NON-TECHNICAL LOSSES IN POWER NETWORKS ANALYSIS AND IMPACT ASSESSMENT

Innocent E. Davidson

School of Electrical and Electronic Engineering University of Natal, Durban 4041, South Africa Tel. (031) 260 1246, Fax (031) 260 1300

E-mail: Davidsoni@nu.ac.za

 

Abstract- Electric utilities operating as government monopoly institutions in rigid grid structures,  have in  the  past  paid little attention to assessing and analyzing technical and non-technical losses because they did not constitute  major operational     or quality of supply problems. Since their impact is economic, costs involved were often passed down to consumers. In market- driven economies and deregulated electricity industry environments, the minimization of these losses has assumed greater importance. In South Africa, non-technical losses  need to be addressed  to determine the  overall performance of transmission  and distribution networks, as these losses are expected to be more dominant at the subtransmission (132kV-33kV) and  reticulation (22kV and 11kV) levels of the electricity supply industry value chain. Non-technical losses appeared to have never been thoroughly studied. In some national grid operations, it is estimated to account for up to 30% of revenue losses to utilities, and overhead expenditure in added maintenance costs. The goal of privatization and deregulation of South Africa’s electricity supply industry and introduction of competition is to provide end-users with lower energy prices and good quality of supply. Hence stakeholders are demanding greater transparency in electricity pricing by regional electricity distributors (RED).  This paper provides an overview of non-technical losses in South Africa’s power grid, and presents strategies for loss minimization, revenue collection and stimulus for further NTL research investigation with active industry participation.

 

Key words: Non-technical losses (NTL), loss minimization.

 

I.   INTRODUCTION

 

Research investigations have been undertaken  to  assess the impact of technical losses in generation, transmission and distribution networks, and the overall performance of power networks [1-5]. Non-technical losses (NTL) appear to have never been adequately studied and in some national grid operations, it may account for up to 30% of revenue losses to utilities due to overhead expenditure in added maintenance costs. To date, no existing data of non-technical losses  in South Africa’s Power System is known to the author.

 

This paper undertakes an introductory study/review of non-technical losses in electric power networks. It identifies and describes the sources of non-technical losses, with this  key question in view: To what extent does  non-technical losses account for loss of revenue to power utilities and municipalities (e.g. annual GWh lost expressed as a  percentage of total GWh produced by Eskom). It further attempts to address this and other issues, such as: the costs associated with NTL, their overall economic impact, and how NTL may be minimized or eradicated?

 

 

II.   NON-TECHNICAL LOSSES

 

The processing and delivery of electricity involves substantial losses, which need to be minimized to maximize revenue. These losses are both technical and non-technical (NTL). Technical losses include: generation losses (due to turbine efficiency), and losses due to the current flowing in

the electrical network such as line losses, copper and iron losses of transformers [5]. Technical and non-technical losses in networks are an economic loss. Losses represent a considerable operating cost, estimated to add 6 to 8 percent to the cost of electricity and some 25 percent to the cost of delivery [2]. The accurate estimation of electrical losses enables the supply authority to determine with  greater accuracy the operating costs for maintaining  supply consumers. This in turn enables a more accurate estimate of  the system lifetime costs, over the expected life of the installation [3].

 

Non-technical losses (NTL) can be attributed to and include the following:

·        Equipment loss and vandalization - loss and damage of hardware, such as meters, protective equipment, cables/conductors and switchgear

·        Unauthorized line tapping

·        Losses due to faulty meters and equipment

·        Inadequate metering and poor revenue collection techniques

·        Inadequacies and inaccuracies of meter reading

·        Inaccurate customer billing

·        Inaccurate estimation of non-metered supplies, such as public lighting, and

·        Performance (inefficiency) of business/technology management systems

 

Most of these types of losses are dominant in lower levels of distribution (reticulation) networks, and lead to loss of

 

revenue. The cost of these losses is often arbitrarily passed on to end-users (consumers) as higher electricity costs. NTL are usually construed as a loss of revenue by the utility, and both these losses need to be reduced to their optimal level. The sources of NTL require new and innovative methods for estimation, analysis and minimization when compared with technical losses.

