CA2876066C - Power grid photo-voltaic integration using distributed energy storage and management - Google Patents
Power grid photo-voltaic integration using distributed energy storage and management Download PDFInfo
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- H—ELECTRICITY
- H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
- H02S—GENERATION OF ELECTRIC POWER BY CONVERSION OF INFRARED RADIATION, VISIBLE LIGHT OR ULTRAVIOLET LIGHT, e.g. USING PHOTOVOLTAIC [PV] MODULES
- H02S10/00—PV power plants; Combinations of PV energy systems with other systems for the generation of electric power
- H02S10/20—Systems characterised by their energy storage means
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- H—ELECTRICITY
- H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
- H02S—GENERATION OF ELECTRIC POWER BY CONVERSION OF INFRARED RADIATION, VISIBLE LIGHT OR ULTRAVIOLET LIGHT, e.g. USING PHOTOVOLTAIC [PV] MODULES
- H02S40/00—Components or accessories in combination with PV modules, not provided for in groups H02S10/00 - H02S30/00
- H02S40/30—Electrical components
- H02S40/38—Energy storage means, e.g. batteries, structurally associated with PV modules
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- H—ELECTRICITY
- H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
- H02J—ELECTRIC POWER NETWORKS; CIRCUIT ARRANGEMENTS OR SYSTEMS FOR SUPPLYING OR DISTRIBUTING ELECTRIC POWER; SYSTEMS FOR STORING ELECTRIC ENERGY
- H02J3/00—Circuit arrangements for AC mains or AC distribution networks
- H02J3/28—Arrangements for balancing of the load in networks by storage of energy
- H02J3/32—Arrangements for balancing of the load in networks by storage of energy using batteries or super capacitors with converting means
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- H—ELECTRICITY
- H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
- H02J—ELECTRIC POWER NETWORKS; CIRCUIT ARRANGEMENTS OR SYSTEMS FOR SUPPLYING OR DISTRIBUTING ELECTRIC POWER; SYSTEMS FOR STORING ELECTRIC ENERGY
- H02J3/00—Circuit arrangements for AC mains or AC distribution networks
- H02J3/38—Arrangements for feeding a single network from two or more generators or sources in parallel; Arrangements for feeding already energised networks from additional generators or sources in parallel
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- H—ELECTRICITY
- H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
- H02J—ELECTRIC POWER NETWORKS; CIRCUIT ARRANGEMENTS OR SYSTEMS FOR SUPPLYING OR DISTRIBUTING ELECTRIC POWER; SYSTEMS FOR STORING ELECTRIC ENERGY
- H02J3/00—Circuit arrangements for AC mains or AC distribution networks
- H02J3/38—Arrangements for feeding a single network from two or more generators or sources in parallel; Arrangements for feeding already energised networks from additional generators or sources in parallel
- H02J3/381—Dispersed generators
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- H—ELECTRICITY
- H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
- H02J—ELECTRIC POWER NETWORKS; CIRCUIT ARRANGEMENTS OR SYSTEMS FOR SUPPLYING OR DISTRIBUTING ELECTRIC POWER; SYSTEMS FOR STORING ELECTRIC ENERGY
- H02J3/00—Circuit arrangements for AC mains or AC distribution networks
- H02J3/38—Arrangements for feeding a single network from two or more generators or sources in parallel; Arrangements for feeding already energised networks from additional generators or sources in parallel
- H02J3/388—Arrangements for the handling of islanding, e.g. for disconnection or for avoiding the disconnection of power
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- H—ELECTRICITY
- H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
- H02J—ELECTRIC POWER NETWORKS; CIRCUIT ARRANGEMENTS OR SYSTEMS FOR SUPPLYING OR DISTRIBUTING ELECTRIC POWER; SYSTEMS FOR STORING ELECTRIC ENERGY
- H02J3/00—Circuit arrangements for AC mains or AC distribution networks
- H02J3/38—Arrangements for feeding a single network from two or more generators or sources in parallel; Arrangements for feeding already energised networks from additional generators or sources in parallel
- H02J3/46—Controlling the sharing of generated power between the generators, sources or networks
- H02J3/466—Scheduling or selectively controlling the operation of the generators or sources, e.g. connecting or disconnecting generators to meet a demand
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- H—ELECTRICITY
- H01—ELECTRIC ELEMENTS
- H01M—PROCESSES OR MEANS, e.g. BATTERIES, FOR THE DIRECT CONVERSION OF CHEMICAL ENERGY INTO ELECTRICAL ENERGY
