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WHITEPAPER CABLE CONDUCTOR SIZING FOR MINIMUM LIFE CYCLE COST Bruno De Wachter, Walter Hulshorst, Rodolfo di Stefano July 2011 ECI Publication No Cu0105 Available from www.leonardo-energy.org/node/156451

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Energy prices are high and expected to rise. All CO2 emissions are being scrutinized by regulators as well as by public opinion. As a result, energy management has become a key factor in almost every business. To get the most out of each kilowatt-hour, appliances must be carefully evaluated for their energy efficiency. It is an often overlooked fact that electrical energy gets lost in both end-use and in the supply system (cables, busbars, transformers, etc.). Every cable has resistance, so part of the electrical energy that it carries is dissipated as heat and is lost. Such energy losses can be reduced by increasing the cross section of the copper conductor in a cable or busbar. Obviously, the conductor size cannot be increased endlessly. The objective should be the economic and/or environmental optimum. What is the optimal cross section necessary to maximize the Return on Investment (ROI) and minimize the Net Present Value (NPV) and/or the Life Cycle Cost (LCC)? This paper will demonstrate that the maximizing of the ROI results in a cross section that is far larger than which technical standards prescribe. Those standards are based entirely on safety and certain power quality aspects. This means there is room for improvement—a great deal of improvement in fact.

TRANSCRIPT

Page 1: Cable Conductor Sizing for Minimum Life Cycle Cost

WHITEPAPER CABLE CONDUCTOR SIZING

FOR MINIMUM LIFE CYCLE COST

Bruno De Wachter, Walter Hulshorst, Rodolfo di Stefano

July 2011

ECI Publication No Cu0105

Available from www.leonardo-energy.org/node/156451

Page 2: Cable Conductor Sizing for Minimum Life Cycle Cost

Publication No Cu0105

Issue Date: July 2011

Page i

Document Issue Control Sheet

Document Title: White Paper – Cable Conductor Sizing for Minimum Life Cycle Cost

Publication No: Cu0105

Issue: 01

Release: 06/07/2011

Author(s): Bruno De Wachter, Walter Hulshorst, Rodolfo di Stefano

Reviewer(s): David Chapman, Hans De Keulenaer, Stefan Fassbinder

Document History

Issue Date Purpose Prepared Approved

1 06/07/2011 Initial publication

2

3

Disclaimer

While this publication has been prepared with care, European Copper Institute and other contributors provide

no warranty with regards to the content and shall not be liable for any direct, incidental or consequential

damages that may result from the use of the information or the data contained.

Copyright© European Copper Institute.

Reproduction is authorised providing the material is unabridged and the source is acknowledged.

Page 3: Cable Conductor Sizing for Minimum Life Cycle Cost

Publication No Cu0105

Issue Date: July 2011

Page ii

CONTENTS

Summary ........................................................................................................................................................ 1

Optimum is several times larger than standard .............................................................................................. 2

Cable sizing according to the standards .......................................................................................................... 2

Economical cable sizing: the basics ................................................................................................................. 4

Searching for the cross section with lowest LCC ............................................................................................ 5

Recalculating the cost to a present value .......................................................................................... 5

Taking the actual loading of the cable into account ......................................................................... 5

Isolating cable characteristics from operational and financial values ............................................ 5

Optimal cross section depending on the cable price ........................................................................ 6

An example of a calculation ................................................................................................................. 6

Table with optimal values ..................................................................................................................... 7

Searching for the current density with lowest LCC ......................................................................................... 7

Calculating the losses based on the current density ........................................................................ 7

The cost of energy losses per ton of conductor material ................................................................. 8

Choosing an optimal current density for a particular economic lifetime ........................................ 8

Graphical representation ...................................................................................................................... 8

Taking the scrap value into account ................................................................................................... 9

Table with optimal values ................................................................................................................... 10

Additional advantages of larger cross sections ............................................................................................. 10

Improved power quality ....................................................................................................................... 10

Increased flexibility .............................................................................................................................. 10

Round-up ...................................................................................................................................................... 11

Annex ........................................................................................................................................................ 12

Table with a few optimal conductor cross sections ............................................................................................. 12

Table with a few optimal current densities .......................................................................................................... 12

Page 4: Cable Conductor Sizing for Minimum Life Cycle Cost

Publication No Cu0105

Issue Date: July 2011

Page 1

SUMMARY Energy prices are high and expected to rise. All CO2 emissions are being scrutinized by regulators as well as by

public opinion. As a result, energy management has become a key factor in almost every business. To get the

most out of each kilowatt-hour, appliances must be carefully evaluated for their energy efficiency.

