environmental decisions. efficiency of common heat engines
TRANSCRIPT
Environmental Decisions
Efficiency of common heat engines
U.S. Emits Nearly Half World's Automotive Carbon Dioxide
WASHINGTON, DC, June 28, 2006 (ENS) - The United States has five percent of the world's population and 30 percent of the world's automobiles, but
the country contributes 45 percent of the world's automotive emissions of the greenhouse gas carbon dioxide, according to a report released today by the advocacy group Environmental Defense.
Kilogram-force
Weight is usually expressed in kilogram-force or pound-force.
1 kg-force = force of gravity on 1 kg of mass. 1 lb-force = force of gravity on 1 lb of mass.
These are not SI units but they have the advantage that the magnitude of the weight is identical to the magnitude of the mass.
1 kg-force = 9.8 NewtonsWhen you say I weight 200 lbs you are indirectly saying: I
have a mass of 200 lbs and the force of gravity on me is 890 N.
In the next examples all weights are expressed either in in lb-force or in kg-force and in order to calculate rolling resistance they will need to be converted to Newtons
Force to move a car at a certain speed
speedv
densityairrho
areafrontalA
tcoefficiendragC
gravityofonacceleratig
massM
ceresisrollingoftcoefficienC
forceF
vrhoACgMCF
d
rr
drr
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Energy in Gasoline
1 Gal Gasoline = 132,000,000 J
One passenger 60 mph
lbs kg 1 Gal GasolineM 2,500.00 984.25 132,000,000.00 JCar 2,300.00 Useful 15%Occupants 200.00 19,800,000
Asphalt F= 561.55Crr 0.03 W = Fd = 21,684,922.58
m/(s^2) Gals 1.10g 9.80
ft^2 m^2CdA 6.79 0.63
rho kg/m^31.20
milesph kmph mpsv 60.00 96.54 26.82
miles km md 24.00 38.62 38,616.00
This is what you spend when you break1/2Mv^2 353,904.34
speedv
densityairrho
areafrontalA
tcoefficiendragC
gravityofonacceleratig
massM
ceresisrollingoftcoefficienC
forceF
vrhoACgMCF
d
rr
drr
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tan:
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Car weight reduced 10 times
lbs kg 1 Gal GasolineM 430.00 169.29 132,000,000.00 JCar 230.00 Useful 15%Occupants 200.00 19,800,000
Asphalt F= 321.95Crr 0.03 W = Fd = 12,432,589.79
m/(s^2)g 9.80
ft^2 m^2CdA 6.79 0.63
rho kg/m^31.20
milesph kmph mpsv 60.00 96.54 26.82
miles km md 24.00 38.62 38,616.00
This is what you spend when you break1/2Mv^2 60,871.55
speedv
densityairrho
areafrontalA
tcoefficiendragC
gravityofonacceleratig
massM
ceresisrollingoftcoefficienC
forceF
vrhoACgMCF
d
rr
drr
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tan:
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2
1 2
Speed Reduced to 40 mph
lbs kg 1 Gal GasolineM 2,500.00 984.25 132,000,000.00 JCar 2,300.00 Useful 15%Occupants 200.00 19,800,000
Asphalt F= 410.34Crr 0.03 W = Fd = 15,845,696.12
m/(s^2)g 9.80
ft^2 m^2CdA 6.79 0.63
rho kg/m^31.20
milesph kmph mpsv 40.00 64.36 17.88
miles km md 24.00 38.62 38,616.00
This is what you spend when you break1/2Mv^2 157,290.82
speedv
densityairrho
areafrontalA
tcoefficiendragC
gravityofonacceleratig
massM
ceresisrollingoftcoefficienC
forceF
vrhoACgMCF
d
rr
drr
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:
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tan:
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2
1 2
Carpool (4 passengers)
lbs kg 1 Gal GasolineM 3,100.00 1,220.47 132,000,000.00 JCar 2,300.00 Useful 15%Occupants 800.00 19,800,000
Asphalt F= 631.00Crr 0.03 W = Fd = 24,366,758.17
m/(s^2) Gals 1.23g 9.80 Compare to 4.40
ft^2 m^2CdA 6.79 0.63
rho kg/m^31.20
milesph kmph mpsv 60.00 96.54 26.82
miles km md 24.00 38.62 38,616.00
This is what you spend when you break1/2Mv^2 438,841.38
speedv
densityairrho
areafrontalA
tcoefficiendragC