- H01M10/00—Secondary cells; Manufacture thereof
- H01M10/42—Methods or arrangements for servicing or maintenance of secondary cells or secondary half-cells
- H01M10/46—Accumulators structurally combined with charging apparatus
- H01M10/465—Accumulators structurally combined with charging apparatus with solar battery as charging system
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- H—ELECTRICITY
- H02—GENERATION; CONVERSION OR DISTRIBUTION OF ELECTRIC POWER
- H02J—ELECTRIC POWER NETWORKS; CIRCUIT ARRANGEMENTS OR SYSTEMS FOR SUPPLYING OR DISTRIBUTING ELECTRIC POWER; SYSTEMS FOR STORING ELECTRIC ENERGY
- H02J2101/00—Supply or distribution of decentralised, dispersed or local electric power generation
- H02J2101/20—Dispersed power generation using renewable energy sources
- H02J2101/22—Solar energy
- H02J2101/24—Photovoltaics
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- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02E—REDUCTION OF GREENHOUSE GAS [GHG] EMISSIONS, RELATED TO ENERGY GENERATION, TRANSMISSION OR DISTRIBUTION
- Y02E10/00—Energy generation through renewable energy sources
- Y02E10/50—Photovoltaic [PV] energy
- Y02E10/56—Power conversion systems, e.g. maximum power point trackers
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- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02E—REDUCTION OF GREENHOUSE GAS [GHG] EMISSIONS, RELATED TO ENERGY GENERATION, TRANSMISSION OR DISTRIBUTION
- Y02E60/00—Enabling technologies; Technologies with a potential or indirect contribution to GHG emissions mitigation
- Y02E60/10—Energy storage using batteries
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- Y—GENERAL TAGGING OF NEW TECHNOLOGICAL DEVELOPMENTS; GENERAL TAGGING OF CROSS-SECTIONAL TECHNOLOGIES SPANNING OVER SEVERAL SECTIONS OF THE IPC; TECHNICAL SUBJECTS COVERED BY FORMER USPC CROSS-REFERENCE ART COLLECTIONS [XRACs] AND DIGESTS
- Y02—TECHNOLOGIES OR APPLICATIONS FOR MITIGATION OR ADAPTATION AGAINST CLIMATE CHANGE
- Y02E—REDUCTION OF GREENHOUSE GAS [GHG] EMISSIONS, RELATED TO ENERGY GENERATION, TRANSMISSION OR DISTRIBUTION
- Y02E70/00—Other energy conversion or management systems reducing GHG emissions
- Y02E70/30—Systems combining energy storage with energy generation of non-fossil origin
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Abstract
Description
POWER GRID PHOTO-VOLTAIC INTEGRATION USING DISTRIBUTED
ENERGY STORAGE AND MANAGEMENT
Cross-Reference to Related Application [0001] This application is related to commonly-assigned Canadian Application
[0002] This application claims priority benefit of United States Provisional Application Serial No. 61/659,227 filed June 13, 2012.
Technical Field
Background
It is therefore desirable to store PV energy for release later to offset peak demand.
[0005A] In a broad aspect, the present invention embodies a method of integrating a plurality of renewable energy sources, the renewable energy source being characterized by varying or unpredictable output with time. The method comprises providing a plurality of distributed energy storage units and coupling each of the distributed energy storage units to one or more of the renewable energy sources. A self-contained controller is provided and is communicatively coupled to each of the plurality of distributed energy storage units and to each of the renewable energy sources. The controller directs one or more of the distributed energy storage units to one of store energy from a coupled renewable energy source and dispatch energy from its storage to a distribution feeder.
The method comprises smoothing output fluctuations of one or more of the plurality of renewable energy sources by selectively providing reactive power, storing energy into, or dispatching energy from the distributed energy storage units under direction of the controller and dynamically adjusting, with the controller, a target state of change of the distributed energy storage units directed to smoothing the output fluctuations.
2a Brief Description of the Drawings
system managing multiple energy sources including at least one photo-voltaic source.
[0009A] Fig. 4 is a graphic depicting state-of charge target off-course corrections in accordance with herein described embodiments.
Detailed Description
generation capacity is to provide associated with PV sources local energy storage. the local energy storage may be adapted to buffer the variation in solar output.
The local energy storage may be adapted to each PV installation, groups of PV
installations or PV
installations may be coordinated with existing distributed energy storage systems.
