylinder with a circulation, Magnus effect-Joukowski theorem-coefficient of lift. Module 3 Euler’s momentum equation-Bernoulli’s equation and its limitations-momentum and energy correction factors-pressure variation across uniform conduit and uniform bend-pressure distribution in irrotational flow and in curved boundaries-flow through orifices and mouthpieces, notches and weirs-time of emptying a tank-application of Bernoulli’s theorem-orifice meter, ventury meter, pitot tube, rotameter. Module 4 Navier-Stoke’s equation-body force-Hagen-Poiseullie equation-boundary layer flow theory-velocity variation- methods of controlling-applications-diffuser-boundary layer separation –wakes, drag force, coefficient of drag, skin friction, pressure, profile and total drag-stream lined body, bluff body-drag force on a rectangular plate-drag coefficient for flow around a cylinder-lift and drag force on an aerofoil-applications of aerofoil- characteristics-work done-aerofoil flow recorder-polar diagram-simple problems. Module 5 Flow of a real fluid-effect of viscosity on fluid flow-laminar and turbulent flow-boundary layer thickness-displacement, momentum and energy thickness-flow through pipes-laminar and turbulent flow in pipes-critical Reynolds number-Darcy-Weisback equation-hydraulic radius-Moody;s chart-pipes in series and parallel-siphon losses in pipes-power transmission through pipes-water hammer-equivalent pipe-open channel flow-Chezy’s equation-most economical cross section-hydraulic jump.

Fluid mechanics notes from shone john

]]> 3644 6 https://cdn.slidesharecdn.com/ss_thumbnails/fluidmechanics-180516083512-thumbnail.jpg?width=120&height=120&fit=bounds document Black http://activitystrea.ms/schema/1.0/post