It is an often overlooked fact that electrical energy gets lost in both end-use and in the supply system (cables,

busbars, transformers, etc.). Every cable has resistance, so part of the electrical energy that it carries is

dissipated as heat and is lost.

Such energy losses can be reduced by increasing the cross section of the copper conductor in a cable or

busbar. Obviously, the conductor size cannot be increased endlessly. The objective should be the economic

and/or environmental optimum. What is the optimal cross section necessary to maximize the Return on

Investment (ROI) and minimize the Net Present Value (NPV) and/or the Life Cycle Cost (LCC)?

This paper will demonstrate that the maximizing of the ROI results in a cross section that is far larger than

which technical standards prescribe. Those standards are based entirely on safety and certain power quality

aspects. This means there is room for improvement—a great deal of improvement in fact.

Two different models are used in this presentation:

1) The first model (see page 4) is more detailed and calculates the most economical cross section for a specific cable connection.

2) The second model (see page 6) is ideal for obtaining an approximation of the ROI with copper conductors and for developing a company-wide policy for cable sizing, independent of the particular rated current of a single connection. It calculates the optimal current density.

Calculating the environmental optimum using a Life Cycle Analysis (LCA) is not within the scope of this

whitepaper. However, it is worth mentioning that this environmental optimum lies at an even larger cable

cross section than the economic one. Indeed, the environmental impact of energy losses quickly mounts to

high levels compared to the environmental impact of copper—a 100% recyclable material.

We will calculate the conductor cross section for minimum LCC and maximum RoI.

Page 5: Cable Conductor Sizing for Minimum Life Cycle Cost

Publication No Cu0105

Issue Date: July 2011

Page 2

OPTIMUM IS SEVERAL TIMES LARGER THAN STANDARD The following examples show the order of magnitude of the gap between the technical minimum standard and

the economic optimum.

Take for instance a cable with a rated current of 100 A and a nominal voltage of 230 V. According to the

minimum technical standard, this cable should have a minimum cross section of 25 mm2 to avoid excessive

heat production.

The economic optimum depends on market and operational conditions. Assume an electricity price of

€100/MWh, a cable price of €0.30/(mm2 x m), a life time of 10 years, and an interest rate of 7.5%.

Furthermore, suppose an average loading of 65% over 3,700 hours per year (42% of the time). Those figures

result in an optimal cable section of 71.77 mm2, a cross section that is nearly three times the standard.

Assuming an average loading of only 40% during a mere 1,400 hours per year (16% of the time) for the same

cable, electricity prices, and lifetime of 10 years, the optimal cable section would still be 44.12 mm2, or nearly

twice the safety standard.

The following chapters will show how those calculations are made.

CABLE SIZING ACCORDING TO THE STANDARDS The international technical standards for cable sizing take safety and certain power quality aspects into

account, but NOT energy efficiency. According to these technical standards, the minimum cross section of a

cable is defined by the most stringent of three restrictions:

1) The thermal impact of the maximum rated current

2) The voltage drop created by the maximum rated current

3) The electro-dynamic impact of the strongest short circuit current

The first restriction is defined in the technical standard IEC 60364-4-43 (Electrical Installations for buildings):

The heat production in the cable should be restricted to avoid the creation of hot spots that could affect the insulation quality or which could be dangerously hot to touch. By choosing a sufficient cross section for the cable, its electrical resistance will remain low, as will the production of heat.

The second restriction is stipulated in the standard DIN 18015-1:2007-09:

The maximum rated current will create a voltage drop in the cable. This should not be higher than 3% of the nominal voltage to ensure the proper functioning of all appliances. By choosing a sufficient cross section for the cable, its electrical resistance will remain low, as will the voltage drop.

The third restriction is defined in the technical standard IEC 60909 (Short-circuit currents in three phase AC

systems):

The short-circuit current Isc, multiplied by the time-current curve of the circuit breaker, should not cross the time-current characteristic expressing the electro-dynamic strength of the cable. The latter is proportional to the cable cross-section.

Page 6: Cable Conductor Sizing for Minimum Life Cycle Cost

Publication No Cu0105

Issue Date: July 2011

Page 3

For shorter cables and/or higher voltages, the first restriction (heat production) will be the most stringent in

most cases. For longer cables and/or lower voltages, the second restriction (voltage drop) that will be the most

stringent in most cases.

This whitepaper will demonstrate that a fourth criterion should be taken into account when choosing the

conductor cross section:

4) The cost of the total energy losses in the cable over its economic lifetime should not be higher than the investment cost of the cable.

This whitepaper will show that this fourth criterion will be the most stringent in the large majority of the

cases.