This local storage, in the form of distributed units of storage or other potential configurations, could then be coordinated by a distribution system operator to allow the stored energy to be used at the most advantageous time of the day or night.
For example, solar power produced in the middle of the day in a residential community where loads are low, might best be stored for use in the early evening when loads in the residential community are high. Such "load shifting" is a high-value application, allowing the energy to be used to reduce the need for costly, additional peak power generation and other capacity improvements.
systems, regulatory requirements or incursion into the customer's premises in any way.
A primary use and the benefit of DEM-based systems as described herein is that they provide a solution for utilities to address the issues of timing and variation of PV generator output. The herein described DEM-based systems can be introduced retroactively as the level of PV penetration increases or in anticipation of PV
penetration. The units can be incrementally deployed, precluding the need for a high, initial investment
operating system could be used. The HUB 2 is primarily self-contained in that it is able to operate and dispatch energy-related operating commands and data without external components other than the DES units (and the intervening wide area communication system), plus a local communication interface 4 to the substation's feeder and transformer breakers which have their own, internal capability to sense current, voltage and other power-related data at the respective breaker. These breakers are commonly available from a wide variety of sources and are typically outfitted with prepackaged breaker controls. The breaker controls include instrumentation and metering functions that allow feeder power/metering data (voltage, current and other derived power properties) to be accessed. The data is then made available to other substation applications such as the HUB, using DNP3.
DNP3 can run over local communication media such as Ethernet or RS232 serial lines, both used widely in the substation environment. The data is provided to the HUB as pre-conditioned, averages over a few seconds of time to reduce the inaccuracy due to brief fluctuations. An example breaker control is the Schweitzer Engineering Laboratories (SEL) 351S. Although the HUB has been implemented with the above components, there are many possible ways to implement the system architecture, the goal being to bring information from the DES units, from other instrumentation such as substation feeder breakers, transformers, and from a system configuration database into an intelligent device that can allocate energy flows in to and out of the DES units based on diverse potential needs and requirements.
external automation system such as the utility's Energy Management System or Distribution Management System to automatically set the value using DNP3 and the same communication interface used by the SCADA system 5.
Although not shown on the diagram, each DES unit 1 is connected to a single phase of the feeder, on a secondary circuit, isolated from the feeder by a distribution customer transformer not shown. The DES units 1 are distributed across multiple phases and multiple feeders. A potential implementation will see as many as a hundred or more DES units connected to the various phases on any one feeder.
In the illustrated embodiment, the customer transformers may be connected phase-ground, although with minor transformations the system could easily work with phase-phase connected transformers. It should also be noted that a three-phase DES unit 1 could be built, consistent with the principles disclosed herein.
Such a unit would typically serve a three-phase load such as a commercial or industrial customer, and would have the added benefit of being capable of improved feeder balancing since power could be shifted back and forth between phases.
smoothing and PV integration functions for many reasons. These include the DES
unit's inherently distributed location in the grid, their storage and high-speed, 4-quadrant real and reactive power control/conditioning capabilities, and their ability to be deployed near the solar generation sources. Deployment of the DES unit fleet can be staged as penetration of PV increases. Another benefit is the ability of the DES units to go into an "islanded" control mode, disconnecting customers from the utility power source and running the loads from the battery system if voltage exceeds allowable extremes. Since the units are between the customer meter and the distribution substation, the utility has the ability to directly control the operation of the units based at least in part on system needs.
1. Target State of Charge (SOC). Battery stored energy level, expressed in percent SOC, that the power smoothing algorithm should attempt to maintain. During power smoothing, the SOC will tend to drift up or down as the CES Unit 2 responds to varying PV source 18 output. As the SOC drifts away from the target, the local algorithm slowly forces energy into or out of the battery back towards the Target SOC. The further the SOC drifts away from the target, the more aggressive the algorithm becomes at compensating.
2. Emergency Voltage Control (high and low) voltage limits. If the voltage begins to fall outside this specified range, the unit will use reactive power (Volt-ampere reactive, VARs) to maintain voltage within the limits.
Additional, local limits are provided such that if voltage wanders even further out of range and cannot be corrected, the DES unit 2 will island to protect its customers.
units 1 may provide energy and capacity management while designated other DES units 1 may be designated PV Smoothing units. Although, it is understood given operating conditions the units may be called upon to provide additional the alternate functions.
Unit 1 is that the further the battery state of charge (SOC) is away from the desired value, the more power is allowed to flow into or out of the battery, subject to suitable limits of various forms.
