Distribution Network Demand and Its Uncertainty

This chapter presents some advanced tools for low voltage (LV) network demand simulation. Such methods will be required to help distribution network operators (DNOs) cope with the increased uptake of low carbon technologies and localised sources of generation. This will enable DNOs to manage the current network, simulate the effect of various scenarios and run load flow analysis. In order to implement such analysis requires high resolution smart meter data for the various customers connected to the network. However, only small amounts of individual smart meter data will be available and such data could be expensive. In likelihood, smart meter data is only going to be freely available at the aggregate level. Hence, in general, to implement LV network tools, customer loads will need to be simulated based on the assumption of limited amounts of monitored data. In addition, due to the high volatility of LV electric distribution networks, demand uncertainty must also be captured within a simulation tool. In this chapter, a number of methods are described for simulating demand on low voltage feeders which rely only on relatively small samples of smart meter data and monitoring. Firstly, a method called ‘buddying’ is described for assigning realistic profiles to unmonitored customers by buddying them to a customer who is monitored. Secondly, a number of methods are presented for capturing the uncertainty on the network. Finally the uncertainty models are incorporated into the buddying method and implemented in a load flow analysis tool on a number of real feeders. Both the buddying and the uncertainty estimation are presented for two different cases based on whether LV substation monitoring is present or not. This illustrates the different impacts of monitoring availability on the modelling tools. This chapter demonstrates the presented methods on a large range of real LV feeders.

[1]  V. Ismet Ugursal,et al.  Modeling of end-use energy consumption in the residential sector: A review of modeling techniques , 2009 .

[2]  Paolo Attilio Pegoraro,et al.  Effects of Measurements and Pseudomeasurements Correlation in Distribution System State Estimation , 2014, IEEE Transactions on Instrumentation and Measurement.

[3]  Neal Wade,et al.  Design and analysis of electrical energy storage demonstration projects on UK distribution networks , 2015 .

[4]  Michael Conlon,et al.  Characterising domestic electricity consumption patterns by dwelling and occupant socio-economic variables: An Irish case study , 2012 .

[5]  A. Raftery,et al.  Strictly Proper Scoring Rules, Prediction, and Estimation , 2007 .

[6]  Gerard J. M. Smit,et al.  Integrating LV network models and load-flow calculations into smart grid planning , 2013, IEEE PES ISGT Europe 2013.

[7]  Tao Hong,et al.  Probabilistic electric load forecasting: A tutorial review , 2016 .

[8]  Alejandro Navarro-Espinosa,et al.  Assessing the benefits of meshed operation of LV feeders with low carbon technologies , 2014, ISGT 2014.

[9]  Matthew Rowe,et al.  The Real-Time Optimisation of DNO Owned Storage Devices on the LV Network for Peak Reduction , 2014 .

[10]  Georgios Giasemidis,et al.  A hybrid model of kernel density estimation and quantile regression for GEFCom2014 probabilistic load forecasting , 2016, 1610.05183.

[11]  Stephen McArthur,et al.  A Review and Synthesis of the Outcomes from Low Carbon Networks Fund Projects , 2016 .

[12]  G. Rizzoni,et al.  A highly resolved modeling technique to simulate residential power demand , 2013 .

[13]  Matthew Rowe,et al.  Mathematical solutions for electricity networks in a low carbon future , 2013 .

[14]  Peter Grindrod,et al.  Analysis and Clustering of Residential Customers Energy Behavioral Demand Using Smart Meter Data , 2016, IEEE Transactions on Smart Grid.

[15]  Phil Blythe,et al.  A probabilistic approach to combining smart meter and electric vehicle charging data to investigate distribution network impacts , 2015 .

[16]  Mike Hazas,et al.  The significance of difference:understanding variation in household energy consumption , 2011 .

[17]  Gerard J. M. Smit,et al.  Impact of peak electricity demand in distribution grids: A stress test , 2015, 2015 IEEE Eindhoven PowerTech.

[18]  Christoph Flath,et al.  Cluster Analysis of Smart Metering Data , 2012, Business & Information Systems Engineering.

[19]  Peter Grindrod,et al.  A new error measure for forecasts of household-level, high resolution electrical energy consumption , 2014 .

[20]  Danica Vukadinovic Greetham,et al.  Long term individual load forecast under different electrical vehicles uptake scenarios , 2015 .

[21]  J. Widén,et al.  A high-resolution stochastic model of domestic activity patterns and electricity demand , 2010 .

[22]  A. R. Wallace,et al.  Optimal power flow evaluation of distribution network capacity for the connection of distributed generation , 2005 .

[23]  Danica Vukadinovic Greetham,et al.  Electric vehicles and low-voltage grid: impact of uncontrolled demand side response , 2017 .

[24]  Peter Grindrod,et al.  A genetic algorithm approach for modelling low voltage network demands , 2016, 1612.06833.

[25]  V. Krsman,et al.  Pre-processing of pseudo measurements based on AMI data for distribution system state estimation , 2016 .

[26]  R. Tibshirani,et al.  An introduction to the bootstrap , 1993 .

[27]  David Infield,et al.  Domestic electricity use: A high-resolution energy demand model , 2010 .