DOCSLIB.ORG

Hector's Posts – Volume 5, 1St Edition Editor's Note Messages

Total Page:16

File Type:pdf, Size:1020Kb

Download full-text PDF Read full-text
Hector's Posts – Volume 5, 1St Edition Editor's Note Messages Hector's Posts – Volume 5, 1st Edition Editor's Note This document contains the postings from mostly one individual, Hector Perez Torres, collected at the yahoo site: http://groups.yahoo.com/group/evgray/. Within are message numbers from 20,000 to 24,999, the rest left to subsequent volumes. Messages #20091 Re: Videos - Longitudinal and Transverse --- I will sum it to a single solution.... "Impedance Matching" RV proves the point quite well with an RV fed from a single wire at a distance , a Air capacitor "plate" is used at ends to complete the "dipole" the single wire signal is lomgitudinal in nature.... Can it be understood ? Hector #20105 Re: Videos - Longitudinal and Transverse Answer within lines (and this are important ones to add to compilations so read carefully ) Hector --- In [email protected], "Dan Combine" <dancombine@...> wrote: > There are 2 kinds of impedance matching: > > 1. complex impedance matching > (R-load = R-line) and Ampere load & Voltage load & density load & vaccum load within a set of many posible vectoring in LC networks from narrowbanded low impedance to broadbanded hi impedanced spectrum . > > This is also called reflectionless or broadband matching, and is the most commonly used in the 'modern' world. (usualy hi impedance) > It is to avoid reflection back into the transmission line or source. In RF the ternm is to avoid reflected power (SWR) matching 1:1 Both > the load and source must be resistive, so Z-load = Z-line = Z- source. not nesesarily as source as well as load can be virstualy superconductive at resonant states , MRA papers gives a hint to that Were is the resistance at 0 point ? if voltage is maximal and current is 0 resistance is 0 As well if current is maximal and voltage is 0 resistance again is virtualy o ... so in a perfect resonant conditions we have specific points were we have ZPE , superconductivity and a virtual GATE into aether time space energy transformation (transponder energy states) > If not, you create standing waves. > Although source and load should each be totally resistive for this form of matching to work, the more general term 'impedance' is still used to describe the source and load characteristics. Any and all reactance actually present in the source or the load will affect the 'match'. within rotating phasors the resistance is also a virtual state within the rotary equation at work within the circuit , the overal circulation average gives impedance value relative to the energy time loss constant within the circuit (impedance ) in ohms being direct relative to oscillation decay of energy within the circuit . the tensor states are rotary from OU (0 point) to under OU loss states , worst case of .618 to .3 decay loss (entropy ) in .5 power factor stage of rotating LC signal . what tesla discharge circuits teach is to take energy at a ZPE peak within LC as sample teslacoil HV trafo secundary were capacitor resonates at peak & discharges its PEAK across spark gap were rapid susesion of secundary oscillations take prace being amplificative in nature of their superconductivity states (virtual overunity power in teslacoil LOW turn Hiper Q primary air coil core (teslacoil . > > > 2. complex conjugate matching > (Z-load = complex conjugate of Z-source; or Z-source = a + jb; Z-load = > a - jb) > > This is used in cases in which the source and load are reactive. This form of impedance matching can only maximize the power transfer between a reactive source and a reactive load at a single frequency. I believe you are referring to the second one (complex conjugate match), > right? Remember I had told the whole circuit parameters are interlaced with each other (skiped to save bandwidth) > Now the problem I have, is how to make the cap in resonance? We need to find > a way to make the Z-source (inverter?) match Z-load (RV) through the air > cap. > Any hint on how to accomplish this? Increase voltage & energy becomes proportionaly increased in a single wire as air capacity becomes greater proportionaly to squared voltage ... (Voltage farad = joule second formula aplies. You will have a linear scalar component induced in the single wire matched to physical mass series resonance formula aplies here within a virtual floating grownd within a resonant dipole .... same rules aply to