Exemplary Implementation
= Scheduled PV Energy Time Shifting. This mechanism relies primarily on a fixed schedule related to the theoretical presence of solar energy and the expected hourly load profile = Irradiance Driven PV Energy Time Shifting; Real-Time, hour & day forecast input (data source TBD). This mechanism improves the scheduled PV Energy Time Shifting algorithm by utilizing outside knowledge such as weather forecasting information.
= Irradiance Driven PV Energy Time Shifting with local measurement (sensor input TBD). This method improves the scheduled PV Energy Time Shifting algorithm by utilizing various sensing methods to locally measure incoming solar energy.
units 1 as located or collocated with PV distributed resources and to designate other DES units 1 as serving only energy or capacity management functions. This allows the DES unit's 1 smoothing function to be utilized where PV-related power smoothing is required, while allowing more effective use of the storage and inverter where PV smoothing is not required. When combined with the PVI enhancements, the DEM's energy dispatch features, in summary, consist of the following:
System Fleet (Substation-level) functions to support the Utility's energy management system (EMS) and explicitly to address external EMS
requirements = Substation-level request for capacitive, reactive power output (explicitly exclusive of PVI units) with optimized power factor at the feeder level = Substation-level request for real power demand restriction (peak shaving) respecting distribution capacity constraints and preferentially utilizing both PVI stored energy and PVI-available demand.
= Substation-level (enable/disable) control over the use of PVI-configured Units to smooth power and store solar energy when available and to discharge that energy at preferred times (load-shifting).
Substation feeder and transformer-level functions to support:
= Reactive power compensation to achieve unity power factor at each feeder breaker, coordinated with EMS requirements and excluding PVI-configured Units.
= Real power capacity mitigation at the feeder and transformer breakers coordinated with PVI-configured units.
Group (Sub-feeder)-level control over coordination of DES units 1 to support all of the features above:
Where the discharge schedules may be either:
= Fixed discharge schedule without regard to explicit capacity or energy management constraints.
= Demand-limited discharge schedule with prioritized control over peak shaving for EMS and capacity constraints.
Where the charge schedules may be either:
= Fixed charge schedule without regard to explicit capacity or energy management constraints.
= Demand-limited charge schedule with prioritized control over peak shaving for EMS and capacity constraints.
and where PVI schedules may be calling for coincident PV smoothing, storage of PV energy or discharge of stored PV energy.
Operating Modes, Commands and Rules 1) All variations of the PV integration (PVI) algorithms can be treated somewhat similarly to the existing scheduled fixed charge or discharge algorithms:
a. Grouped Scheduling. The algorithm is applied to CES Units based on their membership in a Group that has the PVI algorithm specified for use. In the initial implementation of the DEM, the definitions of all Groups had provisions for referencing a wide variety of schedules, allowing one schedule to be selected for group charging and a separate schedule to be selected for group discharge. With the addition of PVI, each Group will have provisions for a third schedule for PVI.
b. PVI Schedules are Overlapping and Dynamic. Without PVI, it can easily be determined if schedule conflicts exist because all times are invariant to unpredictable events. With PVI, both the times of solar availability from the lunar point of view, and the availability of solar energy from the atmospheric point of view, will vary from day to day.
Therefore PVI schedules are allowed to coexist (overlap) with all other schedules. The overlap between the schedules is important, since it provides backup schedules for utilization of the distributed storage and inverters when PVI is not required or the sun is not out.
For the present version of software, Dashboard-level operator overrides allow the PVI operation to be enabled or disabled based upon observed solar availability. In future versions, solar availability may be determined automatically.
c. Active PVI Schedules. A PVI schedule is considered to be active from the effective starting time (either fixed start time or lunar-calculated sunrise) in its schedule to the end of its schedule, assuming:
i. A PVI schedule is specified for the Group PVI is enabled for the Group PVI is enabled for the system as a whole.
d. Priority of Active PVI Schedules. When a PVI schedule is active, it overrides the direct effect of both discharge and charge schedules on all CES Units in the Group. The other schedules may have an influence over the energy flow into the Unit but the Unit will always be performing its PV smoothing function governed by the DEM's PV
smoothing target SOC and commanded voltage bounds.
e. CES Unit Power Smoothing Mode. If a CES Unit is in a Group with an Active PVI Schedule, the Unit will be commanded to perform voltage-limited PV smoothing with an SOC target. That is, instead of being sent commands explicitly setting target real and reactive power output levels, on every control loop iteration the Unit will be sent upper and lower voltage limits (setpoint along with +/- % differentials) and an SOC Target in percent.