 

 

III.   POWER SYSTEM INVESTMENT PLANNING

 

Power system development planning entails load growth identification by magnitude and location over a period of interest, and matching generation is secured. This is followed by the possibility of local generation with fuel transportation compared with remote generation and electrical transport.

The technical problem of transmission is considered  and  a decision made on the choice of ac or dc. The management   of a power-supply authority demands consideration of these factors if the most attractive return is to be secured on the investment.

 

The basics of investment planning for power networks involves:

 

(a.) Fixed (Capital) Costs

·     Switchgear

·     Equipment - generators, transformers, protection devices, etc.

·     Land

·     Infrastructure (building)

·     Loans/interests/insurance

·     Labor (construction)

 

(b.) Variable (Operational) Costs

·     Fuel costs

·     Worker’s salaries

·     Maintenance

·     Transportation

 

Before a numerical evaluation of NTL is carried out, a background on the changing electricity industry environment should be mentioned, and how market forces are shaping a radically different world.

 

 

IV.    STRUCTURAL REFORM AND OPERATION OF THE ELECTRICITY SUPPLY INDUSTRY

 

Globalization, changing public perception, environmental, regulatory and economic challenges are compelling electric utilities and government-owned monopoly institutions to restructure, both in developed and  developing  economies. This is often preceded by privatization (which often entails government divestiture), and then deregulation (or re- regulation).

This market liberalization and industry privatization trend is not limited to the electricity industry, but also applies to the communications, petroleum, defense and other industries. Governments are also under pressure to raise funds to  pay debt, fund social services, balance budgets, and carry out economic reform [6]. Electric utilities are required to supply low cost power to customers, provide better service  and  ensure high environmental and health safety.

As a rule, the fundamental objectives for privatization and restructuring of the electricity supply industry (ESI) must be:

 

·        To sustain future economic and technological growth

·        Deliver adequate social benefits to the populace

·        Ensure a secure and reliable supply of electricity

·        Encourage efficiency through competition and regulation in all segments of the electricity industry.

 

Worldwide experience shows that successful privatization and deregulation of the  electricity industry is  achieved  when it is unbundled into generation, transmission and distribution sections, with each section operating as a business enterprise on its own merit with distinct functions/responsibilities [7]. Restructuring of the electricity industry means  breaking  up the often vertically integrated structures into generation, transmission and distribution operations.

This approach will maximize revenue to be derived from privatization, and ensure wider public involvement in the industry. The operation of each of these sections as separate business entities often involves measures to minimize costs, provide good quality service, maximize profits and provide a high rate of return on investment (ROI).

 

 

V.   OPERATING ELECTRIC POWER NETWORKS AS BUSINESS ENTITIES

 

Consumers/regulators are demanding price transparency and elimination or disclosure of cross subsidies among different users. Consumers want competition in the electric industry so they can get lower prices. Marketers want the electric industry restructured so they can make money, either by getting a higher price for the output  of  generators  they own or to which they have access, or just by opening up  a  new market [8]. These two seemingly opposing  forces  must be adequately managed/regulated to achieve optimal performance of electric power networks.

The business/technical systems performance of network

operators will determine the overall return on investment (ROI), hence economic and business measures have to be adopted. Maximum efficiency minimizes the cost of kWh to the customer and the cost to the company for delivering that kWh, with rising or changing fuel, labor, and maintenance costs.

Recently, the UK electricity regulator opted to remove price controls from the ESI, because of the realization of competition in the industry. Economic operation of power

 

networks entails two components, namely: minimum cost of power production called economic  dispatch  and  minimum loss for delivery of generated power to the loads.

