Your search keyword '"McElroy, Michael B."' showing total 11 results

1. Transition towards higher penetration of renewables: an overview of interlinked technical, environmental and socio-economic challenges

Author

CHEN, Xinyu, MCELROY, Michael B., WU, Qiuwei, SHU, Yinbiao, and XUE, Yusheng

Published

2019

2. Potential for Wind-Generated Electricity in China

Author

McElroy, Michael B., Lu, Xi, Nielsen, Chris P., and Wang, Yuxuan

Published

2009

3. Global Potential for Wind-Generated Electricity

Author

Lu, Xi, McElroy, Michael B., Kiviluoma, Juha, and Anderson, James G.

Published

2009

4. Production of hydrogen from offshore wind in China and cost-competitive supply to Japan.

Author

Song, Shaojie, Lin, Haiyang, Sherman, Peter, Yang, Xi, Nielsen, Chris P., Chen, Xinyu, and McElroy, Michael B.

Subjects

WIND power, HYDROGEN production, ECONOMIC forecasting, HYDROGEN as fuel, CLEAN energy, ENERGY futures

Abstract

The Japanese government has announced a commitment to net-zero greenhouse gas emissions by 2050. It envisages an important role for hydrogen in the nation's future energy economy. This paper explores the possibility that a significant source for this hydrogen could be produced by electrolysis fueled by power generated from offshore wind in China. Hydrogen could be delivered to Japan either as liquid, or bound to a chemical carrier such as toluene, or as a component of ammonia. The paper presents an analysis of factors determining the ultimate cost for this hydrogen, including expenses for production, storage, conversion, transport, and treatment at the destination. It concludes that the Chinese source could be delivered at a volume and cost consistent with Japan's idealized future projections. Hydrogen is regarded as important to Japan's clean energy transition. Here the authors consider the production of hydrogen by electrolysis fueled by offshore wind power in China, and the potential for delivery to Japan as part of Japan's transition. [ABSTRACT FROM AUTHOR]

Published

2021

5. The missing money problem: Incorporation of increased resources from wind in a representative US power market.

Author

Chen, Xinyu, McElroy, Michael B., and Deng, Yawen

Subjects

*WIND power, *WIND power industry, *CARBON taxes, *MARKET prices, *RESOURCE management, *CARBON dioxide reduction, *FINANCE, *PRICES

Abstract

The paper considers opportunities to reduce emissions of CO 2 through increases in commitments to wind in a representative US power market. A model is applied to simulate market operations for different wind levels focusing on implications of the reduction in clearing prices arising due to increasing inputs of zero marginal cost power from wind, a dilemma referred to as the missing money problem. The resulting decrease in income poses problems for existing thermal and nuclear generating systems, at the same time making investments in wind uneconomic in the absence offsetting policy interventions. Two options are considered to subsidize cost: an investment credit (IC) or a subsidy on production (PC). The dilemma could be addressed also with a carbon tax targeted to increase income. It is assumed that the cost associated with the IC and PC options should be borne by the consumer, offsetting benefits from lower wholesale prices. It is assumed further that income from the carbon tax should be rebated to the consumer offsetting related increases in clearing prices. IC and PC options offer opportunities to reduce emissions at low or even negative net costs to the consumer. Higher costs are associated with the option of a carbon tax. [ABSTRACT FROM AUTHOR]

Published

2018

6. Integrated Energy Systems for Higher Wind Penetration in China: Formulation, Implementation, and Impacts.

Author

Chen, Xinyu, McElroy, Michael B., and Kang, Chongqing

Subjects

*WIND power, *ELECTRIC power production forecasting, *COGENERATION of electric power & heat, *HEAT storage

Abstract

With the largest installed capacity in the world, wind power in China is experiencing a ∼20% curtailment. The inflexible combined heat and power (CHP) has been recognized as the major barrier for integrating the wind source. The approach to reconcile the conflict between inflexible CHP units and variable wind power in Chinese energy system is yet unclear. This paper explores the technical and economic feasibility of deploying the heat storage tanks and electric boilers under typical power grids and practical operational regulations. A mixed integer linear optimization model is proposed to simulate an integrated power and heating energy systems, including a CHP model capable of accounting for the commitment decisions and nonconvex energy generation constraints. The model is applied to simulate a regional energy system (Jing–Jin–Tang) covering 100-million population, with hourly resolution over a year, incorporating actual data, and operational regulations. The results project an accelerating increase in wind curtailment rate at elevated wind penetration. Investment for wind breaks even at 14% wind penetration. At such penetration, the electric boiler (with heat storage) is effective in reducing wind curtailment. The investment in electric boilers is justified on a social economic basis, but the revenues for different stakeholders are not distributed evenly. [ABSTRACT FROM AUTHOR]

Published

2018

7. A 32-year perspective on the origin of wind energy in a warming climate.

Author

Huang, Junling and McElroy, Michael B.