f. PVI Schedule Inactive. Any time that the PVI schedule is inactive, the Group's operation will be governed by behavior of the other charge/discharge schedules and algorithms.
g. Group/Fleet Availability. Consistent with the PVI operation described above, the PVI schedule's applicability will be controlled by two, separate enables and disables, both of which are dashboard-resident State variables. One enable will be part of the Group configuration, and one will be associated with the fleet (CES DEM
Dashboard). If PVI is disabled, the Fleet/Group will participate in capacity energy dispatch as before. For a Group's PVI schedule to be active, both the Group enable and the system enable must be true (in the "Enabled" state).
h. CES Unit Availability. Each CES Unit may be disabled via remote request, local request, or by using a physical selector switch (Disconnect control mode). If a CES Unit is in a PVI Group with an active schedule, but is disabled, it will not respond to the PVI
commands. It is therefore not necessary to specifically enable/disable PVI participation at a CES Unit level.
Validation of Algorithm Selection between Groups. In general, it would not make economic sense to have one group of CES units charging while another group is discharging. However, due to unusual constraints, such as one feeder overcapacity and another feeder under-capacity, with both connected to active PV sources, such a circumstance might occur. The following rules dictate how these potential conflicts are managed in the absence of capacity threshold violations:
i. Scheduled Fixed Charge/Discharge. These groups will generally be used to handle unusual circumstances in coordination with other groups set up for demand-limited charge/discharge. The conflict should be allowed on the assumption that the user "knows best" as to how to set up the system.
ii. Demand-Limited Charge/Discharge. From the standpoint of validation of the configuration, potential conflicts cannot be determined at configuration time, and are therefore allowed.
Other types of conflict resolution that must be performed in real-time are discussed below in the section on Coexistence of PVI with Other Capacity Management Functions.
i. Fixed Time PVI Parameters. For the initial version of the PVI
algorithm, all scheduled times and SOC targets are predetermined (configured) in static, absolute terms. The times are in time of day or duration, both expressed in HH:MM with the same scheduling consideration and features for Day of Week and Holiday as is provided for existing energy dispatch scheduling. SOC Buffers are in %. The algorithm determines Maximum and Minimum SOC Targets from the configured buffers and other settings such as Islanding Reserve and Headroom Reserve. In the future it is possible that the configured times might be adjusted through various automated means.
j. PVI Fixed Time Charge/Discharge Profile. For all PVI algorithm variants, a trapezoidal charge/discharge energy dispatch profile is specified. However, in contrast to scheduled fixed charge or discharge algorithms, the profile drives energy flow (into or out of the battery) by guiding the battery state of charge (SOC) up or down. The fully-configured profile is shown graphically in Figure 1 below:
k. For PVI schedules, the parameters that configure the PVI algorithm apply to the Group as a whole, and cannot be assigned on a Unit by Unit basis. The PVI Schedule parameters are defined as follows:
i. Start Time. Time of day when the PVI algorithm should be activated. This time will tend to be the approximate time of sunrise.
ii. Sunrise Smoothing Duration. The length of time during which the PVI algorithm should be allowed to run without changing the SOC target. Specified as a time duration in minutes.
PV Storage Duration. This is the length of time from the start of the scheduled period that SOC should be adjusted (or ramped-up) to store the available PV energy, with the goal being to reach the SOC target value for the group at the end of the ramp up period.
iv. PV Hold Duration. Elapsed time during which the SOC target should be held at its maximum value without change. This time duration allows the PV energy to be held while continuing to perform PV smoothing while waiting for a preferred time to begin discharge.
v. PV Release Start Time. The time of day when the PVI
algorithm will begin discharging the battery to release stored PV Energy.
vi. PV Release Duration. This is the length of time during which the SOC should be reduced to reach the SOC minimum PV
integration value at the end of the time period. In future versions, this time could be defined in different ways. For example, it might be adjusted based upon solar incidence. Or it might be fixed to a time of day associated with the end of peak loading.
vii. Sundown Smoothing Duration. This is the length of time during which the SOC should be held at its minimum target value to allow for smoothing near the time of sundown.
viii. Minimum SOC Smoothing Buffer. This is the amount of energy, in % SOC, that should be left in the battery to provide adequate reserve for the PV smoothing algorithm both before the sun comes out and near sundown, typically after discharge (PV energy release) completion.
ix. Maximum SOC Smoothing Buffer. This is the amount of energy, in % SOC, that should be left out of the battery to provide adequate reserve for the PV smoothing algorithm as the battery approaches maximum PV energy storage.