pure current transmision using EARTH wave as virtual conductor ... only Tesla was not able to aply herzian theory and RF modern theory to it . I had being telling this sinse 1989 over the internet and sinse 1979 within closed engineering R&D groups ... RV lab construction contains all that is needed to understand the marriage of RF (radiant energy ) and power engineering ... (Kindergarden basic stuff), current waves as well as voltage waves can be matched at distant points within resonant nodes . One thing basic to be understood is that you need to create a dipole , the other part of the pole you are to tap energy from in order to extract or use energy from it ... and this POWER needs to be extracted non reflectively to source or resonant resistive to it (in case of a natural standing wave ) reread postings on taping to natural energy tensors .. Hector :) #20130 Re: Air cap... cont'd ... Dan/Hector. The longitudinal waves signal use the spherical condensers as resonators (free standing ) were its signal response is as a charge being oscillatory in nature and resonant with its medium, being the distance a NULL as the spheres contain their own mass related charge (not tied to each other) ClC were C is alike a mass resonator (rod) were signal travels end to end forming an standing wave (acustico-electrical resonance ) the free sphere has a given dipole wavelenght value at with it resonates in free space . That is the confusion of TESLA method & Hertz method hertz antenna is treated as reactive node , Tesla treats the antenna as a capacitive component node ... Its RF in 2 modes of usage, the methods are in we use CLC or LCL in wireless energy transmission or single wire one . Try using a 55 gallon metal drum as end C in a 10KV secundary connecting with 100feet of fine wire to another trafo 100FT away 10Kv secundary connected to another 55 gall metal drum as end resonator , the conectivity of the 2 is not coupled to their distance, but to the CHARGE potential as condenser node within its aether medium ... that makes the single wire the sole conection needed to transmit power ... alike a can & an string and the another can , does the sound wave travel the grownd ? (no) it travels the single wire to the other can were it resonates its mass .. Electrically is the same, the spherical condenser is a non-moving medium to the relative wave traveling the CLC being the spherical condenser an STANDING wave NODE in the LCL circuit ,this can be demostrated using oscilloscope readings within the components under energy transmision from point to point ... Alike RV such setup has a set of parameters that works optimal and OU ClC values Q as well as its best operating frequency .. Using hi efficiency transformers as frequency is increased its ability to transmit more power efectively goes up untill a max optimal is reached Power energy can be turned to RF mode and from RF mode at the other end back to being Power into a receiving end node (load). (RV shows that quite efectively ) From one phase we get 3 Then why not from a single wire ? (its easy ) having the MEANS to match the SOURCE to the load needs as Tesla Told. What we need is the signal to RESONATE REFLECTIVE to Source in order to match it to the load ,in a power factor goin to trash RF mode but constricted Electro - accusticaly to the carrier wave wire , signal glues on to the wire it travels on ... prefering it 1,000,000 to 1 than traveling the air medium . (The sphere is the best Capacitive node antenna ) The resonant charge is distributed 360Deg within its surface. but is not coupled to anything (only to space tensor ) "Aether ambient pressure" and air conductivity (local). Keep this Notes as this are the true no bullshit Tesla secret solutions . Open sourced & free ... Lab tested & RF engineering book justified ... Hector :) #20247 Keely Motor secret. Looking at a modern PM stator DC motor, lets take the rotor and look at it as if it were off the shelf VTA, what do we have missing ? The vertical sideway shield, that is a copper tube were you slide the rotor into to create a damping shield. Once you have that an EXTRA set of brushes Anyone can convert a DC PM motor to VTA or a VTA to a Kellymotor. can be static or rotary, thing is it can run itself with its own magnetic ampl;ification energy . The shield does not afect its workings as a motor at all sinse its on the same non inducing plane as a parrallel wire to a parrallel field. (non interacting) AMEN ! Tales from the "Kript" will continue later. Hector :) #20280 Re: VTA DC ROTOR Acts like a POLARIZED filter Lets signal pass the vertical but not the horizontal (damping) Or lets pass the horizontal and not the vertical . That PERMITS the magnetotransistor effect amplification Can be used Without The Faraday Shield but somewhat is more problematic to keep magnets gaused over time ... AC tends to degause magnets over time Even Bb,Cn ones .. But ones to use are ceramic 8 Other types need to be adapted to effect as field is a Mayor factor in VTA effect . http://www.howmagnetswork.com/types.html (basics) Some magnets have MODULATION permeability Or the Spring action needed for a verry efective VTA operation Thoose with FULL magnetic Latching capability (like IBM memory cores ) are OU out from the Box ,
Load more

Recommended publications
  • Net Zero by 2050 a Roadmap for the Global Energy Sector Net Zero by 2050
    Net Zero by 2050 A Roadmap for the Global Energy Sector Net Zero by 2050 A Roadmap for the Global Energy Sector Net Zero by 2050 Interactive iea.li/nzeroadmap Net Zero by 2050 Data iea.li/nzedata INTERNATIONAL ENERGY AGENCY The IEA examines the IEA member IEA association full spectrum countries: countries: of energy issues including oil, gas and Australia Brazil coal supply and Austria China demand, renewable Belgium India energy technologies, Canada Indonesia electricity markets, Czech Republic Morocco energy efficiency, Denmark Singapore access to energy, Estonia South Africa demand side Finland Thailand management and France much more. Through Germany its work, the IEA Greece advocates policies Hungary that will enhance the Ireland reliability, affordability Italy and sustainability of Japan energy in its Korea 30 member Luxembourg countries, Mexico 8 association Netherlands countries and New Zealand beyond. Norway Poland Portugal Slovak Republic Spain Sweden Please note that this publication is subject to Switzerland specific restrictions that limit Turkey its use and distribution. The United Kingdom terms and conditions are available online at United States www.iea.org/t&c/ This publication and any The European map included herein are without prejudice to the Commission also status of or sovereignty over participates in the any territory, to the work of the IEA delimitation of international frontiers and boundaries and to the name of any territory, city or area. Source: IEA. All rights reserved. International Energy Agency Website: www.iea.org Foreword We are approaching a decisive moment for international efforts to tackle the climate crisis – a great challenge of our times.
    [Show full text]
  • Energy and Training Module ITU Competitive Coach
    37 energy and training module ITU Competitive Coach Produced by the International Triathlon Union, 2007 38 39 energy & training Have you ever wondered why some athletes shoot off the start line while others take a moment to react? Have you every experienced a “burning” sensation in your muscles on the bike? Have athletes ever claimed they could ‘keep going forever!’? All of these situations involve the use of energy in the body. Any activity the body performs requires work and work requires energy. A molecule called ATP (adenosine triphosphate) is the “energy currency” of the body. ATP powers most cellular processes that require energy including muscle contraction required for sport performance. Where does ATP come from and how is it used? ATP is produced by the breakdown of fuel molecules—carbohydrates, fats, and proteins. During physical activity, three different processes work to split ATP molecules, which release energy for muscles to use in contraction, force production, and ultimately sport performance. These processes, or “energy systems”, act as pathways for the production of energy in sport. The intensity and duration of physical activity determines which pathway acts as the dominant fuel source. Immediate energy system Fuel sources ATP Sport E.g. carbohydrates, energy performance proteins, fats “currency” Short term energy system E.g. swimming, cycling, running, transitions Long term energy system During what parts of a triathlon might athletes use powerful, short, bursts of speed? 1 2 What duration, intensity, and type of activities in a triathlon cause muscles to “burn”? When in a triathlon do athletes have to perform an action repeatedly for longer than 10 or 15 3 minutes at a moderate pace? 40 energy systems Long Term (Aerobic) System The long term system produces energy through aerobic (with oxygen) pathways.
