Defining a Standard Metric for Electricity Savings

Jonathan Koomey; Hashem Akbari; Carl Blumstein; Marilyn Brown; Richard Brown; Robert Budnitz; Chris Calwell; Sheryl Carter; Ralph Cavanagh; Audrey Chang; David Claridge; Paul Craig; Rick Diamond; Joseph H. Eto; William J. Fisk; William Fulkerson; Ashok Gadgil; Howard Geller; José Goldemberg; Chuck Goldman; David B. Goldstein; Steve Greenberg; David Hafemeister; Jeff Harris; Hal Harvey; Eric Heitz; Eric Hirst; Holmes Hummel; Dan Kammen; Henry Kelly; Skip Laitner; Mark Levine; Amory Lovins; Gil Masters; Pat McAuliffe; James E. McMahon; Alan Meier; Michael Messenger; John Millhone; Evan Mills; Steve Nadel; Bruce Nordman; Lynn Price; Joe Romm; Marc Ross; Michael Rufo; Jayant Sathaye; Lee Schipper; Stephen H. Schneider; Robert H. Socolow; James L. Sweeney; Malcolm Verdict; Alexandra von Meier; Diana Vorsatz; Devra Wang; Carl Weinberg; Richard Wilk; John Wilson; Jane Woodward; Ernst Worrell

doi:10.1063/1.3653843

Defining a Standard Metric for Electricity Savings

Jonathan Koomey
, Hashem Akbari
, Carl Blumstein
, Marilyn Brown
, Richard Brown
, Robert Budnitz
, Chris Calwell
, Sheryl Carter
, Ralph Cavanagh
, Audrey Chang
, David Claridge
, Paul Craig
, Rick Diamond
, Joseph H. Eto
, William J. Fisk
, William Fulkerson
, Ashok Gadgil
, Howard Geller
, José Goldemberg
, Chuck Goldman

David B. Goldstein, Steve Greenberg, David Hafemeister, Jeff Harris, Hal Harvey, Eric Heitz, Eric Hirst, Holmes Hummel, Dan Kammen, Henry Kelly, Skip Laitner, Mark Levine, Amory Lovins, Gil Masters, Pat McAuliffe, James E. McMahon, Alan Meier, Michael Messenger, John Millhone, Evan Mills, Steve Nadel, Bruce Nordman, Lynn Price, Joe Romm, Marc Ross, Michael Rufo, Jayant Sathaye, Lee Schipper, Stephen H. Schneider, Robert H. Socolow, James L. Sweeney, Malcolm Verdict, Alexandra von Meier, Diana Vorsatz, Devra Wang, Carl Weinberg, Richard Wilk, John Wilson, Jane Woodward, Ernst Worrell

Stanford University

Research output: Contribution to journal › Article › Academic › peer-review

Abstract

The growing investment by governments and electric utilities in energy efficiency programs highlights the need for simple tools to help assess and explain the size of the potential resource. One technique that is commonly used in that effort is to characterize electricity savings in terms of avoided power plants, because it is easier for people to visualize a power plant than it is to understand an abstraction like billions of kilowatt-hours. Unfortunately, there is no standardization around the characteristics of such power plants. In this article we define parameters for a standard avoided power plant that have physical meaning and intuitive plausibility, for use in back-of-the-envelope calculations. For the prototypical plant this article settles on a 500-megawatt existing coal plant operating at a 70% capacity factor with 7% T&D losses. Displacing such a plant for one year would save 3 billion kWh/year at the meter and reduce emissions by 3 million metric tons of CO2 per year. The proposed name for this metric is the Rosenfeld, in keeping with the tradition among scientists of naming units in honor of the person most responsible for the discovery and widespread adoption of the underlying scientific principle in question—Dr. Arthur H. Rosenfeld.

Original language	English
Pages (from-to)	26-43
Journal	AIP Conference Proceedings
Volume	1401
Issue number	1
DOIs	https://doi.org/10.1063/1.3653843
Publication status	Published - 1 Nov 2011

Bibliographical note

PHYSICS OF SUSTAINABLE ENERGY II: USING ENERGY EFFICIENTLY AND PRODUCING IT RENEWABLY. ISBN: 978-0-7354-0972-9

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

SDG 7 Affordable and Clean Energy

Keywords

standardization
energy conservation
economics
regulation
air pollution
Air quality and air pollution