1. CES Unit Control. From the time when the algorithm begins running (Start Time), until the end of the run (after the Sundown Smoothing Duration has expired), the CES Unit will be continuously commanded by the DEM to operate in Power Smoothing mode.
CES Unit Energy allocation is managed by the DEM with cooperative participation by individual CES Units. Islan ding Reserve, Depleted Battery Reserve, and Headroom Reserve are CES Unit settings since the CES Unit has some autonomous functions which utilize those settings.
Minimum and Maximum SOC Smoothing Buffer are not required as CES
Unit settings, however, since they are implicit in the Target SOC
communicated from the DEM to the CES Unit.
(informative note) In the case of the fixed charge and discharge schedules used for the other capacity management operating modes, the ramping simply allows demand to transition smoothly up and down. In the case of PV
integration, the ramping is not of demand but of battery SOC, and the ramping is fundamentally what drives energy into or out of the storage system. Holding of SOC at a given value simply defines a period of time when the SOC target should be held at that level for an extended period of time, allowing PV smoothing but preventing significant storage or release of solar energy.
m. Effective SOC Target calculation. For many reasons, at every evaluation interval, the present SOC of each battery could be at any level from 0% to 100% of maximum. For example, a unit could have just been put online after being disabled. Or, the unit could have just returned from an islanded circumstance, or the system may have just been reconfigured, etc. The logic must always drive the SOC toward the desired value following the trapezoidal shape. Guiding criteria are that we want to charge the batteries from solar energy and not from the grid and we want to always try and provide for an adequate SOC
to allow the smoothing to function to work whenever it's enabled.
The following calculations handle these requirements consistently.
See "Error! Reference source not found." for a graphic description of how the SOC Target is calculated based upon the present SOC at the time of evaluation, and "Error! Reference source not found." for a graphic description of how the SOC in the battery is driven by the logic below during off-course corrections:
i. Present SOC above Maximum SOC Target prior to PV
Release. The SOC Target should be set to the Maximum SOC
Target.
ii. Present SOC below Minimum SOC Target prior to PV
Storage. The SOC Target should be set to the Minimum SOC
Target. If neither this condition nor the previous condition is true, the other calculations below should be performed.
iii. Residual Storage During Sunup Smoothing. Residual energy stored in the CES Unit should be held rather than released prior to the PV Storage time interval. To accomplish this, the SOC Target should be held fixed during this time interval to reduce the possibility of having energy drifting into the storage system over an extended period of time due to smoothing. On startup after the first reading of the SOC from each Unit, the target SOC should be established for Sunup Smoothing as either the Minimum SOC Target or the present SOC whichever is greater. That target should then be held fixed throughout the sunup smoothing time period. Note: The PVI algorithm remains inactive and uninitialized for any CES Unit until the Unit responds to a DNP poll with valid data. After that point, if a communication error prevents updating of the Unit's status or data, the previous data read is used.
iv. Target SOC during Sundown Smoothing. During this entire time period, the Target SOC should remain fixed at the Minimum SOC Target value.
v. Target SOC during PV Hold. During this entire time period, the Target SOC should remain fixed at the Maximum SOC
Target value unless the Present SOC is below the Minimum SOC
Target. If the Present SOC is below the Minimum SOC Target, then the Target SOC should remain fixed at the Minimum SOC
Target until the end of Sundown Smoothing. Note that if the Present SOC is ever found to be below the Minimum SOC Target after PV Storage is completed, it suggests that solar energy input is not sufficient to provide significant energy storage. In this case the goal is to store just enough energy in the battery to support solar smoothing rather than time-shifting.
vi. Target SOC during PV Storage. If the PVI algorithm is in PV
Storage mode, the Target SOC is calculated assuming a linear SOC ramp to reach the Maximum SOC Target by the end of the PV Storage interval. The calculation is:
Target SOC = Present SOC + (Maximum SOC Target -Present SOC) / (Elapsed Time to Reach Maximum SOC
Target / Evaluation Interval Time).
1. For the calculations above, if the Present SOC is greater than the Maximum SOC Target, the Target SOC is set to the Maximum SOC Target, otherwise 2. For the calculations above, if the Present SOC is less than the Minimum SOC Target, then substitute the Minimum SOC Target for the Present SOC, otherwise 3. If the Present SOC is less than the previous SOC read from the CES Unit during PVI, the value used for the present SOC is the previous SOC read from the CES Unit.
