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Short Range Transportation

Active Transportation

Active transportation, powered primarily by human muscles, can be of comparable energy intensity to vehicles used for transportation over equivalent distances.

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Following Canning et al. 1, we estimate 15 units of primary energy are required throughout the food system to produce one unit of food energy, much greater than the primary energy factor of about 3 for electricity. Energy consumption for various modes of active transportation are estimated from the USDA 2, and only the energy consumption in excess of rest energy is considered. These figures depend greatly on the diet and metabolic rate of the individual, and due to the very different nature of energy input, caution should be used in comparing them to the energy demand of other transportation modes.

Problem:
Need to Promote Active Transportation
Solution:
Manhattan Pedestrian Skybridge

Small Vehicles

Small vehicles can be highly efficient for traveling short distances.

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Data sources: Elektroroller Aktuell 3, Halvorson 4, IEA 5, McCarran and Carpenter 6, Salmeron-Manzano and Manzano-Agugliaro 7, Saxena et al. 8.

Problem:
Space and Energy of Driving
Solution:
Micro-Mobility Lanes

Short Range Transit

Following, we compare the energy intensities of several mass transit systems that are designed to operate over small distances.

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Data on aerial tramways, inclined planes and streetcars are taken from the National Transit Database 9 and represent the performance of a small number of systems in the United States. In particular, the aerial tramway figure is based on a single system in Portland, Oregon. The figures for autonomous shuttles are estimated from the Mcity pilot program at the University of Michigan 10.

Elevators and Escalators

Elevators are highly energy intensive per unit distance traveled, but vertical distances in buildings are usually much less than horizontal distances traveled between buildings.

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Energy consumption by elevators in buildings ranging from 3 to 13 stories, including standby energy while the elevators are waiting to be summoned 11, 12. We assume an average of one person in an elevator car when it is moving (there may be no people after the elevator is called and before it arrives at the pickup floor). Also shown are energy needs for climbing four stories round trip 13.

Hydraulic elevators are most suitable up to about six stories, geared traction from 3-25 stories, and gearless traction for buildings over 25 stories 12. Energy consumption varies widely by elevator type, efficiency standards, and pattern of use. However, for a typical midrise building, an elevator round trip generally requires less energy than driving a kilometer.

Relative to other modes of transportation, escalators require little energy per passenger.

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Data sources: Building Energy Codes Program 11, E3T 14, KONE 15.

Problem:
Traditional Elevator Limitations
Solution:
Maglev Elevators

References

  1. Canning, P., Charles, A., Huang, S., Polenske, K., Waters, A. "Energy Use in the U.S. Food System". United States Department of Agriculture, Economic Research Report Number 94. March 2010.

  2. ChooseMyPlate.gov. "How Many Calories Does Physical Activitiy Use (Burn)?". United States Department of Agriculture. Accessed May 24, 2019.

  3. Elektroroller Aktuell. "Electric scooter cost". Accessed May 24, 2019.

  4. Halvorson, B. "Toyota i-Road Electric City Car: Here's How It Leans". Green Car Reports. October 2014.

  5. International Energy Agency. "The Future of Rail". January 2019.

  6. McCarran, T., Carpenter, N. "Electric Bikes: Survey and Energy Efficiency Analysis". Efficiency Vermont, DSS Tech Demo Report: 000-053. March 2018.

  7. Salmeron-Manzano, E., Manzano-Agugliaro, F. "The Electric Bicycle: Worldwide Research Trends". Energies 11(7), 1894. 2018.

  8. Saxena, S., Gopal, A., Phadke, A. "Electrical consumption of two-, three- and four-wheel light-duty electric vehicles in India". Applied Energy 115, pp. 582-590. November 2013.

  9. Federal Transit Administration. "National Transit Database". Accessed May 24, 2019.

  10. Peng, H. "Mcity Driverless Shuttle: A Case Study". September 2018.

  11. Building Energy Codes Program. "Prototype Building Models High-rise Apartment". Building Technologies Office, Office of Energy Efficiency and Renewable Energy, U. S. Department of Energy. April 2011. 2

  12. Patrão, C., Fong, J., Rivet, L., de Almeida, A. "Energy efficient elevators and escalators". European Council for an Energy Efficient Economy. Summer 2009. 2

  13. Freedhoff, Y. "Climbing Stairs Isn't About Burning Calories". April 2015.

  14. Energy Efficiency Emerging Technology (E3T) Proram. "Energy Efficient Escalators". Washington State University, Bonneville Power Administration. Accessed November 6, 2019.

  15. KONE. "Planning Guide for KONE Escalators & Autowalks". 2016.