gravityofonacceleratig
massM
ceresisrollingoftcoefficienC
forceF
vrhoACgMCF
d
rr
drr
:
:
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tan:
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2
1 2
Toyota Priushttp://privatenrg.com/
Temperature: 87º F Elevation: 400’ feet above sea level Humidity: 67% Barometer: 30.03 in/hg Load: 350 lbs (driver & gear) Auto AC: OFF Climate Control: 72º F Wind: NONE Wind Dir: 235º (tail wind/crosswind – slightly detrimental) Fuel: 114,500 BTU (avg Summer Blend) -- see: http://www.epa.gov/otaq/rfgecon.htm kWh: 33.5568 kWh (energy available per gallon/US) RRR: .001144 Road Rolling Resistance (smooth asphalt roads) TRR: .007 Tire Rolling Resistance Cd: .26 Aerodynamic Coefficient of Drag FA: 2.16m^2 Frontal Area in meters squared cwCd: 1.4e-5 (crosswind correction for Cd) cwFA: 8.5e-5 (crosswind correction for FA)
Toyota Prius city/highway/combined 51/48/50
lbs kg 1 Gal GasolineM 2,500.00 984.25 132,000,000.00 JCar 2,300.00 Useful 15%Occupants 200.00 19,800,000
Asphalt F= 253.35Crr 0.0011440 W = Fd = 19,567,028.97
m/(s^2) Gals 0.99g 9.80 Compare to 1.10
ft^2 m^2CdA 0.56
rho kg/m^31.20
milesph kmph mpsv 60.00 96.54 26.82
miles km md 48.00 77.23 77,232.00
This is what you spend when you break1/2Mv^2 353,904.34
speedv
densityairrho
areafrontalA
tcoefficiendragC
gravityofonacceleratig
massM
ceresisrollingoftcoefficienC
forceF
vrhoACgMCF
d
rr
drr
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tan:
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2
1 2
Toyota Prius Ideal v =0
lbs kg 1 Gal GasolineM 2,500.00 984.25 132,000,000.00 JCar 2,300.00 Useful 15%Occupants 200.00 19,800,000
Asphalt F= 11.03Crr 0.0011440 W = Fd = 19,796,541
m/(s^2) Gals 1.00g 9.80 Compare to 1.10
ft^2 m^2CdA 0.56
rho kg/m^31.20
milesph kmph mpsv 0.00 0.00 0.00
miles km md 1,115.00 1,794.04 1,794,035.00
This is what you spend when you break1/2Mv^2 0.00
speedv
densityairrho
areafrontalA
tcoefficiendragC
gravityofonacceleratig
massM
ceresisrollingoftcoefficienC
forceF
vrhoACgMCF
d
rr
drr
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tan:
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1 2
How MPG is calculated?
CdA ft² Automobile model2.31 (around 1.46 m² × 0.15) 2008 Aptera Typ-12.5 1986 Twike [3]3.95 1996 GM EV15.1 1999 Honda Insight5.4 1989 Opel Calibra5.71 1990 Honda CR-X Si5.74 2002 Acura NSX5.76 1968 Toyota 2000GT5.8 1986 Toyota MR25.81 1989 Mitsubishi Eclipse GSX5.88 1990 Nissan 240SX hatchback / 200SX / 180SX5.92 1994 Porsche 911 Speedster5.95 1990 Mazda RX76 1970 Lamborghini Miura6.08 2008 Nissan GTR6.13 1991 Acura NSX6.17 1995 Lamborghini Diablo6.24 2004 Toyota Prius6.27 1986 Porsche 911 Carrera
Prius
Aptera
Insight
CdA ft² Automobile model7.57 1992 Toyota Camry7.69 1994 Chrysler LHS7.72 1993 Subaru Impreza8.02 2005 Bugatti Veyron8.7 1990 Volvo 740 Turbo8.7 1992 Ford Crown Victoria8.71 1991 Buick LeSabre Limited9.54 1992 Chevrolet Caprice Wagon10.7 1992 Chevrolet Blazer11.6 2005 Ford Escape Hybrid11.7 1993 Jeep Grand Cherokee16.8 2006 Hummer H317.4 1995 Land Rover Discovery26.5 2003 Hummer H2
Hummer H2
Escape
Are this images familiar to you?
Hard to improve old technologies
1807: Swiss engineer François Isaac de Rivaz built an internal combustion engine powered by a hydrogen and oxygen mixture. [3]
1824: French physicist Sadi Carnot established the thermodynamic theory of idealized heat engines. This scientifically established the need for compression to increase the difference between the upper and lower working temperatures.
http://en.wikipedia.org/wiki/History_of_the_internal_combustion_engine
Hard to improve old technologies
1838: a patent was granted to William Barnet (English). This was the first recorded suggestion of in-cylinder compression.