    [Show full text]
  • Hydropower Special Market Report Analysis and Forecast to 2030 INTERNATIONAL ENERGY AGENCY
    Hydropower Special Market Report Analysis and forecast to 2030 INTERNATIONAL ENERGY AGENCY The IEA examines the IEA member IEA association full spectrum countries: countries: of energy issues including oil, gas and Australia Brazil coal supply and Austria China demand, renewable Belgium India energy technologies, electricity markets, Canada Indonesia energy efficiency, Czech Republic Morocco access to energy, Denmark Singapore demand side Estonia South Africa management and Finland Thailand much more. Through France its work, the IEA Germany advocates policies that Greece will enhance the Hungary reliability, affordability Ireland and sustainability of Italy energy in its 30 member countries, Japan 8 association countries Korea and beyond. Luxembourg Mexico Netherlands New Zealand Norway Revised version, Poland July 2021. Information notice Portugal found at: www.iea.org/ Slovak Republic corrections Spain Sweden Switzerland Turkey United Kingdom Please note that this publication is subject to United States specific restrictions that limit its use and distribution. The The European terms and conditions are available online at Commission also www.iea.org/t&c/ participates in the work of the IEA This publication and any map included herein are without prejudice to the status of or sovereignty over any territory, to the delimitation of international frontiers and boundaries and to the name of any territory, city or area. Source: IEA. All rights reserved. International Energy Agency Website: www.iea.org Hydropower Special Market Report Abstract Abstract The first ever IEA market report dedicated to hydropower highlights the economic and policy environment for hydropower development, addresses the challenges it faces, and offers recommendations to accelerate growth and maintain the existing infrastructure.
    [Show full text]
  • Chapter 1: Energy Challenges September 2015 1 Energy Challenges
    QUADRENNIAL TECHNOLOGY REVIEW AN ASSESSMENT OF ENERGY TECHNOLOGIES AND RESEARCH OPPORTUNITIES Chapter 1: Energy Challenges September 2015 1 Energy Challenges Energy is the Engine of the U.S. Economy Quadrennial Technology Review 1 1 Energy Challenges 1.1 Introduction The United States’ energy system, vast in size and increasingly complex, is the engine of the economy. The national energy enterprise has served us well, driving unprecedented economic growth and prosperity and supporting our national security. The U.S. energy system is entering a period of unprecedented change; new technologies, new requirements, and new vulnerabilities are transforming the system. The challenge is to transition to energy systems and technologies that simultaneously address the nation’s most fundamental needs—energy security, economic competitiveness, and environmental responsibility—while providing better energy services. Emerging advanced energy technologies can do much to address these challenges, but further improvements in cost and performance are important.1 Carefully targeted research, development, demonstration, and deployment (RDD&D) are essential to achieving these improvements and enabling us to meet our nation’s energy objectives. This report, the 2015 Quadrennial Technology Review (QTR 2015), examines science and technology RDD&D opportunities across the entire U.S. energy system. It focuses primarily on technologies with commercialization potential in the mid-term and beyond. It frames various tradeoffs that all energy technologies must balance, across such dimensions as diversity and security of supply, cost, environmental impacts, reliability, land use, and materials use. Finally, it provides data and analysis on RDD&D pathways to assist decision makers as they set priorities, subject to budget constraints, to develop more secure, affordable, and sustainable energy services.
    [Show full text]
  • The Radio Amateurs Microwave Communications Handbook.Pdf