 

 

VI.   NTL AND SOUTH AFRICA’S POWER GRID

 

An accurate diagnosis of the NTL problem is critical to prescribe suitable solution. As a basic constraint, the cost of implementing solutions should not exceed the cost of NTL in revenue to electric utilities. Factors affecting NTL include:

 

(i.) Socio-economic: unemployment, rural and urban poverty, financial insecurity, illiteracy and lack of broad-based private/community sector ownership.

(ii.) Professionalism: This is often poor in many business enterprises, as well as weak business skills

(iii.) Organizational behavior: This is often poor  leading  to inappropriate attitude to customer service.

(iv.) Technical Tools: Insufficient cost-effective technical resources to tackle these problems.

 

The strategies to be adopted for NTL reduction include development of optimum business models, new  capabilities for managing power networks as business entities, and a shift in public attitude. These can be divided into focused areas:

 

Business & Management Focus: This involves:

·        Development of optimum business models for enhanced management of processes

·        Development  of business capabilities:

·        Standardization of measurement techniques.

·        Pre-paid metering, to reduce NTL within the  pre-  paid environment

·        Energy monitoring and data acquisition techniques

·        Electronic and cashless financial transaction in the electricity supply industry

·        Testing, maintenance and elimination of  faulty meters, and out-dated equipment.

·        Detection of metering tempering

 

Public Sector Focus: This involves:

 

·        Extensive private sector/community participation in ownership of power network/infrastructure

·        Public safety issues

·        Minimization of fraud at work and theft of monies in transit to protect revenue

 

 

VII.   TECHNICAL AND NTL ESTIMATION

 

Using South Africa’s power grid as a case study, a review of the evaluation procedure for technical losses  in transmission and distribution (T&D) system is  carried  out, and a method for NTL estimation is presented. The total system loss is given by the difference between the energy generated or delivered and the energy sold. Normally the energy used in power station or substation auxiliaries is deducted from the losses to get a true reflection of the system losses. Energy loss is given by:

-         Structures and controls to reduce errors

-         Improve segregation of duties/accountability

-         Reduce possibilities for fraud

ELoss

= EDelivered

-  ESold

… ... … … … … (1)

-         Eliminate inaccurate financial reporting and reconciliation

-         Effective system recording, documentation and journal entries for energy data, operational and additional maintenance costs due to NTL.

CLoss  = UCost x ELoss + MCost..................... (2)

CNTL  = CLoss - CTLoss................................................. (3)

-         Standardization of reporting techniques and energy-balancing tools.

-         Accuracy of management reporting and the

C

where,

NTL

= UCost

x ELoss

+  MCost

- CTLoss

… (4)

processing of pre-paid transactions.

-         Energy data and revenue audits

·        Staff training to support these business capabilities,  as well as work ethics, professionalism and good customer service.

·        Development of efficient community-based revenue collection techniques, bulk meter installations for – small power consumers.

 

Technology Focus: This involves technologies management and deployment, in areas such as:

·        Operating more power substations on supervisory control (SCADA)

·        Protection, metering and control (PMC) functional integration and automation

CLoss = Revenue loss due to technical/additional losses

UCost = Unit cost of electricity

MCost = Maintenance and additional operation costs

CNTL = Non-technical loss cost component.

CTLoss = Technical loss cost component.

 

The NTL has an energy component directly related to the power network losses, and a second component due to non- energy related revenue loss, accounted for additional maintenance costs, and direct revenue loss. The first component is computed as in equation (4), but the second component is obtained for additional operation/maintenance costs associated with NTL data.

 

For technical loss estimation, the annual cost of I ² R  loss in Rand per mm2 of conductor cross-section per mm length, can be estimated.

 

Structural charge, S is given by

S = L(aA + � ) r Rand/annum

100

 

Cost of technical losses, W is given by:

NTL minimization is a concrete economic and business tool to optimize the overall performance of our power networks.

 

IX. ACKNOWLEDGEMENTS

 

This work has been supported by research funds from the University of Natal, Durban, South Africa.