1854-57: Eugenio Barsanti & Felice Matteucci invented an engine that was rumored to be the first 4-cycle engine, but the patent was lost.
http://en.wikipedia.org/wiki/History_of_the_internal_combustion_engine
It does not mean “do not use old technologies”, it means use the better ones
What to do?
InnovateFollow good examples
http://www.world-nuclear.org/info/inf40.html
France derives over 75% of its electricity from nuclear energy. This is due to a long-standing policy based on energy
security.
France is the world's largest net exporter of electricityDue to its very low cost of generation, and gains over
EUR 3 billion per year from this.
http://www.world-nuclear.org/info/inf40.html
France has been very active in developing nuclear technology.Reactors and fuel products and services are a major
export.
It is building its first Generation III reactor and planning a second.
http://energy.edf.com/edf-fr-accueil/edf-and-power-generation-122160.html
Powerful, safe and efficient, nuclear power forms the basis of EDF’s power generation business.
Not only does it make France independent in terms of energy supply, but also generates power without producing any greenhouse gas emissions.
In addition, its plants have a high capacity rate and electricity prices are amongst the most competitive in Europe.
The construction of a new EPR unit at Flamanville is part of the EDF Group’s industrial project.
http://energy.edf.com/edf-fr-accueil/edf-and-power-generation-122160.html
EDF, one of the European leaders in the energy field, operates the largest electricity generation capacity, 95% of which does not emit any greenhouse gases.
The competitiveness of EDF’s generation facilities is based on diversity, performance and safety of its means of generation.
http://energy.edf.com/edf-fr-accueil/edf-and-power-generation-
122160.html
EDF, the world’s leading nuclear power utility, operates a French nuclear fleet consisting of 58 reactors spread over 19 different sites
http://energy.edf.com/edf-fr-accueil/edf-and-power-generation-122160.html
Due to be commissioned in 2012, the EPR plant will constitute the first version of a new generation of reactors.
Preparing for the replacement of EDF’s nuclear power plants, as the oldest ones could be decommissioned in around 2020.
http://energy.edf.com/edf-fr-accueil/edf-and-power-generation-122160.html
Since 1996, the EDF Group has operated the first and only geothermal power plant in the world to generate electricity on a commercial basis. The power plant is located at Bouillante in Guadeloupe.
Being Green can be Cool
Renault Fluence EV to Cost Significantly Less Than Gasoline Version
http://www.allcarselectric.com/blog/1036429_renault-fluence-ev-to-cost-significantly-less-than-gasoline-version
Being Green can be Cool
They will start to appear in 2012
It appears appropriated to ask?And you?What’s in your wallet?
Humanity, Nature, and Technology: The Hannover Principles
The City of Hannover, Germany, was designated as the site of the world exposition in the year 2000.
The city decided to directly address the difficult issue of imagining and encouraging a sustainable future.
THE HANNOVER PRINCIPLES
1. Insist on rights of humanity and nature to co-exist in a healthy, supportive, diverse and sustainable condition.
2. Recognize interdependence. The elements of human design interact with and depend upon the natural world, with broad and diverse implications at every scale. Expand design considerations to recognizing even distant effects.
3. Respect relationships between spirit and matter. Consider all aspects of human settlement including community, dwelling, industry and trade in terms of existing and evolving connections between spiritual and material consciousness.
4. Accept responsibility for the consequences of design decisions upon human well-being, the viability of natural systems and their right to co-exist.
5. Create safe objects of long-term value. Do not burden future generations with requirements for maintenance or vigilant administration of potential danger due to the careless creation of products, processes or standards.
THE HANNOVER PRINCIPLES
6. Eliminate the concept of waste. Evaluate and optimize the full life-cycle of products and processes, to approach the state of natural systems. in which there is no waste.
7. Rely on natural energy flows. Human designs should, like the living world, derive their creative forces from perpetual solar income. Incorporate this energy efficiently and safely for responsible use.
8. Understand the limitations of design. No human creation lasts forever and design does not solve all problems. Those who create and plan should practice humility in the face of nature. Treat nature as a model and mentor, not as an inconvenience to be evaded or controlled.
9. Seek constant improvement by the sharing of knowledge. Encourage direct and open communication between colleagues, patrons, manufacturers and users to link long term sustainable considerations with ethical responsibility, and re-establish the integral relationship between natural processes and human activity.