http://activitystrea.ms/schema/1.0/posted

0 Cryogenics notes /slideshow/cryogenics-notes/97265905 cryogenicsnotes-180516082945
Mg university, KTU univeraity Btech Module 1 (8 hours) Introduction: Historical development- application of cryogenics -present areas involving cryogenic engineering-cryogenics in space technology- cryogenics in biology and medicinesuperconductivity applications. Module 2 (12 hours) Basic thermodynamics applied to liquefaction and refrigeration process – isothermal, adiabatic and Joule Thomson expansion process -efficiency to liquefaction and coefficient of performances- irreversibility and losses. Low temperature properties of engineering materials: mechanical properties – thermal properties -electrical and magnetic properties. Properties of cryogenic fluids- superconductivity and super fluidity - materials of constructions for cryogenic applications. Module 3 (15 hours) Gas liquefaction systems: Production of low temperatures – general liquefaction systemsliquefaction systems for neon, hydrogen and helium. Module 4 (15hours) Cryogenic refrigeration systems: ideal refrigeration systems- refrigerators using liquids and gases as refrigerants- refrigerators using solids as working media - adiabatic demagnetization method. Module 5 (10 hours) Cryogenic storage and transfer systems: Cryogenic fluid storage vessels- cryogenic fluid transfer systems-cryo pumping. Teaching scheme Credits: 4 3 hours lecture and 1 hour tutorial per week Text Books 1. Barron R., Cryogenic Systems, Oxford Science Publications 2. Scott R.B., Cryogenic Engineering, Van Nostrand Co. Reference Books 1. Mamata Mukhopadyay., Fundamentals of Cryogenic Engineering, PHI Learning 2. Haseldon G.G., Cryogenic Fundamentals, Academic Press 3. Flynn T.M., Cryogenic Engineering, Marcel Dekker. ]]>
Mg university, KTU univeraity Btech Module 1 (8 hours) Introduction: Historical development- application of cryogenics -present areas involving cryogenic engineering-cryogenics in space technology- cryogenics in biology and medicinesuperconductivity applications. Module 2 (12 hours) Basic thermodynamics applied to liquefaction and refrigeration process – isothermal, adiabatic and Joule Thomson expansion process -efficiency to liquefaction and coefficient of performances- irreversibility and losses. Low temperature properties of engineering materials: mechanical properties – thermal properties -electrical and magnetic properties. Properties of cryogenic fluids- superconductivity and super fluidity - materials of constructions for cryogenic applications. Module 3 (15 hours) Gas liquefaction systems: Production of low temperatures – general liquefaction systemsliquefaction systems for neon, hydrogen and helium. Module 4 (15hours) Cryogenic refrigeration systems: ideal refrigeration systems- refrigerators using liquids and gases as refrigerants- refrigerators using solids as working media - adiabatic demagnetization method. Module 5 (10 hours) Cryogenic storage and transfer systems: Cryogenic fluid storage vessels- cryogenic fluid transfer systems-cryo pumping. Teaching scheme Credits: 4 3 hours lecture and 1 hour tutorial per week Text Books 1. Barron R., Cryogenic Systems, Oxford Science Publications 2. Scott R.B., Cryogenic Engineering, Van Nostrand Co. Reference Books 1. Mamata Mukhopadyay., Fundamentals of Cryogenic Engineering, PHI Learning 2. Haseldon G.G., Cryogenic Fundamentals, Academic Press 3. Flynn T.M., Cryogenic Engineering, Marcel Dekker. ]]> Wed, 16 May 2018 08:29:45 GMT /slideshow/cryogenics-notes/97265905 shonejohn1@slideshare.net(shonejohn1) Cryogenics notes shonejohn1 Mg university, KTU univeraity Btech Module 1 (8 hours) Introduction: Historical development- application of cryogenics -present areas involving cryogenic engineering-cryogenics in space technology- cryogenics in biology and medicine�superconductivity applications. Module 2 (12 hours) Basic thermodynamics applied to liquefaction and refrigeration process – isothermal, adiabatic and Joule Thomson expansion process -efficiency to liquefaction and coefficient of performances- irreversibility and losses. Low temperature properties of engineering materials: mechanical properties – thermal properties -electrical and magnetic properties. Properties of cryogenic fluids- superconductivity and super fluidity - materials of constructions for cryogenic applications. Module 3 (15 hours) Gas liquefaction systems: Production of low temperatures – general liquefaction systems�liquefaction systems for neon, hydrogen and helium. Module 4 (15hours) Cryogenic refrigeration systems: ideal refrigeration systems- refrigerators using liquids and gases as refrigerants- refrigerators using solids as working media - adiabatic demagnetization method. Module 5 (10 hours) Cryogenic storage and transfer systems: Cryogenic fluid storage vessels- cryogenic fluid transfer systems-cryo pumping. Teaching scheme Credits: 4 3 hours lecture and 1 hour tutorial per week Text Books 1. Barron R., Cryogenic Systems, Oxford Science Publications 2. Scott R.B., Cryogenic Engineering, Van Nostrand Co. Reference Books 1. Mamata Mukhopadyay., Fundamentals of Cryogenic Engineering, PHI Learning 2. Haseldon G.G., Cryogenic Fundamentals, Academic Press 3. Flynn T.M., Cryogenic Engineering, Marcel Dekker. <img style="border:1px solid #C3E6D8;float:right;" alt="" src="https://cdn.slidesharecdn.com/ss_thumbnails/cryogenicsnotes-180516082945-thumbnail.jpg?width=120&height=120&fit=bounds" /> Mg university, KTU univeraity Btech Module 1 (8 hours) Introduction: Historical development- application of cryogenics -present areas involving cryogenic engineering-cryogenics in space technology- cryogenics in biology and medicine�superconductivity applications. Module 2 (12 hours) Basic thermodynamics applied to liquefaction and refrigeration process – isothermal, adiabatic and Joule Thomson expansion process -efficiency to liquefaction and coefficient of performances- irreversibility and losses. Low temperature properties of engineering materials: mechanical properties – thermal properties -electrical and magnetic properties. Properties of cryogenic fluids- superconductivity and super fluidity - materials of constructions for cryogenic applications. Module 3 (15 hours) Gas liquefaction systems: Production of low temperatures – general liquefaction systems�liquefaction systems for neon, hydrogen and helium. Module 4 (15hours) Cryogenic refrigeration systems: ideal refrigeration systems- refrigerators using liquids and gases as refrigerants- refrigerators using solids as working media - adiabatic demagnetization method. Module 5 (10 hours) Cryogenic storage and transfer systems: Cryogenic fluid storage vessels- cryogenic fluid transfer systems-cryo pumping. Teaching scheme Credits: 4 3 hours lecture and 1 hour tutorial per week Text Books 1. Barron R., Cryogenic Systems, Oxford Science Publications 2. Scott R.B., Cryogenic Engineering, Van Nostrand Co. Reference Books 1. Mamata Mukhopadyay., Fundamentals of Cryogenic Engineering, PHI Learning 2. Haseldon G.G., Cryogenic Fundamentals, Academic Press 3. Flynn T.M., Cryogenic Engineering, Marcel Dekker.

Cryogenics notes from shone john

]]> 6424 3 https://cdn.slidesharecdn.com/ss_thumbnails/cryogenicsnotes-180516082945-thumbnail.jpg?width=120&height=120&fit=bounds document Black http://activitystrea.ms/schema/1.0/post

http://activitystrea.ms/schema/1.0/posted

0 https://public.slidesharecdn.com/v2/images/profile-picture.png *self motivated mechanical engineer with multidisciplinary views who believes in the engineering world beyond the syllabus *an exploring minded person ,who continuously learns and updates what an industry /company need from an engineer. https://cdn.slidesharecdn.com/ss_thumbnails/futureresume4-180830163112-thumbnail.jpg?width=320&height=320&fit=bounds slideshow/shone-john-resume-112276990/112276990 shone john resume https://cdn.slidesharecdn.com/ss_thumbnails/futureresume-180616105517-thumbnail.jpg?width=320&height=320&fit=bounds slideshow/shone-john-resume-102530818/102530818 shone john resume https://cdn.slidesharecdn.com/ss_thumbnails/downloadfile-180527193822-thumbnail.jpg?width=320&height=320&fit=bounds slideshow/internship-industrial-training-report/99079636 INTERNSHIP/ INDUSTRIAL...