Subjects

*WIND power, *HIGH temperatures, *THERMODYNAMICS, *KINETIC energy, *ATMOSPHERIC circulation

Abstract

Based on assimilated meteorological data for the period January 1979 to December 2010, the origin of wind energy is investigated from both mechanical and thermodynamic perspectives, with special focus on the spatial distribution of sources, historical long-term variations and the efficiency for kinetic energy production. The dry air component of the atmosphere acts as a thermal engine, absorbing heat at higher temperatures, approximately 256 K , releasing heat at lower temperatures, approximately 252 K . The process is responsible for production of wind kinetic energy at a rate of 2.46 W / m 2 sustaining thus the circulation of the atmosphere against frictional dissipation. The results indicate an upward trend in kinetic energy production over the past 32 years, indicating that wind energy resources may be varying in the current warming climate. This analysis provides an analytical framework that can be adopted for future studies addressing the ultimate wind energy potential and the possible perturbations to the atmospheric circulation that could arise as a result of significant exploitation of wind energy. [ABSTRACT FROM AUTHOR]

Published

2015

8. Costs for Integrating Wind into the Future ERCOT System with Related Costs for Savings in CO2 Emissions.

Author

Xi Lu, McElroy, Michael B., and Sluzas, Nora A.

Subjects

*EMISSIONS (Air pollution), *COST effectiveness, *CARBON dioxide mitigation, *WIND power industry, *WIND power, *ELECTRIC power consumption, *ECONOMICS, *INDUSTRY & the environment

Abstract

Wind power can make an important contribution to the goal of reducing emissions of CO2. The major problem relates to the intrinsic variability of the source and the difficulty of reconciling the supply of electricity with demand particularly at high levels of wind penetration. This challenge is explored for the case of the ERCOT system in Texas. Demand for electricity in Texas is projected to increase by approximately 60% by 2030. Considering hourly load data reported for 2006, assuming that the pattern of demand in 2030 should be similar to 2006, and adopting as a business as usual (BAU) reference an assumption that the anticipated additional electricity should be supplied by a combination of coal and gas with prices, discounted to 2007 dollars of $2 and $6 per MMBTU respectively, we conclude that the bus-bar price for electricity would increase by about 1.1 ¢/kWh at a wind penetration level of 30%, by about 3-4 ¢/kWh at a penetration level of 80%. Corresponding costs for reductions in CO2 range from $20/ton to $60/ton. A number of possibilities are discussed that could contribute to a reduction in these costs including the impact of an expanded future fleet of electrically driven vehicles. [ABSTRACT FROM AUTHOR]

Published

2011

9. Modeling formulation and validation for accelerated simulation and flexibility assessment on large scale power systems under higher renewable penetrations.

Author

Han, Xingning, Chen, Xinyu, McElroy, Michael B., Liao, Shiwu, Nielsen, Chris P., and Wen, Jinyu

Subjects

*RENEWABLE energy sources, *UNIT commitment problem (Electric power systems), *POWER system simulation, *WIND power

Abstract

Highlights • Novel formulation of unit commitment model for large-scale power system simulation. • Validated with standard test system and applied to real regional systems in China. • Increase the computational speed by more than 20,000 times with ∼1% error. • Can be applied to planning issues, e.g. optimal sizing of wind, solar and hydro. Abstract Deploying high penetration of variable renewables represents a critical pathway for decarbonizing the power sector. Hydro power (including pumped-hydro), batteries, and fast responding thermal units are essential in providing system flexibility at elevated renewable penetration. How to quantify the merit of flexibility from these sources in accommodating variable renewables, and to evaluate the operational costs considering system flexibility constraints have been central challenges for future power system planning. This paper presents an improved linear formulation of the unit commitment model adopting unit grouping techniques to expedite evaluation of the curtailment of renewables and operational costs for large-scale power systems. All decision variables in this formulation are continuous, and all chronological constraints are formulated subsequently. Tested based on actual data from a regional power system in China, the computational speed of the model is more than 20,000 times faster than the rigorous unit commitment model, with less than 1% difference in results. Hourly simulation for an entire year takes less than 3 min. The results demonstrate strong potential to apply the proposed model to long term planning related issues, such as flexibility assessment, wind curtailment analysis, and operational cost evaluation, which could set a methodological foundation for evaluating the optimal combination of wind, solar and hydro investments. [ABSTRACT FROM AUTHOR]

