An Examination of California's 2030 Transportation Electrification Goals

Rivera, Patricia

01 January 2019

Climate change and air pollution pose serious consequences including longer heat waves and sea level rise. California is taking several initiatives to address these problems, calling for an 80% reduction in greenhouse gas emissions by 2050 from 1990 levels. The transportation sector in California has relied heavily on fossil fuels, significantly contributing to the emissions of greenhouse gas emissions. As a result, one of the main technologies the state has been motivating to combat this is the implementation of battery electric vehicles. These vehicles have not started gaining popularity until recently and there are still several market barriers that slow down electric vehicle adoption, such as availability of charging ports. Several other aspects need to be considered, such as the effects on grid demand and supply, as California expects to see a large- scale implementation of electric vehicles. This paper aims to provide information on California's long-term transportation electrification goals and analyze how the state is progressing towards their stated goals, given current electric vehicle market trends, charging availability, and electric demand and supply capacity.

Electric Vehicles

Transportation Electrification

Power Grid

Applied Mathematics

Design and Control of a Brushless Doubly-Fed Machine for Aviation Propulsion

Peng, Peng

January 2020

No description available.

Engineering

Harnessing demand flexibility to minimize cost, facilitate renewable integration, and provide ancillary services

Kefayati, Mahdi

18 September 2014

Renewable energy is key to a sustainable future. However, the intermittency of most renewable sources and lack of sufficient storage in the current power grid means that reliable integration of significantly more renewables will be a challenging task. Moreover, increased integration of renewables not only increases uncertainty, but also reduces the fraction of traditional controllable generation capacity that is available to cope with supply-demand imbalances and uncertainties. Less traditional generation also means less rotating mass that provides very short term, yet very important, kinetic energy storage to the system and enables mitigation of the frequency drop subsequent to major contingencies but before controllable generation can increase production. Demand, on the other side, has been largely regarded as non-controllable and inelastic in the current setting. However, there is strong evidence that a considerable portion of the current and future demand, such as electric vehicle load, is flexible. That is, the instantaneous power delivered to it needs not to be bound to a specific trajectory. In this thesis, we focus on harnessing demand flexibility as a key to enabling more renewable integration and cost reduction. We start with a data driven analysis of the potential of flexible demands, particularly plug-in electric vehicle (PEV) load. We first show that, if left unmanaged, these loads can jeopardize grid reliability by exacerbating the peaks in the load profile and increasing the negative correlation of demand with wind energy production. Then, we propose a simple local policy with very limited information and minimal coordination that besides avoiding undesired effects, has the positive side-effect of substantially increasing the correlation of flexible demand with wind energy production. Such local policies could be readily implemented as modifications to existing "grid friendly" charging modes of plug-in electric vehicles. We then propose improved localized charging policies that counter balance intermittency by autonomously responding to frequency deviations from the nominal frequency and show that PEV load can offer a substantial amount of such ancillary services. Next, we consider the case where real-time prices are employed to provide incentives for demand response. We consider a flexible load under such a pricing scheme and obtain the optimal policy for responding to stochastic price signals to minimize the expected cost of energy. We show that this optimal policy follows a multi-threshold form and propose a recursive method to obtain these thresholds. We then extend our results to obtain optimal policies for simultaneous energy consumption and ancillary service provision by flexible loads as well as optimal policies for operation of storage assets under similar real-time stochastic prices. We prove that the optimal policy in all these cases admits a computationally efficient form. Moreover, we show that while optimal response to prices reduces energy costs, it will result in increased volatility in the aggregate demand which is undesirable. We then discuss how aggregation of flexible loads can take us a step further by transforming the loads to controllable assets that help maintain grid reliability by counterbalancing the intermittency due to renewables. We explore the value of load flexibility in the context of a restructured electricity market. To this end, we introduce a model that economically incentivizes the load to reveal its flexibility and provides cost-comfort trade-offs to the consumers. We establish the performance of our proposed model through evaluation of the price reductions that can be provided to the users compared to uncontrolled and uncoordinated consumption. We show that a key advantage of aggregation and coordination is provision of "regulation" to the system by load, which can account for a considerable price reduction. The proposed scheme is also capable of preventing distribution network overloads. Finally, we extend our flexible load coordination problem to a multi-settlement market setup and propose a stochastic programming approach in obtaining day-ahead market energy purchases and ancillary service sales. Our work demonstrates the potential of flexible loads in harnessing renewables by affecting the load patterns and providing mechanisms to mitigate the inherent intermittency of renewables in an economically efficient manner. / text

Energy systems

Flexible loads

Smart grid

Optimal control

Plug-in electric vehicle

PEV

Transportation electrification

Stochastic programming

Renewable energy

Dynamic programming

Optimization