Post on 15-Dec-2015
Through a selective Smart Metering towards Smart Grids
17. – 18. 4. 2013 KCMTE Ing. Igor Chrapčiak
Smart Grid is no target but an instrument
The World is changing...
New conditions, changes and interrelations:
Population growth: Movement of population to cities, increased standard of living, demands for comfort, growing energy intensity followed by crises
Environment pollution, high production of CO2, smog and exhaust gases, undesirable health consequences, global warming
High dependence on fossil fuel sources and their possessors
Big centralised power sources, long-distance transmission lines, risk of loss of value of vast territories and loss of many people at outages, risk of "blackouts"
Renewable energy sources, local and time-dependent oversupplies and shortages of power
Planned e-mobility
Undesirable new phenomena
in power grids
Investment and economic interests
...
Development in Power Industry – Smart Grid
Efforts of EU countries to adopt reasonable measures for making energy processes more effective with regard to the environment, safety and stability of power transmission, controllability, minimisation of operating costs, efficiency, customer satisfaction… Rules 20/20/20: Smart Grid notion
Smart Production (Smart power generation), consisting in addition of smaller distributed energy resources, e.g. Renewable Energy Sources (RES) or Combined Generation (of power and heat - CoGen), to classical big power stations…
In short: Decentralised power generation with a suitable mix of sources
Smart Distribution, consisting in recognition and control of grid conditions at all voltage levels and transformer stations, with two-way flows of power in lines, active self-control ability, optimised transfer, reduced losses, increased efficiency…
Smart Consumption, consisting in optimisation of power consumption, including households, Smart appliances, control, e-mobility, Smart Home, Smart Cities
Slovak Republic - Act on Power Industry No.251 of 31.7.2012
§ 42 Intelligent Metering Systems (IMS)
The Ministry, in cooperation with the Authority, Operators of regional distribution systems and other participants in the market with power, shall elaborate the Analysis of economic benefits resulting from the implementation of various versions of Intelligent Metering Systems (IMS) and costs for their procurement, installation and operation for appropriate categories of end consumers
On the basis of such Analysis, it determines the categories of end power consumers and imposes the duty to implement IMS in at least 80% of consumption points pertaining to each individual category
Participants in the market with power shall collaborate with PDS in exerting cooperation at the installation and operation of IMS by the way and under the conditions as stipulated in Sect. § 95.
It has been decided…
The Ministry (MHSR) decided in September 2012, in cooperation with ÚRSO and on the basis of analyses, that it will be economically effective under current conditions to implement IMS at all consumption points with the annual power consumption higher than 4,000 kWh.
The overall annual power consumption at those consumption points represents approx. 53% of the total consumed power at the LV level and those consumption points represent approx. 23% of the total consumption points at the LV level.
It results from the pilot projects and related data concerning real costs and benefits, with consideration of possible development of respective technologies, that the actual scenario may have to be updated after two years.
Further progress and functionalities of the system shall be specified by MHSR in cooperation with an expert group in compliance with Sect. § 95 of the Act No.251/2012 (not later than on 30. 6. 2013).
How to do that? Act on Power Industry No.251 of 31.7.2012
Sect. § 95 Authorising provisions h) The Ministry shall issue a generally binding legal regulation
which will include the following items concerning the implementation and operation of IMS according to Sect. § 42:
1. Criteria and conditions for the implementation of IMS for the individual categories of end power consumers,
2. Deadlines for the implementation of IMS for the individual categories of end power consumers at which it seems to be reasonable to implement IMS within the next 10 years,
3. Requirements for the cooperation of individual participants in the market with power in the installation and operation of IMS,
4. Required technical parameters of IMS, 5. Requirements for data transfers and cooperation of individual systems, 6. Method of access to data collected by IMS from the side of individual
participants in the market with power,
Other relations – Act No. 251/2012 Optional regulation of power consumption
Sect. § 31 Rights and duties of Distribution System Operator (DSO)
p) The Distribution System Operator is obliged to install Intelligent Metering Systems in accordance with Sect. § 42
q) The Distribution System Operator is obliged to ensure the installation of appropriate equipment for the continuous metering of consumed power with possible remote reading from respective point of consumption, namely at the moment of replacement of designated electricity meter, and for a new point of consumption in case of fulfilment of respective conditions in accordance with market rules*.
