THE SMART GRID CHARGING EVS

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Transcription:

THE SMART GRID CHARGING EVS GRANT BY THE MINISTRY OF ENERGY Benny Lutati, Vadim Levit, Tal Grinshpoun and Amnon meisels

(Smart) Motivation 2 The Smart Grid is here Much work on up-to-date information for smart production (and distribution) Good for the energy provider Focus on the consumer.. Smart homes can plan consumption according to dynamic pricing Cooperate for better bargaining

Motivation a simple case 3 Smart homes consumption is complex (multiple appliances and daily activities/schedule) A (somewhat) simpler consumption pattern Electric Vehicles (EVs) A 2-years study (granted by the Ministry of Energy) Our part EV charging in day-to-day practical scenarios Find methods to induce cooperation for better bargaining

4 V2G-enabled charging problem

EVs charging 5 Electric Vehicles (EVs) are an important part of the transition plan to a low carbon economy Expected to contribute ~50% to the total electric energy consumption Can stress the distribution system causing performance degradations and overloads The Smart Grid relates to advanced methods of balancing load Use computerized interactions to achieve load balancing Lower dependability on non-renewable, highly polluting energy sources

EVs charging 6 Main advantages of V2G-enabled EVs Charge in a well-balanced pattern in order to avoid overloading the smart grid Charge at a low demand time in order to store energy to be used at peak hours (helps the provider) Sell back the energy stored to reduce costs (helps consumer)

A day-to-day EVs charging problem 7 Many EVs are expected to be charged during the same time phase Between the times that the majority of the population is driving to work and back home Multiple EVs parked in large parking lots This pattern may lead to large demand peaks If tackled by extending the grid infrastructure can reduce the positive effects on the environment A better way is to attempt to find a peak reducing schedule for the EVs charging

A major goal - peak-reducing schedule 8 Find a schedule that will reduce the peaks and balance the load Take into consideration that different consumers: Have different time constraints Need different amounts of energy Have different willingness to pay

9 Game theoretic approach

Game theory vs. EV charging 10 Game theory assumes rationality of players The inherently self-interested nature of EVs meets game theoretic assumptions Game-theoretic model can be designed in order to capture the problem dynamics A mechanism can be applied to the game to ensure a desirable result

EV charging game 11 Resource allocation game - the cost of resources depends on the demand EVs select what time-slots to charge in Background load + EVs selections costs Each player is able to both produce resources and consume resources (e.g., charge or discharge) A sequence of rational responses leads to a stable state Theoretically predictable result of the game

12 Example

EVs charging game example 13 t 1 t 2 Require 2 Require 1 Request Request t 1 t 2 Require 2 Request t 1 t 2 A 1 A 2 A n Background Load Total load t 1 t 2 8 5 10 10 7 11

EVs charging game example 14 t 1 t 2 Require 2 Require 1 Request Request t 1 t 2 Require 2 Request t 1 t 2 A 1 A 2 A n Background Load Total load t 1 t 2 8 5 10 10 7 11

EVs charging game example 15 t 1 t 2 Require 2 Require 1 Request Request t 1 t 2 Require 2 Request t 1 t 2 A 1 A 2 A n Background Load Total load t 1 t 2 8 5 10 10 8 10

EVs charging game example 16 t 2 Require 2 Require 1 t 1 t 1 t 2 t 1 t 2 Require 2 Request Request Request A 1 A 2 A n Background Load Total load t 1 t 2 8 5 10 10 8 10

EVs charging game example 17 t 1 t 2 t 1 t 2 Require 2 Require 1 Require 2 Request Request Request t 1 t 2 A 1 A 2 A n Background Load Total load t 1 t 2 8 5 10 10 8 10

Controlling predictability 19 Background vs. Fixed Pricing Background vs. FCG

Conclusion (take home) 20 Simple mechanisms for balanced charging exist Consumers (EVs) play a selfish game and benefit Similar mechanisms can be designed for smart homes The overall dynamic-pricing model can be designed to include the producer (electricity distributor) All benefit - our group s second result first steps towards a start-up of smart meters software on the smart grid

22 Questions?

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