Access to Document

10.1063/1.3653843

http://adsabs.harvard.edu/abs/2011AIPC.1401...26K

Cite this

Koomey, J., Akbari, H., Blumstein, C., Brown, M., Brown, R., Budnitz, R., Calwell, C., Carter, S., Cavanagh, R., Chang, A., Claridge, D., Craig, P., Diamond, R., Eto, J. H., Fisk, W. J., Fulkerson, W., Gadgil, A., Geller, H., Goldemberg, J., ... Worrell, E. (2011). Defining a Standard Metric for Electricity Savings. AIP Conference Proceedings, 1401(1), 26-43. https://doi.org/10.1063/1.3653843

@article{9870c1018f384223871b37b1095623fd,

title = "Defining a Standard Metric for Electricity Savings",

abstract = "The growing investment by governments and electric utilities in energy efficiency programs highlights the need for simple tools to help assess and explain the size of the potential resource. One technique that is commonly used in that effort is to characterize electricity savings in terms of avoided power plants, because it is easier for people to visualize a power plant than it is to understand an abstraction like billions of kilowatt-hours. Unfortunately, there is no standardization around the characteristics of such power plants. In this article we define parameters for a standard avoided power plant that have physical meaning and intuitive plausibility, for use in back-of-the-envelope calculations. For the prototypical plant this article settles on a 500-megawatt existing coal plant operating at a 70\% capacity factor with 7\% T\&D losses. Displacing such a plant for one year would save 3 billion kWh/year at the meter and reduce emissions by 3 million metric tons of CO2 per year. The proposed name for this metric is the Rosenfeld, in keeping with the tradition among scientists of naming units in honor of the person most responsible for the discovery and widespread adoption of the underlying scientific principle in question—Dr. Arthur H. Rosenfeld.",

keywords = "standardization, energy conservation, economics, regulation, air pollution, Air quality and air pollution",

author = "Jonathan Koomey and Hashem Akbari and Carl Blumstein and Marilyn Brown and Richard Brown and Robert Budnitz and Chris Calwell and Sheryl Carter and Ralph Cavanagh and Audrey Chang and David Claridge and Paul Craig and Rick Diamond and Eto, \{Joseph H.\} and Fisk, \{William J.\} and William Fulkerson and Ashok Gadgil and Howard Geller and Jos{\'e} Goldemberg and Chuck Goldman and Goldstein, \{David B.\} and Steve Greenberg and David Hafemeister and Jeff Harris and Hal Harvey and Eric Heitz and Eric Hirst and Holmes Hummel and Dan Kammen and Henry Kelly and Skip Laitner and Mark Levine and Amory Lovins and Gil Masters and Pat McAuliffe and McMahon, \{James E.\} and Alan Meier and Michael Messenger and John Millhone and Evan Mills and Steve Nadel and Bruce Nordman and Lynn Price and Joe Romm and Marc Ross and Michael Rufo and Jayant Sathaye and Lee Schipper and Schneider, \{Stephen H.\} and Socolow, \{Robert H.\} and Sweeney, \{James L.\} and Malcolm Verdict and \{von Meier\}, Alexandra and Diana Vorsatz and Devra Wang and Carl Weinberg and Richard Wilk and John Wilson and Jane Woodward and Ernst Worrell",

note = "PHYSICS OF SUSTAINABLE ENERGY II: USING ENERGY EFFICIENTLY AND PRODUCING IT RENEWABLY. ISBN: 978-0-7354-0972-9 ",

year = "2011",

month = nov,

day = "1",

doi = "10.1063/1.3653843",

language = "English",

volume = "1401",

pages = "26--43",

journal = "AIP Conference Proceedings",

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Koomey, J, Akbari, H, Blumstein, C, Brown, M, Brown, R, Budnitz, R, Calwell, C, Carter, S, Cavanagh, R, Chang, A, Claridge, D, Craig, P, Diamond, R, Eto, JH, Fisk, WJ, Fulkerson, W, Gadgil, A, Geller, H, Goldemberg, J, Goldman, C, Goldstein, DB, Greenberg, S, Hafemeister, D, Harris, J, Harvey, H, Heitz, E, Hirst, E, Hummel, H, Kammen, D, Kelly, H, Laitner, S, Levine, M, Lovins, A, Masters, G, McAuliffe, P, McMahon, JE, Meier, A, Messenger, M, Millhone, J, Mills, E, Nadel, S, Nordman, B, Price, L, Romm, J, Ross, M, Rufo, M, Sathaye, J, Schipper, L, Schneider, SH, Socolow, RH, Sweeney, JL, Verdict, M, von Meier, A, Vorsatz, D, Wang, D, Weinberg, C, Wilk, R, Wilson, J, Woodward, J & Worrell, E 2011, 'Defining a Standard Metric for Electricity Savings', AIP Conference Proceedings, vol. 1401, no. 1, pp. 26-43. https://doi.org/10.1063/1.3653843

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AU - Koomey, Jonathan

AU - Akbari, Hashem

AU - Blumstein, Carl

AU - Brown, Marilyn

AU - Brown, Richard

AU - Budnitz, Robert

AU - Calwell, Chris

AU - Carter, Sheryl

AU - Cavanagh, Ralph

AU - Chang, Audrey

AU - Claridge, David

AU - Craig, Paul

AU - Diamond, Rick

AU - Eto, Joseph H.