f) The Operator has right to equip respective point of consumption with a technical device regulating the quantity of consumed power
Other relations – Act No. 251/2012 Measurement of power quality parameters
§ 31 Rights and duties of Distribution System Operator (DSO)
Subsect.1, Par.e, Subpar.8., Subpar.9.: Distribution System Operator has right:
to reduce or discontinue power distribution to an inevitable extent and for an inevitable period of time, without liability for indemnification except of those cases when a damage has arisen due to the fault of Distribution System Operator, when
. 8. such power has been consumed by facilities which influence the quality and reliability of power supply and when respective power consumer has not ensured the limitation of such influences by any available technological means
9. such power has been generated by facilities which influence the quality and reliability of power supply and when respective power producer has not ensured the limitation of such influences by any available technological means.
(Expected) secondary legislation to the Act No.251 - regulations to implement this Act
Executive regulation for Intelligent Metering Systems (2013)Definition of goals, requirements and parameters for the implementation (of IMS), definition of pilot project, safety requirements, requirements on national communication standards, guarantees for interoperability
Regulation ÚRSO (No.3/2013) which determines the method, extent and structure of provision of data on
power consumption to the power consumer at the point of consumption and storage of such data
Regulation No.24/2013 Market rules which determines the collection and administration of data on power consumption
and related invoicing performed by the organiser of short-term market with power
Regulation No.275/2012 ÚRSO of 5. 9. 2012 which determines the standards of power quality
Metrology, safety, protection of personal data...
Our principal goals – IMS+
Analysis of output and qualitative parameters of LV grid, analysis of losses, revealing of reserves
Prevention of fault conditions and outages
Improved control and shifting of peak power consumption
Equalisation of balance between power consumption and generation in the area of interest
Resolution of issues connected with Renewable Energy Sources (RES): instability, surplus or shortage of power which is often generated in an unsuitable period of time, depending on hardly predictable external influences
Reduction and optimisation of power transmission
Improvement of qualitative power supply parameters
Reduction of losses and improved efficiency
How to be Smart?
1. No grid can be Smart or no grid can even exist without Smart Metering.
2. It would be ineffective or almost useless, if we implement Smart Metering without actually building up Smart Grid.
3. All that would be useless,if the metering is incorrect and incomplete
Daily profiles of power generation andconsumption from fotovoltaic sources
There are efforts to equalise the balance of power generation [green curve] and consumption [blue/red curve] or to "shave" peaks of consumption.
Peaks of power generation and consumption occur at different times
Elimination of negative influences of Renewable Energy Sources (RES)
(USUAL) SUPPLY OF DTS FROM SUPERIOR GRID (HV)
DISTRIBUTIONTRANSFORMING STATION (DTS)
USUAL HOUSEHOLD
CONSUMPTION
Hot water heatersHeat storageappliancesBatteries (for e-vehicles)Dishwashing / washing machines, tumble dryers
UNCONTROLLABLE
Municipality, locality
CONTROLLABLE
CONSUMPTION POWER GENERATION (RES)Small Fotovoltaic
PG sources
Given configuration of PG sources and power consumption induces a non-standard flow of power from LV grid to HV grid in peaks (up to 65% of the output)
This negative impact could be possibly eliminated by switching-on suitable heat storage appliances or heaters
A stand-by household - an example
Appliance items % of non-use P S A(P)/year Sum A(S)/year
[W] [VA] [kWhr] [€] [kVAhr]
"digital clocks" 2 100% 10 20 175 21 350
Satellite receiver 2 60% 12 20 126 15 210
PC set 2 50% 10 25 88 11 219
notebook 1 60% 5 15 26 3 79
chargers 5 80% 2 20 70 8 701
LCD TV 2 60% 1 22 11 1 231
HiFi player 2 90% 15 30 237 28 473
DVD/CD record player 1 90% 10 15 79 9 118
Total 1 household 811 97 2382
Total Slovakia [MWhr] 1 539 612 4 521 03630 % ? 461 883 1 356 310
Number of households: 1,898,000
+
+
=
u(t)
i(t)
Deformácia vplyvom fázového posunu a vyšších harmonických
0)().(1
0
T
dttituT
P
Are we metering correctly? Current is “contaminated” and asymmetric
Current is composed not only of the first harmonics but also of higher harmonics, there is a phase shift between current and voltage and a three-phase system is often asymmetric
Deformation due to a phase shift and higher harmonics
Are we metering correctly? Apparent power and other sorts of power
1st term – active power P. The unit of P is watt. Customer pays for such power.
