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NTC v4.0 / Generator Performance Standards – Information Session

This information session aims to provide stakeholders with an understanding of the changes in the NTC.v4.0 Generator Performance Standards and how it may impact their operations. The session will cover the context and basis of the changes, and facilitate discussions on stakeholder issues. Please note that this session will not address existing NTEM issues or individual project-specific issues.

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NTC v4.0 / Generator Performance Standards – Information Session

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  1. NTC v4.0 / Generator Performance Standards– Information Session 18 February 2019

  2. Welcome Objectives - What do we want out of this session? • Stakeholders understand the reasons for change and how the changes may impact on their operations. • PWC fully understands the issues and perspectives of all stakeholders to enable any further changes to the final Codes. Session Approach Expect: • Context and basis of GPS changes and associated edits to NTC and SCTC will be covered. • Discussion to be focussed around issues important to stakeholders to ensure mutual understanding of positions and points of view. • Commercial / sensitive information will be respected. • Items not dealt with during this session will be duly considered prior to finalisation of Codes and responding to stakeholder formal submissions. Don’t Expect: • NTEM existing / design issues – eg bidding, dispatch, scheduling, settlements / price, ancillary services (other than interface with GPS in a technical context) to be addressed. • Individual project specific issues to be addressed. • That every issue will be agreed / resolved.

  3. Session Overview

  4. Presentation Session

  5. Why the need for change ? • The transition to a power system dominated by non- synchronous (inverter connected) generation technologies will require these generators to provide some of the services and capability previously offered by synchronous plant. • In meeting the challenges of this transition we are mindful of: • Its not like the NEM or WEM: • Significantly smaller scale • Relativity of ancillary services to energy dispatched • Presently non mature energy and non existent ancillary services market • Renewable energy is via a single source (solar) • Non interconnected system (access to markets, diversity in energy sources – type and solar time zone) • Increasing penetration of embedded (behind the meter) uncontrolled rooftop PV poses concurrent supply balance challenges.

  6. Transition considerations 50 % renewables Energy security & reliability Customer Electricity prices

  7. Key Principles in Developing the GPS • Maintain power system and energy security • Energy source agnostic • Technically feasible • “do no harm” / “causer pays” • Be in the long term interest of customers • Automatic access standard with negotiated access provision • Leverage extensive work undertaken in the NEM

  8. Overview of the new GPS Section 3.3.5 of the NTC is predominantly aligned to NER Chapter 5 Schedule 5.2 “Conditions for Connection of Generators” to fulfil the objective of facilitating connections. • General capability requirements under normal power system conditions; and • Power system conditions that generators are required to remain in continuous operation; and • Response requirements during and following power system contingency events to support the power system. The majority of clauses are neutral to the existing NTC with the exception of the following slides which are additional / changes to the NTC.

  9. 3.3.5.1 – Reactive Power Capability What are we trying to achieve? • Maintain the existing balance of system normal reactive power contribution between generators and PWC network. How and why • Practically preserve current obligations for synchronous generators but converted to the connection point. • Similar to changes made in SA – dropping the “sliding Vee” capability (see next slide).

  10. 3.3.5.1 – Reactive Power Capability AS IS TO BE

  11. 3.3.5.4 – Response to Voltage Disturbances What are we trying to achieve? • Generators to stay online during and post disturbance and not fall off before the load. How and why • Current obligations are not adequate. • Consistent with NER S5.2.5.4 with the additional imported existing NTC requirement of withstanding zero voltage at the connection point for up to 0.5 seconds.

  12. 3.3.5.5 – Generating System Response to Disturbances Following Contingency Events What are we trying to achieve? • All generators contribute to maintaining resilience of the power system. How and why • Require generators to remain connected for a range of credible power system events. • Require generators to assist in providing short term reactive power support to the power system during and post event to support voltage levels. • Generally consistent with NER S5.2.5.5. but imports existing NTC longer fault clearing times and higher asynchronous reactive current contribution.

  13. 3.3.5.11 – Frequency Control What are we trying to achieve? • Enable the power system to maintain frequency over a wide range of operating conditions and power system events. How and why • Require all generators to have capability to provide all forms of frequency control services. • Generally consistent with NER S5.2.5.11 – but removed the NER clause only requiring generator to operate in frequency response mode when providing market ancillary services (as the AS market doesn’t exist yet). • Increased RE opportunity. • All generators treated equally. • Note – SCTC requires all generators to provide C-FCAS.