    1594 THE RADIO AMATEUR'S COM ' · CA 10 S HANDBOOK DAVE INGRAM, K4TWJ THE RADIO AMATEUR'S - MICROWAVE COMMUNICATIONS · HANDBOOK DAVE INGRAM, K4TWJ ITABI TAB BOOKS Inc. Blue Ridge Summit, PA 17214 Other TAB Books by the Author No. 1120 OSCAR: The Ham Radio Satellites No. 1258 Electronics Projects for Hams, SWLs, CSers & Radio Ex­ perimenters No. 1259 Secrets of Ham Radio DXing No. 1474 Video Electronics Technology FIRST EDITION FIRST PRINTING Copyright © 1985 by TAB BOOKS Inc. Printed in the United States of America Reproduction or publication of the content in any manner, without express permission of the publisher, is prohibited. No liability is assumed with respect to the use of the information herein. Library of Congress Cataloging in Publication Data Ingram, Dave. The radio amateur's microwave communications handbook. Includes index. 1. Microwave communication systems-Amateurs' manuals. I. Title. TK9957.154 1985 621.38'0413 85-22184 ISBN 0-8306-0194-5 ISBN 0-8306-0594-0 (pbk.) Contents Acknowledgments v Introduction vi 1 The Amateur 's Microwave Spectrum 1 The Early Days and Gear for Microwaves- The Microwave Spectrum- Microwavesand EME-Microwavesand the Am- ateur Satellite Program 2 Microwave Electronic Theory 17 Electronic Techniques for hf/vhf Ranges- Electronic Tech- niques for Microwaves-Klystron Operation-Magnetron Operation-Gunn Diode Theory 3 Popular Microwave Bands 29 Circuit and Antennas for the 13-cm Band-Designs for 13-cm Equipment 4 Communications Equipment for 1.2 GHz 42 23-cm Band Plan-Available Equipment- 23-cm OX 5
    [Show full text]
  • The Entropocene
    THE ENTROPOCENE Jeff Robbins Rutgers University 101 Murray Hall, New Brunswick, NJ 08901, USA ABSTRACT According to Eric Schneider and the late James Kay “nature abhors a gradient” as it seeks to degrade any and all differences that can make a difference. They also claim that life self-organized by creating a meta-order out of disordered orders, evolving as an increasingly efficient, effective, sustainable (order from order) means for degrading the huge sun to earth temperature gradient. They inject purpose into the scheme by claiming that life represents “order emerging from disorder in the service of more disorder.” Or, as Jeffrey Wicken succinctly put it in “Evolution and Thermodynamics: The New Paradigm,” “Organisms are remote-from-equilibrium systems that maintain their organizational structures by irreversibly degrading free energy through informed kinetic pathways acquired through evolution. Dissipation through structuring is the strategy of life.” In other words, life came about as an evolving means for giving the Second Law of Thermodynamics what it wants. Entropy. In my 2015 ISSS paper, “Anthropocene as Life’s State of the Art in Disorder Production: A Sustainability Conundrum,” I proposed that our species collectively is disorder producer summa cum laude. We are the most efficient, most effective, degrader of gradients, producer of entropy yet evolved. Calling our epoch, “the Anthropocene” doesn’t capture our essence. Our epoch is the Entropocene. We have turned the bio-geosphere from an accumulator of solar exergy (“free energy”, the measure of energy’s utility) as in fossil fuels, into a trapper of entropy a.k.a., global warming.
    [Show full text]
  • System-Of-Systems Approach for Integrated Energy Systems
    A System-of-Systems Approach for Integrated Energy Systems Modeling and Simulation Preprint Saurabh Mittal, Mark Ruth, Annabelle Pratt, Monte Lunacek, Dheepak Krishnamurthy, and Wesley Jones National Renewable Energy Laboratory Presented at the Society for Modeling & Simulation International Summer Simulation Multi-Conference Chicago, Illinois July 26–29, 2015 NREL is a national laboratory of the U.S. Department of Energy Office of Energy Efficiency & Renewable Energy Operated by the Alliance for Sustainable Energy, LLC This report is available at no cost from the National Renewable Energy Laboratory (NREL) at www.nrel.gov/publications. Conference Paper NREL/CP-2C00-64045 August 2015 Contract No. DE-AC36-08GO28308 NOTICE The submitted manuscript has been offered by an employee of the Alliance for Sustainable Energy, LLC (Alliance), a contractor of the US Government under Contract No. DE-AC36-08GO28308. Accordingly, the US Government and Alliance retain a nonexclusive royalty-free license to publish or reproduce the published form of this contribution, or allow others to do so, for US Government purposes. This report was prepared as an account of work sponsored by an agency of the United States government. Neither the United States government nor any agency thereof, nor any of their employees, makes any warranty, express or implied, or assumes any legal liability or responsibility for the accuracy, completeness, or usefulness of any information, apparatus, product, or process disclosed, or represents that its use would not infringe privately owned rights. Reference herein to any specific commercial product, process, or service by trade name, trademark, manufacturer, or otherwise does not necessarily constitute or imply its endorsement, recommendation, or favoring by the United States government or any agency thereof.