2nd term – reactive power Q. The unit of Q is var. Customer sometimes pays for such power in the form of surcharge or penalty.
3rd term – distortional power D. The unit of D is VA. Nobody pays for such power, nor is penalised for it.
over - undesirable Obviously: S = U.I
+
+
=
u(t)
i(t)
Deformácia vplyvom fázového posunu a vyšších harmonických
0)().(1
0
T
dttituT
P
Let us not neglect the future!
Active power P
Wattless (reactive) power Q
Distortional power D
Asymmetry NPower = total power S
Power factor P/S (PF), losses
22
2
2min
21
PFP
S
IR
IRkz
2
2
2
2
2
2
1 1P
N
P
D
P
Qk z
It is prescribed in the pricelists of power distribution for monthly invoiced customers to monitor also "the power factor or cos φ" which must be within the limits 0.95 to 1. When this condition has not been satisfied, the customer is penalised by a tariff surcharge, a percentage surcharge to the tariff price for the distribution.
We should realise that cos φ in this case represents just a phase shift of the first harmonics u and i, which is defined by means of tg φ as a ratio Q/P and does not represent a real "power factor" which is understood to be the ratio of watt and wattless power in a periodic mode:.
PF = λ = P/S (i.e. not cos φ)
The notion "phase shift" φ, or "power factor" cos φ can be used only for the harmonics u and i.For non-harmonic cycles, we should use PF, i.e. P/S
PF is not the same as cosφ (even if it sometimes is...)
S
P
IU
PPF
.
Losses – loss increase coefficient kz, P/S
Undesirable increase of losses is characterised by loss increase coefficient kz – it indicates how many times are respective losses higher than minimally possible losses for a given power output.
or, after re-arrangement:
If kz >1, then (undesirably) we consume power also for phase shifting, generation of higher harmonics and asymmetry.
3 principal factors which need to be analysed and their influence minimised:Magnitude of wattless power Q, measurement of Q1 and cos φ
Magnitude of distortional power D, measurement of S and higher harmonics of U, I
Magnitude of asymmetry, measurement of U and I in a three-phase system
22
2
2min
21
PFP
S
IR
IRkz
2
2
2
2
2
2
1 1P
N
P
D
P
Qk z
Cos φ and P/S (Monthly monitoring 10/2012, weekend 6 – 7 / 10)
cos(φ) – measured according to power industry usage, it includes the influence of QP/Sa ("cos" Sa) – measured with the help of arithmetic apparent power, it includes the influence of Q, DP/Sr ("cos" Sr) – measured with the help of correct apparent power, it includes the influence of Q, D and, in a three-phase system, also asymmetry NAll measurements are cumulative, i.e. on the basis of energy, not output
cos(φ)
Analysis of DTS loading - values P, Q, S from LZQJ-XC processed in EDW
Maximum 78,4 kW- 28.12.2012 12,00Minimum 17,6 kW- 26.12.2012 03,45
TS : PA_1007 – Rosice nad Labem [CZ], 400 kVA
What we have measured...
26
Table report of performance
Evaluated period: from - to
Asymmetry of current – low PF value
Losses in DS – linear 3-phase arrangement
Improved asymmetry of current – standard PF value
Losses in DS – linear 3-phase arrangement
Situation in an administrative building
How it is in reality?Example of an administrative building
Situation in a family house
How it is in reality?Example of a family house
Situation in a family house
How it is in reality?Example of a family house
Fotovoltaic power generation sources (FVE) – measured results
22min
2nadRIRIRI
Losses in lines
Total losses in lines “over-losses" in lines
Minimum possible losses in lines
"Good" Imin and “Bad" Inad current
Losses caused by the passage of electric current through a conductor are inevitable. They can be optimal or higher than that. They are optimal, if they have a minimum possible value at a given transmitted power output – minimum losses occur when P=S.
22min
2nadIII
U
PI min
How much are losses changing?