  14. 3.3.5.14 – Active Power Control What are we trying to achieve? • Ability to manage regular foreseeable energy supply events without the need to use C-FCAS or load shedding. How and why • Applying a scheduled classification to all generators to provide the level of control via obligations of a scheduled generator (capability forecast, following dispatch target). • Acknowledge that one subclause has caused confusion around ramp rate “not less (ie slower than) than 5%” – this was incorrectly placed under a dispatch target clause. It will be updated to require generators : • To reliably and accurately follow their respective dispatch target smoothly and “quickly”. • That are capable of changing their output between minimum and maximum output at a fast but stable rate. • Cloud cover for solar is not considered an abnormal event and is therefore not considered a contingency event (BAU). • Increased RE opportunity. • All generators treated equally.

  15. 3.3.5.15 – Inertia and Contingency FCAS What are we trying to achieve? • To maximise renewable energy capacity by ensuring new entrants provide some of the capabilities of generators they are displacing. How and why • Reduce inertia requirements by allowing trade off between C-FCAS and inertia. • Increased RE opportunity by minimising constraints and / or existing generators filling available solar capacity. • All generators treated equally. • Consistent with SA approvals requirements.

  16. 3.3.5.16 – System Strength What are we trying to achieve? • That the connection of a new generator does not adversely affect the ability to maintain a stable power system under any contingency or protected event. How and why • PWC will undertake a system strength impact assessment following the AEMO process as part of its connection engineering studies. • Do no harm / causer pays in regard to remedy solution. Note the optimum solution maybe either network side or generator side. • All generators treated equally.

  17. Application of GPS • Applies to NEW ENTRANT or MODIFIED existing generators. • Grandfathering arrangements for existing generators : • Generators connected prior to the approval of NTC v4.0 will be deemed to comply but will require their existing performance capability to be agreed with the Network Operator and Power System Controller and documented within an agreed timeframe. • As a minimum existing generators will need to meet the existing NTC. • The SCTC relates to market operation and power system security and may not be feasible to grandfather certain parts. Specific issues would be worked through with individual generators. • Most of the GPS requirements apply to “generating systems” and are measured at the connection point. The NER definition of a generating system (to be incorporated into the final version of NTC): “a system comprising one or more generating units and includes auxiliary or reactive plant that is located on the Generator’s side of the connection point and is necessary for the generating system to meet its performance standards” • Ability to negotiate GPS based on principles outlined in NTC 3.3.5

  18. Discussion Session

  19. Scheduled Generator Operation – Intro (slide 1/4) • Generator needs to forecast a day ahead capability (real time resubmissions are permissible for legitimate forecastable changes in “fuel”) • PWC will send generator a dispatch target for the generator to follow that is a function of capability, economics and power system security. • If unconstrained the dispatch target will follow the forecast capability subject to economic merit.

  20. Scheduled Generator Operation – Forecasting (slide 2/4) THESE ARE ANTICIPATED OPERATIONAL REQUIREMENTS (SSG) • Closer to real-time forecasts require greater accuracy and updated more frequently • 60 minutes ahead, updated at 1 minute intervals: • 60 predictions at one minute intervals with accuracy: • 95% of times - the forecasts are exceeded, • for the other 5% of times – capacity under the forecast by no greater than the lesser of 5% nameplate or 1 MW. • 12 hours ahead, updated at 10 minute intervals: • 72 predictions at 10 minute intervals, with accuracy: 90% of forecasts are exceeded. • Days ahead through market arrangements: • 30 minute intervals: 90% of forecasts exceeded • Ramping for cloud cover will be done with intent to minimise spilt energy whilst maintaining system security

  21. Cloud Event Scenario – Simplified Spilled Energy Example - 10 MW array (slide 3/4) * Single axis tracking PV array annual yield for Darwin sourced from Solar Choice website.

  22. Cloud Event Scenario – Sequence of Events(slide 4/4) Objective is to manage the supply balance during periods of rapid change in solar energy without the need to use C-FCAS or load shedding.

  23. Next Steps and Close

  24. Next Steps • Reflect on feedback from todays session. • Submissions close 25th Feb. We are very keen to hear your views on the following: • Are there technical limitations that would prevent generators from meeting the proposed technical standards? • Will costs associated with meeting the proposed technical standards be prohibitive? • Are there other concerns you have with the technical standards as proposed? • Are there other changes you would propose to improve the set of technical standards for generators? • Possibility of another round of consultation on (parts). • Finalise Code changes. • Present Codes to Utilities Commission. • Release new Codes.

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