W = 3x

I 2 · p · L

1000 · A

x 24x365x

p

 

100

Rand /annum

REFERENCES

 

[1]         Paul C.R., “System loss in a Metropolitan utility

where, I = Phase current (Amps), L = Total length (mm),

p is resistivity of conductor material (O-mm), p is cost of energy in cent/kWh, and r is combined % rate of interest and depreciation of the line conductors.

 

From estimates of technical losses, it is easy to estimate  the impact of NTL in revenue and on electricity pricing. Therefore small reductions in network losses will amount to significant financial savings to utilities as well as customers.

 

 

VIII.  CONCLUSION

 

To evaluate the impact of system losses, the magnitude of these losses needs to be determined. As shown, the  total system losses can easily be determined. The losses are then divided into technical and non-technical losses. The next step is to assess the continuing cost of losses, usually in annual terms. This cost should reflect cost of production (in terms of generating capacity), fuel consumption and reflect the cost of capacity/delivery in transmission and distribution networks. These losses should be recognized as real and  substantial  costs on the supply of electricity and should be managed like other costs.

Losses can be reduced by local network development and implementing the strategies advanced in this paper. By using this option you not only reduce the generation and system capacity but also reduce the cost of delivery of energy, which is the biggest contributor to the final cost of energy. This option also improves system efficiency and reduces cost of electricity to consumers. The expected benefits of NTL estimation/minimization include:

 

·    Provide vital database information on the risk factor associated with our power network to power system planners and maintenance units, and thus improve on security and quality of supply

·    It translates into direct economic benefits with  enhanced revenue for distribution companies and municipalities

·    Potentially reducing electricity prices, and boost economic competitiveness in local industrial  sector,  and improve affordability by the poor

network”, IEE Power Engineering Journal, pp. 305- 307, September 1987.

[2]         Tobin N and Sheil N, “Managing to reduce power transmission system losses”,  Transmission Performance, Publication of Electricity Supply Board International, Dublin, Ireland 1987.

[3]         Sellick R.L. and Gaunt C.T. “Load Data Preparation   for Losses Estimation”. Proceedings of  the  7th  Southern African Universities Power Engineering Conference (SAUPEC), Stellenbosch, South Africa, Vol. 7, pp 117-120, 1998.

[4]         Krishnaswamy N, “A holistic approach to practical techniques to analysis and reduce technical losses on Eskom power networks using the principles of management of technologies”, Technology Leadership Program, Management of Technology Dissertation, April 2000.

[5]        Davidson I.E., Odubiyi A., Kachienga M.O. and Manhire, B., “Technical Loss Computation and Economic Dispatch Model in Transmission & Distribution Systems in a Deregulated Electricity Supply Industry”, Paper submitted to the IEE Power Engineering Journal, October 2001.

[6]         Davidson IE, Okafor FN, Jimoh AA and Ojo JO, “Power Systems Control Automation in Developing Economies – The Nigerian Experience,” Proceedings of the IFAC Conference on Technology Transfer in Developing Countries: Automation in Infrastructure Creation, Pretoria, South Africa, 5-7 July 2000, pp. 114-118.

[7]         Davidson IE, Odubiyi A, “Power system automation and integration in  developing  economies”.  Proceedings of the CIGRE 1nternational  Conference on Power Systems (CIGRE ICPS2001), September 03- 05, 2001, Wuhan, Hubei, China.

[8]         Lively, M.B., “Competitive Electricity Prices by Changing Tariffs, Not by Changing Providers”, The Washington DC Customer Choice/Utility Competition Report, Prepared for District of Columbia Office, People Counsel Conference Utility Competition, May  5, 1998.

[9]         Davidson I E, Naidoo DR. “Network Loss Calculation in a Deregulated ESI”, 11th Southern African Universities Power Engineering Conference (SAUPEC), Vaal Triangle Technikon, South Africa, January 30-February 1, 2002.

 

 

 

 

 

 

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