Note: The purpose of the last constraint above is to insure that the SOC target always moves in a positive direction toward the storage target.
vii. Target SOC during PV Release. If the PVI algorithm is in PV
Release mode, the Target SOC is calculated assuming a linear discharge to reach the Minimum SOC Target by the end of the PV Discharge interval. The calculation is:
Target SOC = Present SOC - (Present SOC - Minimum SOC Target) / (Elapsed Time to Reach Minimum SOC
Target / Evaluation Interval Time).
1. For the calculations above, if the Present SOC is less than the Minimum SOC Target, the Target SOC is set to the Minimum SOC Target.
2. If the Present SOC is greater than the previous SOC read from the CES Unit during PVI, the value used for the present SOC is the previous SOC read from the CES Unit.
Note: The purpose of the last constraint above is to insure that the SOC target always moves in a negative direction toward the discharge target.
n. Flexible use of this trapezoidal profile is supported, allowing one or more of the solar integration time intervals to be set to zero. This would permit, for example, Scheduled Fixed Discharge to be used in lieu of PV release, if the PV Storage time interval was non-zero, but the PV Release time interval was zero. However, some combinations are invalid because they would trigger sudden, large energy swings.
Allowable combinations of durations are shown in the table below:
Sunrise PV PV Hold PV Release Sundown Smoothing Storage Smoothing Zero Non-zero Zero Zero Zero Zero Non-zero Zero Non-zero Zero Zero Non-zero Zero Non-zero Non-zero Zero Non-zero Non-zero Zero Zero Zero Non-zero Non-zero Non-zero Zero Zero Non-zero Non-zero Non-zero Non-zero Non-zero Non-zero Zero Zero Zero Non-zero Non-zero Zero Non-zero Zero Non-zero Non-zero Zero Non-zero Non-zero Non-zero Non-zero Non-zero Zero Zero Non-zero Non-zero Non-zero Non-zero Zero Non-zero Non-zero Non-zero Non-zero Non-zero Coexistence of PVI with Other Capacity Management Functions Peak-shaving versus PVI energy management functions tend to be inherently different. Peak shaving functions address various feeder, substation and energy management capacity and generation limitations inherent in the distribution system. PVI functions address PV-related, localized voltage and power quality requirements, further allowing the solar energy to be stored and used later to reduce peak generation requirements or carbon footprint (load-shifting).
However, both peak shaving and PVI-designated CES Units can be effectively utilized in combination. For example, in a heavily-urbanized area there might be significant substation capacity constraints while at the same time there might also be certain selected residential areas with significant PV penetration. To address the needs of these hybrid systems, the DEM must coordinate the simultaneous operation of CES
Units running both types of algorithms.
Proper coordination of the two types of energy management functions involves conflict resolution between charge and discharge requirements that might be occurring simultaneously. Simultaneous charging and discharging of units affecting the same part of the distribution system is considered a conflict due to the combined energy loss of the energy transfers into/out of the battery system, plus the unnecessary effect on the cycle life (maximum number of charge/discharge cycles) of the battery.
For example, it is considered a conflict of fleet operations if a CES Group on a feeder, configured for peak shaving is requesting discharge while another Group configured for PVI is in PV Storage mode, charging its battery. It is anticipated that the CES
Fleet operator will carefully schedule fleet operations to minimize conflicts between peak shaving and PV Integration of storage resources handled by a single DEM.
It is possible that conflicts will occur, however, so a simplistic approach to dealing with potential conflicts is desired. Further, even if peak shaving is not scheduled to be active, an associated limit (substation, transformer or feeder overcapacity) could be exceeded for some unexpected reason. If some CES Units configured for PVI are requesting charging, it would be highly undesirable to unnecessarily burden the distribution system with the additional load. Instead, the units should not charge from PV and all of the PV power should be available to the system. Ideally, under such conditions, stored energy in the PVI units should be discharged to reduce the system-level overload, but this can be very complex to fully-achieve. Proper coordination of the two types of energy management functions also involves coordination to insure that the PV smoothing algorithm in PVI-designated CES
units is always enabled and active, as scheduled, during hours of daylight, even if a capacity constraint is calling for discharge.