PF1/PF2 0,5 0,6 0,7 0,8 0,85 0,9 0,92 0,94 0,96 0,98 10,5 0,000,6 1,22 0,000,7 1,96 0,74 0,000,8 2,44 1,22 0,48 0,000,85 2,62 1,39 0,66 0,18 0,000,9 2,77 1,54 0,81 0,33 0,15 0,000,92 2,82 1,60 0,86 0,38 0,20 0,05 0,000,94 2,87 1,65 0,91 0,43 0,25 0,10 0,05 0,000,96 2,91 1,69 0,96 0,48 0,30 0,15 0,10 0,05 0,000,98 2,96 1,74 1,00 0,52 0,34 0,19 0,14 0,09 0,04 0,001 3,00 1,78 1,04 0,56 0,38 0,23 0,18 0,13 0,09 0,04 0,00
2321
23
22
21
23
22
21
2
2
)(
)).((
PPP
IIIUUU
P
Sk r
z
min2121 )( JZZ PkkPP
The increase of P/S from 0.85 to 0.92 e.g. means that the real losses decrease by 20 % of the magnitude of minimum possible losses
Graphical expression of changeHow much will losses change?
%
Let us try to improve P/S
originally 0.9
originally 0.9
Let us seek common benefits and opportunities, functionalities and data
Data for power consumersData for grid administrators and operatorsData for power suppliers and tradersData for dispatching system and producersData for higher-level system Data for other participants in market with power
Sources for:Analysis of grid conditionOptimisation of switchingImprovement of efficiency and reduction of lossesResolution of undesirable and fault conditionsSupport of integration and control of Renewable Energy SourcesSupport of e-mobility...
Smart Metering – let us seek common benefits and opportunities
Bidirectional communication with points of meteringInformation on actual power consumption and history of power output consumption in time, to be available even for consumers –through websites, home displays, SMSs or TV setsOptional automatic remote reading as of the defined date and time, in regular intervals (e.g. monthly) or on prompt demand (stop-reading, contractual modifications...)Optional remote disconnection and reconnection of consumersLimitation of agreed power output (tariff change-over, limitation of output, prepaid services...)Checks of unauthorised tamperingOptional monitoring and analysing of grid operation parametersOptional input for data from metering of other utilities in the future (gas, water, heat... - with exploitation of existing data transfer and communication channels)
Smart Metering – let us seek common benefits and opportunities
Accurate and more frequent metering – more accurate and detailed information on consumer behaviour with regard to energy and planning
More accurate specification of reserved capacity, reduction of deviation
More accurate prediction – possible better prices for power (?)
Sources for creation of new trading products and motivating, effective or social tariffs
Information on outages and other problems in grids, on alarms and tampering
Refinement (or replacement) of TDO, possible complement / replacement of HDO
Necessary data for future smart grids a development of e-mobility
Enlargement of possibilities for deployment of RES, sources for effective control of power generation units and decentralised power supply in localities
Elimination of negative impacts and influences from deployment of RES
Support of resolution of possible emergency condition
and many other opportunities...
Smart Metering – let us try to resolve drawbacks, risks and threats
Uncertainty of real benefits and return on investment
High one-time costs, unclear financing
Challenging communication and IT solutions
Absence of standards, questionable reliability of the system
Unknown (high) degree of vulnerability and lability of the system
Necessity of complicated coordination, logistic and organisation structures
Questionable relationship of customers to the project, condition of installations and switchboards
Legal aspects of data security and personal data protection
Unclearly defined requirements of future Smart Grids
Complicated interoperability of metering systems and devices
Questionable benefits of control technology in relation to HDO
Insufficiently prepared legislation, etc…
We are starting…
Monitoring DTS outagesLive assembly
Possible design of a switchboard for SG in DTS
RS485
Signal input
GPRS
UPS
AIL09 – Device for monitoring of outages of transforming station outlets
SIEM electricity meter LZQJ-XC
Thermometer
L+Gmeter
ZPA meter
Meter & ControlMeter
MikroelektronikaMeter
L+G NAMeter
IUSAMeter
L+G BrazilMeter
Smart Grid Powerline
Concentrator
Do we want to be ready also for the future?
2221
22_ IUQPS henergetikev
Performance factor P/S
+
+
=
u(t)
i(t)
Deformácia vplyvom fázového posunu a vyšších harmonických
0)().(1
0
T
dttituT
P
Thank you for your attention…
i.chrapciak@schrack.sk