    [Show full text]
  • Transforming Buildings Through Integrated Energy Systems
    Transforming Buildings Through Integrated Energy Systems A Novel Approach to Integration As modern society becomes increasingly dependent on electricity, the implications are more apparent during grid disruptions―such as extreme weather events or cascading power failures that can leave homes and businesses without power for weeks at a time. Moreover, at least 1.3 billion people worldwide have no access to electricity at all; for a billion more, access is unreliable. Distributed energy generation from solar arrays holds promise to help address these challenges, especially given the falling cost of photovoltaic (PV) technologies. Integrated energy systems enable buildings to use and However, rapid deployment of distributed power is store energy from available resources (such as solar beginning to create new challenges for centralized grid energy) efficiently. systems that must now be addressed. A cross-disciplinary research team at Oak Ridge implement an integrated energy system control to National Laboratory (ORNL) is tackling the challenge of optimally manage the building load, distributed providing reliable, resilient, and responsible energy use generation, and required energy storage; and in buildings through an integrated approach to electricity generation, distribution, and consumption. enable use-inspired research to understand the science needed to make transformative When successful, this research will enable breakthroughs in energy storage. cost effective, sustainable integration of The expertise of members of this research effort spans distributed and renewable energy sources into various areas including materials science, building building systems and technologies, vehicle research, advanced manufacturing, cost-optimal development, design, and power systems, optimization, sensors and controls, and Contact management of integrated energy systems (load, microgrid research.
    [Show full text]
  • Hydropower Vision Chapter 2
    Chapter 2: State of Hydropower in the United States Hydropower A New Chapter for America’s Renewable Electricity Source STATE OF HYDROPOWER 2 in the United States Photo from 65681751. Illustration by Joshua Bauer/NREL 70 2 Overview OVERVIEW Hydropower is the primary source of renewable energy generation in the United States, delivering 48% of total renewable electricity sector generation in 2015, and roughly 62% of total cumulative renewable generation over the past decade (2006-2015) [1]. The approximately 101 gigawatts1 (GW) of hydropower capacity installed as of 2014 included ~79.6 GW from hydropower gener ation2 facilities and ~21.6 GW from pumped storage hydro- power3 facilities [2]. Reliable generation and grid support services from hydropower help meet the nation’s require- ments for the electrical bulk power system, and hydro- power pro vides a long-term, renewable source of energy that is essentially free of hazardous waste and is low in carbon emissions. Hydropower also supports national energy security, as its fuel supply is largely domestic. % 48 HYDROPOWER PUMPED CAPACITY STORAGE OF TOTAL CAPACITY RENEWABLE GENERATION Hydropower is the largest renewable energy resource in the United States and has been an esta blished, reliable contributor to the nation’s supply of elec­ tricity for more than 100 years. In the early 20th century, the environmental conse- quences of hydropower were not well characterized, in part because national priorities were focused on economic development and national defense. By the latter half of the 20th century, however, there was greater awareness of the environmental impacts of dams, reservoirs, and hydropower operations.
    [Show full text]
  • 2019 California Energy Efficiency Action Plan
    California Energy Commission FINAL STAFF REPORT 2019 California Energy Efficiency Action Plan 2019 California Energy Efficiency Action Plan Gavin Newsom, Governor November 2019 | CEC-400-2019-010-SF California Energy Commission David Hochschild Chair Janea A. Scott Vice Chair Karen Douglas, J.D. J. Andrew McAllister, Ph.D. Patty Monahan Commissioners Michael Kenney Heather Bird Heriberto Rosales Primary Authors Michael Kenney Project Manager Jennifer Nelson Office Manager EXISTING BUILDINGS OFFICE Michael J. Sokol Deputy Director EFFICIENCY DIVISION Drew Bohan Executive Director DISCLAIMER Staff members of the California Energy Commission prepared this report. As such, it does not necessarily represent the views of the Energy Commission, its employees, or the State of California. The Energy