- Constant Energy in a World of Constant Change mart Grids and Energy Storage - MicroGrids Answers for infrastructure and ci
MicroGrid? A group of interconnected loads and distributed energy resources (DER) with clearly defined electrical boundaries that acts as a single controllable entity with respect to the grid [and can] connect and disconnect from the grid to enable it to operate in both grid-connected or island mode. US Department of Energy
3-phase generator from Siemens & Halske Beginning of electrification HVAC transmission lines Synchronous AC Systems HVDC with Power Electronics Interconnected grids CCPP efficiency >60% Clean & efficient fossil age Wind turbine > 6MW Multiple Stakeholders Digitalization Energy Cells (MicroGrids) ~ 1830-1920 1920-1950 1970 2010 2012 2010 20XX
mart Grid Suite hrough innovation a comprehensive solution set GENERATION TRANSMISSION DISTRIBUTION RAIL & MICROGRIDS CONSUMPTION BIG DATA ANALYTICS, IT INTEGRATION GRID AND ENTERPRISE IT COMMUNICATION & AUTOMATION FIELD DEVICES SENSORS AND PROTECTION EMS DEMS ADMS Microgrids GRID CONTROL GRID APPLICATION Virtual Power Plants Demand Response Meter Data Mgmt. ecar Operation Center HMI COMMUNICATION AUTOMATION SENSORS PROTECTION POWER QUALITY SMART METER PRIMARY EQUIPMENT SMART TRANSMISSION SMART DISTRIBUTION RAIL & MICROGRIDS
ignificant changes in energy systems distributed energy bidirectional rgy balancing End-to-end Management Microgrids Hydrogen Storage Rail Wind Parks Onshore Diesel Generator Private Solar Storage Solutions Pumped Storage Power Plant Wind Parks Offshore Large Scale PV Plant Electrical Vehicles Smart Street Lighting Medium Voltage DC Connection Smart Transmission alancing of eneration & onsumption Load management & peak avoidance Resiliency through automatic outage prevention & restoration Smart Distribution CO2 avoidance & cost curtailment Avoidance of non technical losses Cost optimization an improved security o supply
ocus areas of innovation for the future energy system: s about technology, business models and public acceptance Managing Increasingly complex energy systems Cross regional electricity transfer and integration of distributed generation Automation Digitization (Modeling Studies / DEMS / MGMS / MDM / IEDs) Grids (Hybrid Power Generation CHP / SiPLINK - MVDC) Energy Storage (SieStorage - Battery / SILyzer Electrolyzer H2) Flexible & Efficient Power Generation (Wind / Solar / CCPP / Thermal / Biomass) Grid Stability and system efficiency Cost efficient use of conventional and renewable energy
ig Picture:onversion renewable power generation to chemical storage Generation Conversion / Storage / Transport Application Electrical AC supply from battery inverters Commercial / Re (Battery Powe Direct usage without storage Intelligent Battery Storage Electric + Fuel Cell Home oltaic's Mobility (Battery Powe H2 or NH3 storage Fluctuating electricity generation Fuel Cell or Electric Car PEM electrolysis Energy Reconv (Gas Power Gen Gas / Liquid pipeline Power Gas Fired Power Plant ntional sil fuel) Constant electricity generation Grid Methanization / Ammonianization / CO2 utilization (Sabatier Process /Habor Bosch) Industr (Battery Power / H Industry H2 Drives the convergence between energy & industry markets
hanging infeed patterns are challenging existing grid infrastructures eekly loading of a Distribution Substation in a rural area LEW-Verteilnetz GmbH 2003 and 2011 d in kw Load profile 2003 Load profile 2011 0 0 0 0 0 0 12:00 0:00 LEW 12:00 0:00 12:00 0:00 12:00 0:00 12:00 0:00 12:00 0:00 12:00 0:00
ILYZER completes energy storage portfolio and upports tailored solutions for all major industries Key Statements Large scale storage typically comprises of Pumped Hydro, Compressed Air (CAES) and chemical storage such as Hydrogen and Methane The potential to extend pumped hydro capacity is limited Hydrogen is used in many industries such as the synthesis of fuel for the petrochemical Industry and the production of Ammonia / Fertiliser for the food industry; renewable onsite hydrogen production is a promising alternative to trailer/truck/piped energy fuel supply The future CO2-optimized energy scenario will require smart solutions
0MW MicroGrid MV Network AS ENERGY SPECTRUM POWE + DEMS + MDM / SMART M + ecar + HEMS
summary e average efficiency of all coal power stations in the orld currently stands at ~31%, (Hans-Dieter Schilling Energie-Fakten). The existing SuperGrids designed 40 to 60 years ag are expanded upon year in year out have onerous technical requirements, if we were to design a grid f scratch today with the innovation available, we wou so very differently. An isolated MicroGrid connected to a SuperGrid de with today's innovation can be more than ~80% mo reliable, operate ~50% more efficiently and cost ~30 less than the equivalent SuperGrid expansions of to An Energy Cell or MicroGrid will look like a large D battery to the SuperGrid, it will participate in the who / retail energy market deriving an untapped revenue stream, whilst optimizing the peak demand cycle ac our networks. NSW's solar researchers have converted over 40% of e sunlight hitting a solar system into electricity, the ghest efficiency ever reported. attery storage at today's prices will only provide stability grid-forming in a MicroGrid as prices come down, these ttery systems will expand to offer load shifting. istributed Gas / Diesel Generators + their CHP energy nversion, is up to 85% efficient when local to the load. ybrid Generation, with Solar will offset the cost of fuel ring its operating lifetime by up to 30% if Wind is cluded, this could exceed 70%.
perational efficiency ptimization of Volt/Var conditions Impact on high-voltage Impact on medium-voltage Impact on low-voltage Voltage band violation due to decentralized power generation, e.g. renewable energy Voltage band violation due to distributed. Infeed into low-voltage or medium-voltage grid, e.g. energy. Voltage band violation and overload of grid components due to distributed infeed, e.g. renewable energy Overload of cable Distribution transformer overload Power quality problem caused by inverters
perational efficiency ptimization of Volt/Var conditions A, V, VA Var, W Regional controller Voltage P, Q P, Q Vmax VN Vmin Line le Q Consumers and distributed generation without control Semi-distributed with transformer Volt/VAR load storage control control tap control (generators, capacitor banks) smart control control combination of control devices
ault and outage management utomated switching for isolation and service restoration LessTime thanzero 300 IEC 61850GOOSE NOP Service Fault isolation location restoration Distribut
mart Polygeneration Microgrid Savona Campus ystem Overview rol: SICAM Microgrid Manager mation Equipment: SICAM TM SICAM TM SICAM ation modes: connected eutral rid supporting rid supported Features: Monitoring and control Automatic mode Load and generation forecast Energy optimization (electricity& heat) SICAM Microgrid Manager SICAM TM ical: tovoltaic plant (80 kw), 1 Battery storage (140 kwh), 3 e-car ing posts, 3 Micro-CHP (1 x 30 kwe/57 kwth, 2 x 65 20 kwth), 2 Heat storages (500 kwth), 3 Concentrated solar (1 kwe/kwth), 1 Absorption chillers (100 kwth) SICAM TM SICAM TM
cogridse autonomy of MicroGrids / Energy Cells SuperGrid SuperGrid Co-Generation
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