Enabling Peer to Peer Energy Trading Marketplace Using Consortium Blockchain Networks

abstract: Blockchain technology enables peer-to-peer transactions through the elimination of the need for a centralized entity governing consensus. Rather than having a centralized database, the data is distributed across multiple computers which enables crash fault tolerance as well as makes the sy...

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Other Authors: Sadaye, Raj Anil (Author)
Format: Dissertation
Language:English
Published: 2019
Subjects:
Online Access:http://hdl.handle.net/2286/R.I.55571
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spelling ndltd-asu.edu-item-555712020-01-15T03:01:11Z Enabling Peer to Peer Energy Trading Marketplace Using Consortium Blockchain Networks abstract: Blockchain technology enables peer-to-peer transactions through the elimination of the need for a centralized entity governing consensus. Rather than having a centralized database, the data is distributed across multiple computers which enables crash fault tolerance as well as makes the system difficult to tamper with due to a distributed consensus algorithm. In this research, the potential of blockchain technology to manage energy transactions is examined. The energy production landscape is being reshaped by distributed energy resources (DERs): photo-voltaic panels, electric vehicles, smart appliances, and battery storage. Distributed energy sources such as microgrids, household solar installations, community solar installations, and plug-in hybrid vehicles enable energy consumers to act as providers of energy themselves, hence acting as 'prosumers' of energy. Blockchain Technology facilitates managing the transactions between involved prosumers using 'Smart Contracts' by tokenizing energy into assets. Better utilization of grid assets lowers costs and also presents the opportunity to buy energy at a reasonable price while staying connected with the utility company. This technology acts as a backbone for 2 models applicable to transactional energy marketplace viz. 'Real-Time Energy Marketplace' and 'Energy Futures'. In the first model, the prosumers are given a choice to bid for a price for energy within a stipulated period of time, while the Utility Company acts as an operating entity. In the second model, the marketplace is more liberal, where the utility company is not involved as an operator. The Utility company facilitates infrastructure and manages accounts for all users, but does not endorse or govern transactions related to energy bidding. These smart contracts are not time bounded and can be suspended by the utility during periods of network instability. Dissertation/Thesis Sadaye, Raj Anil (Author) Candan, Kasim S (Advisor) Boscovic, Dragan (Committee member) Zhao, Ming (Committee member) Arizona State University (Publisher) Computer science Blockchain Distributed Systems Energy trading Hyperledger Fabric Marketplace Smart Contracts eng 97 pages Masters Thesis Computer Science 2019 Masters Thesis http://hdl.handle.net/2286/R.I.55571 http://rightsstatements.org/vocab/InC/1.0/ 2019
collection NDLTD
language English
format Dissertation
sources NDLTD
topic Computer science
Blockchain
Distributed Systems
Energy trading
Hyperledger Fabric
Marketplace
Smart Contracts
spellingShingle Computer science
Blockchain
Distributed Systems
Energy trading
Hyperledger Fabric
Marketplace
Smart Contracts
Enabling Peer to Peer Energy Trading Marketplace Using Consortium Blockchain Networks
description abstract: Blockchain technology enables peer-to-peer transactions through the elimination of the need for a centralized entity governing consensus. Rather than having a centralized database, the data is distributed across multiple computers which enables crash fault tolerance as well as makes the system difficult to tamper with due to a distributed consensus algorithm. In this research, the potential of blockchain technology to manage energy transactions is examined. The energy production landscape is being reshaped by distributed energy resources (DERs): photo-voltaic panels, electric vehicles, smart appliances, and battery storage. Distributed energy sources such as microgrids, household solar installations, community solar installations, and plug-in hybrid vehicles enable energy consumers to act as providers of energy themselves, hence acting as 'prosumers' of energy. Blockchain Technology facilitates managing the transactions between involved prosumers using 'Smart Contracts' by tokenizing energy into assets. Better utilization of grid assets lowers costs and also presents the opportunity to buy energy at a reasonable price while staying connected with the utility company. This technology acts as a backbone for 2 models applicable to transactional energy marketplace viz. 'Real-Time Energy Marketplace' and 'Energy Futures'. In the first model, the prosumers are given a choice to bid for a price for energy within a stipulated period of time, while the Utility Company acts as an operating entity. In the second model, the marketplace is more liberal, where the utility company is not involved as an operator. The Utility company facilitates infrastructure and manages accounts for all users, but does not endorse or govern transactions related to energy bidding. These smart contracts are not time bounded and can be suspended by the utility during periods of network instability. === Dissertation/Thesis === Masters Thesis Computer Science 2019
author2 Sadaye, Raj Anil (Author)
author_facet Sadaye, Raj Anil (Author)
title Enabling Peer to Peer Energy Trading Marketplace Using Consortium Blockchain Networks
title_short Enabling Peer to Peer Energy Trading Marketplace Using Consortium Blockchain Networks
title_full Enabling Peer to Peer Energy Trading Marketplace Using Consortium Blockchain Networks
title_fullStr Enabling Peer to Peer Energy Trading Marketplace Using Consortium Blockchain Networks
title_full_unstemmed Enabling Peer to Peer Energy Trading Marketplace Using Consortium Blockchain Networks
title_sort enabling peer to peer energy trading marketplace using consortium blockchain networks
publishDate 2019
url http://hdl.handle.net/2286/R.I.55571
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