Published

2019

10. Reducing curtailment of wind electricity in China by employing electric boilers for heat and pumped hydro for energy storage.

Author

Zhang, Ning, Lu, Xi, McElroy, Michael B., Nielsen, Chris P., Chen, Xinyu, Deng, Yu, and Kang, Chongqing

Subjects

*WIND power plants, *BOILERS, *ENERGY storage, *ELECTRIC power systems, *WATER power, *HEAT pumps

Abstract

Accommodating variable wind power poses a critical challenge for electric power systems that are heavily dependent on combined-heat-and-power (CHP) plants, as is the case for north China. Pumped hydro storage (PHS) and electric boilers (EBs) are two of the strongest technological options under discussion in China to address this challenge, but rigorous quantitative analyses of their effectiveness rooted in actual system data are lacking. An improved unit-commitment based power system chronological simulation is applied to evaluate potential benefits from PHS and EBs in West Inner Mongolia (WIM), where CHP capacity is projected to increase to 33.8 GW by 2020. A business-as-usual (BAU) reference model assumes deployment of 20 GW of wind capacity. Compared to BAU, expanding wind capacity to 40 GW would allow for a reduction in CO 2 emissions of 33.9 million tons, but at a relatively high cost of US$25.3/ton, reflecting primarily high associated curtailment of wind electricity (20.4%). A number of scenarios adding PHS and/or EBs combined with higher levels of wind capacity are evaluated. The best case indicates that a combination of PHS (3.6 GW) and EBs (6.2 GW) together with 40 GW of wind capacity would reduce CO 2 emissions by 43.5 million tons compared to BAU and at a lower cost of US$16.0/ton. Achieving this outcome will require a price-incentive policy designed to ensure the profitability of both PHS and EB facilities. [ABSTRACT FROM AUTHOR]

Published

2016

11. Opportunities for household energy on the Qinghai-Tibet Plateau in line with United Nations' Sustainable Development Goals.

Author

Zhuang, Minghao, Lu, Xi, Peng, Wei, Wang, Yanfen, Wang, Jianxiao, Nielsen, Chris P., and McElroy, Michael B.

Subjects

*SUSTAINABLE development, *RENEWABLE energy sources, *WIND power, *INDOOR air pollution, *RENEWABLE energy transition (Government policy), *CLEAN energy

Abstract

Approximately seven million population in the Qinghai-Tibet Plateau of China, a global climate sensitive region, still rely primarily on yak dung for household cooking and heating. The treatment and combustion of yak dung result in a variety of negative impacts in terms of local alpine grassland degradation, indoor air pollution, public health risk, as well as global climate change. There is an urgent need to explore alternative pathway for affordable and clean energy as indicated in the United Nations' Sustainable Development Goals for 2030. This perspective has analyzed the key challenges rooted in yak dung use on the Qinghai-Tibet Plateau region. Based on this, this perspective has further proposed a new complementary energy system to take advantage of locally available, clean and sustainable energy sources of wind and solar power, and have provided economic analyses. Meanwhile, this perspective has pointed out the potential barriers to promoting the new complementary energy system in the Qinghai-Tibet Plateau region due to traditional habits, economic factors and policies. Finally, strategies for transitioning from yak dung to the proposed alternative energy system is discussed at the end. Successful energy transition for the Qinghai-Tibet Plateau region offers an important option to achieving many other sustainable development goals related to climate change, economic development, and environment. The perspective is expected to shed light on the development of sustainable energy in other developing region or countries in the world to address multiple societal goals. • Integrative analysis on negative impacts of dung combustion on ecological system, public health, and climate change. • Proposal of coupled wind-solar-storage system on the Qinghai-Tibet Plateau. • Solution toward sustainable energy transition on the Qinghai-Tibet Plateau. [ABSTRACT FROM AUTHOR]

Published

2021