AU - Fisk, William J.

AU - Fulkerson, William

AU - Gadgil, Ashok

AU - Geller, Howard

AU - Goldemberg, José

AU - Goldman, Chuck

AU - Goldstein, David B.

AU - Greenberg, Steve

AU - Hafemeister, David

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AU - Harvey, Hal

AU - Heitz, Eric

AU - Hirst, Eric

AU - Hummel, Holmes

AU - Kammen, Dan

AU - Kelly, Henry

AU - Laitner, Skip

AU - Levine, Mark

AU - Lovins, Amory

AU - Masters, Gil

AU - McAuliffe, Pat

AU - McMahon, James E.

AU - Meier, Alan

AU - Messenger, Michael

AU - Millhone, John

AU - Mills, Evan

AU - Nadel, Steve

AU - Nordman, Bruce

AU - Price, Lynn

AU - Romm, Joe

AU - Ross, Marc

AU - Rufo, Michael

AU - Sathaye, Jayant

AU - Schipper, Lee

AU - Schneider, Stephen H.

AU - Socolow, Robert H.

AU - Sweeney, James L.

AU - Verdict, Malcolm

AU - von Meier, Alexandra

AU - Vorsatz, Diana

AU - Wang, Devra

AU - Weinberg, Carl

AU - Wilk, Richard

AU - Wilson, John

AU - Woodward, Jane

AU - Worrell, Ernst

N1 - PHYSICS OF SUSTAINABLE ENERGY II: USING ENERGY EFFICIENTLY AND PRODUCING IT RENEWABLY. ISBN: 978-0-7354-0972-9

PY - 2011/11/1

Y1 - 2011/11/1

N2 - The growing investment by governments and electric utilities in energy efficiency programs highlights the need for simple tools to help assess and explain the size of the potential resource. One technique that is commonly used in that effort is to characterize electricity savings in terms of avoided power plants, because it is easier for people to visualize a power plant than it is to understand an abstraction like billions of kilowatt-hours. Unfortunately, there is no standardization around the characteristics of such power plants. In this article we define parameters for a standard avoided power plant that have physical meaning and intuitive plausibility, for use in back-of-the-envelope calculations. For the prototypical plant this article settles on a 500-megawatt existing coal plant operating at a 70% capacity factor with 7% T&D losses. Displacing such a plant for one year would save 3 billion kWh/year at the meter and reduce emissions by 3 million metric tons of CO2 per year. The proposed name for this metric is the Rosenfeld, in keeping with the tradition among scientists of naming units in honor of the person most responsible for the discovery and widespread adoption of the underlying scientific principle in question—Dr. Arthur H. Rosenfeld.

AB - The growing investment by governments and electric utilities in energy efficiency programs highlights the need for simple tools to help assess and explain the size of the potential resource. One technique that is commonly used in that effort is to characterize electricity savings in terms of avoided power plants, because it is easier for people to visualize a power plant than it is to understand an abstraction like billions of kilowatt-hours. Unfortunately, there is no standardization around the characteristics of such power plants. In this article we define parameters for a standard avoided power plant that have physical meaning and intuitive plausibility, for use in back-of-the-envelope calculations. For the prototypical plant this article settles on a 500-megawatt existing coal plant operating at a 70% capacity factor with 7% T&D losses. Displacing such a plant for one year would save 3 billion kWh/year at the meter and reduce emissions by 3 million metric tons of CO2 per year. The proposed name for this metric is the Rosenfeld, in keeping with the tradition among scientists of naming units in honor of the person most responsible for the discovery and widespread adoption of the underlying scientific principle in question—Dr. Arthur H. Rosenfeld.

KW - standardization

KW - energy conservation

KW - economics

KW - regulation

KW - air pollution

KW - Air quality and air pollution

U2 - 10.1063/1.3653843

DO - 10.1063/1.3653843

M3 - Article

SN - 0094-243X

VL - 1401

SP - 26

EP - 43

JO - AIP Conference Proceedings

JF - AIP Conference Proceedings

IS - 1

ER -

Defining a Standard Metric for Electricity Savings

Abstract

Bibliographical note

UN SDGs

Keywords

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