Commission, the State of California, its employees, contractors and subcontractors make no warrant, express or implied, and assume no legal liability for the information in this report; nor does any party represent that the uses of this information will not infringe upon privately owned rights. This report has not been approved or disapproved by the Energy Commission nor has the Commission passed upon the accuracy or adequacy of the information in this report. ACKNOWLEDGEMENTS Martha Brook Glen Baird Antonio Cano Charles Belk Bryan Early California Department of Community Services and Development Aida Escala Carolyn Cook Anne Fisher California Department of Food and Fritz Foo Agriculture Nicholas Janusch Rachel Ballanti Erik Jensen Eliana Camargo Daniel
    [Show full text]
  • Guide for Conducting Energy Efficiency Potential Studies
    Guide for Conducting Energy Effi ciency Potential Studies A RESOURCE OF THE NATIONAL ACTION PLAN FOR ENERGY EFFICIENCY NOVEMBER 2007 About This Document This Guide for Conducting Energy Effi ciency Potential Studies is provided to assist state offi cials, regulators, legislators, and others in the implementation of the recommendations of the National Action Plan for Energy Effi ciency (Action Plan) and the pursuit of its longer-term goals. This Guide identifi es three main applications for energy effi ciency potential studies and provides examples of each, along with a de­ scription of how key decisions regarding scope and methodology are made to best achieve the studies’ objectives. It also provides an overview of the main analytical steps in conducting a potential study and introduces several related concepts. The primary intended audience for this Guide is policy-makers, state offi cials, utility staff, and effi ciency advocates looking for guidance on the process of conducting potential studies. These individuals can also use the Guide to review the results of already- completed studies. Guide for Conducting Energy Effi ciency Potential Studies A RESOURCE OF THE NATIONAL ACTION PLAN FOR ENERGY EFFICIENCY NOVEMBER 2007 The Guide for Conducting Energy Effi ciency Potential Studies is a product of the National Action Plan for Energy Effi ­ ciency Leadership Group and does not refl ect the views, policies, or otherwise of the federal government. The role of the U.S. Department of Energy and U.S. Environmental Protection Agency is limited to facilitation of the Action Plan. This document was fi nal as of December 2007 and incorporates minor modifi cations to the original release.
    [Show full text]
  • Chapter 7 on Energy Systems Gas (GHG) Emissions
    7 Energy Systems Coordinating Lead Authors: Thomas Bruckner (Germany), Igor Alexeyevich Bashmakov (Russian Federation), Yacob Mulugetta (Ethiopia / UK) Lead Authors: Helena Chum (Brazil / USA), Angel De la Vega Navarro (Mexico), James Edmonds (USA), Andre Faaij (Netherlands), Bundit Fungtammasan (Thailand), Amit Garg (India), Edgar Hertwich (Austria / Norway), Damon Honnery (Australia), David Infield (UK), Mikiko Kainuma (Japan), Smail Khennas (Algeria / UK), Suduk Kim (Republic of Korea), Hassan Bashir Nimir (Sudan), Keywan Riahi (Austria), Neil Strachan (UK), Ryan Wiser (USA), Xiliang Zhang (China) Contributing Authors: Yumiko Asayama (Japan), Giovanni Baiocchi (UK / Italy), Francesco Cherubini (Italy / Norway), Anna Czajkowska (Poland / UK), Naim Darghouth (USA), James J. Dooley (USA), Thomas Gibon (France / Norway), Haruna Gujba (Ethiopia / Nigeria), Ben Hoen (USA), David de Jager (Netherlands), Jessica Jewell (IIASA / USA), Susanne Kadner (Germany), Son H. Kim (USA), Peter Larsen (USA), Axel Michaelowa (Germany / Switzerland), Andrew Mills (USA), Kanako Morita (Japan), Karsten Neuhoff (Germany), Ariel Macaspac Hernandez (Philippines / Germany), H-Holger Rogner (Germany), Joseph Salvatore (UK), Steffen Schlömer (Germany), Kristin Seyboth (USA), Christoph von Stechow (Germany), Jigeesha Upadhyay (India) Review Editors: Kirit Parikh (India), Jim Skea (UK) Chapter Science Assistant: Ariel Macaspac Hernandez (Philippines / Germany) 511 Energy Systems Chapter 7 This chapter should be cited as: Bruckner T., I. A. Bashmakov, Y. Mulugetta, H. Chum, A. de la Vega Navarro, J. Edmonds, A. Faaij, B. Fungtammasan, A. Garg, E. Hertwich, D. Honnery, D. Infield, M. Kainuma, S. Khennas, S. Kim, H. B. Nimir, K. Riahi, N. Strachan, R. Wiser, and X. Zhang, 2014: Energy Systems. In: Climate Change 2014: Mitigation of Climate Change. Contribution of Working Group III to the Fifth Assessment Report of the Intergovernmental Panel on Climate Change [Edenhofer, O., R.
    [Show full text]