In summary, there are some fundamental principles that can be applied to these hybrid peak shaving/PVI systems:
= PVI-designated units must always have their smoothing functions, with associated energy storage buffers, enabled and operating during hours when PVI is scheduled. This scheduling will inherently take into account the fact that the sun rises in the morning and sets in the evening. Correspondingly, PV smoothing is not required at night when there is no sunlight.
= It does not make sense, from the economic point of view, for any of the capacity management algorithms to be calling for units on a feeder to be discharging, while at the same time, other units on that same feeder and phase are in PV Storage mode, increasing effective demand on the feeder.
Similar conflicts could occur with substation transformer overcapacity, or an external request for demand reduction. In essence, an algorithmic conflict is one that leaves some units charging while other units are discharging, when the conflict can be prevented by reducing the absolute magnitude of the demand comparably on both units or groups.
Peak Shaving - PVI Coordination Algorithm The following algorithm provides a simplified way to coordinate the peak shaving and PVI algorithms to prevent charge/discharge potential conflicts.
1) A CES Unit is designated to be in PVI mode if a. It is in Manual Override/PVI Mode, or b. It is in Automatic mode, and the System PVI and Group PVI Mode is enabled, and its Group's PVI schedule is active (based on day of week and time versus scheduled times and durations).
2) A CES Unit in PVI mode will always be commanded to do PV Smoothing without regard to any possible conflicting system requirements for peak shaving-related storage or discharge. Thus, further definition of commands sent to the unit in PVI mode relate to commanding the Unit's Target SOC
which may be influenced by peak shaving system requirements.
3) A PV Coordination Storage Event (PV storage conflict) is present for a given CES Group in PVI mode under the following circumstances:
a. The Group is active (it has CES Units assigned). Note that a unit can be manually overridden and commanded in or out of PVI mode.
Individual Unit status should not influence the Group status.
b. The PVI schedule time is within the PV Storage or PV Hold Time Intervals, and i. A non-zero External Three-phase Demand Limit is present, and 1. At least one CES Unit in the fleet, operating in Peak Shaving mode, was being commanded to discharge to meet the limit on the last control cycle, or 2. The DEM's total load under its control (presently, the load at the substation transformer) is above or equal to the External Three-Phase Demand Limit.
ii. Or a non-zero Transformer three-phase demand limit is present and, 1. At least one CES Unit in the fleet on the given phase was being commanded to discharge to meet the limit on the last control cycle, or 2. The load at the substation transformer on the given phase is above or equal to one third of the Transformer Three-Phase Demand Limit.
iii. Or a non-zero Feeder three-phase demand limit is present and, 1. At least one CES Unit in the fleet on the feeder, on the given phase was being commanded to discharge to meet the limit on the last control cycle, or 2. The load at the feeder breaker on the given phase is above or equal to one third of the Feeder Three-Phase Demand Limit.
4) If a PV Coordination Storage Event is active, all units in the affected Group operate in PV Release operating mode, with the target SOC calculated for a discharge that ends at either the end of the PV Release time interval, if scheduled, or otherwise at the end of PV Hold. The Target SOC is calculated assuming a linear SOC Target ramp to reach the Minimum SOC Target by the 24end of the interval. The calculation is:
Target SOC = Present SOC - (Present SOC - Minimum Target SOC) / (Elapsed Time to Reach Minimum SOC
Target! Evaluation Interval Time).
Note: If the Present SOC is less than the Minimum SOC
Target, it is set to the Minimum SOC Target.
Claims (14)
providing a plurality of distributed energy storage units and coupling each of the distributed energy storage units to one or more of the renewable energy sources;
providing a self-contained controller and communicatively coupling the controller to each of the plurality of distributed energy storage units and to each of the renewable energy sources;
directing from the controller one or more of the distributed energy storage units to one of store energy from a coupled renewable energy source and dispatch energy from its storage to a distribution feeder;
smoothing output fluctuations of one or more of the plurality of renewable energy sources by:
selectively providing reactive power, storing energy into, or dispatching energy from the distributed energy storage units under direction of the controller, and dynamically adjusting with the controller a target state of charge of the distributed energy storage units directed to smoothing the output fluctuations.
schedule photo-voltaic (PV) energy time shifting;
irradiance driven PV energy time shifting based upon real-time, hour and day forecast data; and irradiance driven PV energy time shifting with local measurement.
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| PCT/US2013/045371 WO2013188517A2 (en) | 2012-06-13 | 2013-06-12 | Power grid photo-voltaic integration using distributed energy storage and management |
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