Page 7: Cable Conductor Sizing for Minimum Life Cycle Cost

Publication No Cu0105

Issue Date: July 2011

Page 4

ECONOMICAL CABLE SIZING: THE BASICS The power losses in a cable at a given moment in time can be calculated using the following formula:

Ploss = I2 x (ρ/A) x l

With:

I = the current in the conductor (depending on the load)

ρ = the specific electrical resistance of the conductor

A = the cross section of the conductor

l = the length of the cable

This should be multiplied by the total time of operation over the lifetime of a cable to obtain the total lifetime

energy losses El:

Elosses = (I2 x (ρ/A) x l) x tlife

We see that the energy losses are inversely proportional to the cross section of the conductor.

The investment cost of the cable, on the contrary, increases close to linear with its cross section.

CTotal = CInvestment + CLosses

The economic cable cross section will be the point where the sum of the investment

cost and the cost of the losses goes through a minimum.

Page 8: Cable Conductor Sizing for Minimum Life Cycle Cost

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Issue Date: July 2011

Page 5

SEARCHING FOR THE CROSS SECTION WITH LOWEST LCC

Even though the basic principle is simple, calculating the cable section S leading to the lowest life cycle cost

CTotal introduces a few complexities.

CTotal = CInvestment [S] + CLosses [1/S]

RECALCULATING THE COST TO A PRESENT VALUE

The initial step in this process is to recalculate the cost of the losses to reveal the operational cost at the date

of installation. An interest rate (i) should be set, as well as the economic lifetime of the cable (n). The cost of

the losses should then be multiplied by the following capitalization factor:

N(i,n) = ((1 + i)n – 1) / (i – (1 + i)

n)

Moreover, the average electricity tariff (T) over the economic lifetime of the cable should be estimated.

This leads to the formula for the cost of the energy losses:

Closses = (I2 x (ρ/A) x L) x tecon life x Tariff electr (€/kWh) x N(i,n)

TAKING THE ACTUAL LOADING OF THE CABLE INTO ACCOUNT

A second point is that the cable will not be loaded at its rated power continuously. This means the time t is not

the complete economic lifetime of the cable, but only the time the cable will be loaded: toperational hours econ life.

Moreover, the current I will not be the rated current, but the average of the currents that really flow through

the cable, a figure that depends on the average relative loading

Ploading = Pload/Prated.

Ireal = (Ireal/Irated) x Irated

= (Pload/Prated) x Irated

= Ploading x Irated

with Ploading a figure varying between 0 and 1

This leads to the following equation:

CLosses = (Ploading)2 (Irated

2 x (ρ/A) x l) x thours x Tariff [€/kWh] x N(i,n)

ISOLATING CABLE CHARACTERISTICS FROM OPERATIONAL AND FINANCIAL VALUES

Now we can put all the factors which are not cable characteristics into one operational and financial value F.

F = (Ploading)2 x thours x Tariff[€/kWh] x N(i, n)

The following table gives a few average values for F per sector.

Industry Interest N (year) Energy Price (euro/MWh) Loading T (hours) F (euro/W)

Iron 7,5% 10 100 65% 3700 7,62

Non Ferrous 7,5% 10 100 35-45% 2730 5,62

Paper 7,5% 10 100 65% 3700 7,62

Chemical 7,5% 10 100 40% 1400 2,88

Datahotel 7,5% 5 100 25-75% 2735 3,32

Office 7,5% 10 100 20-40% 1182 2,43

Page 9: Cable Conductor Sizing for Minimum Life Cycle Cost

Publication No Cu0105

Issue Date: July 2011

Page 6

In general industrial conditions, F will vary between 0.5 and 20 €/W. The average value of F across all European

industry sectors is 4.24 €/W. For a long-term investment in a cable that will be constantly loaded close to its

rated power, F can rise above 50 €/W.

The LCC formula now becomes:

CT = CI + CL

CT = CI[S] + 1/A x Irated2 x ρ x length x F

OPTIMAL CROSS SECTION DEPENDING ON THE CABLE PRICE

The specific resistance of a copper conductor is 2.054 µΩ*cm at a typical operating temperature of 105 °C

(1.720 µΩ*cm at 20 °C) or 0.02054 mΩ*mm.

Consequently, the equation for one meter of cable (1,000 mm) now becomes:

CT = Cc x A + 1/A x Ir2 x 0.02054 x F

With:

Cc the cable price in euro per mm2 cable cross section and per meter cable length

A the cable cross section expressed in mm2

Ir the rated current in Ampère

F the operational and financial value in €/Watt

This equation gives the total Life Cycle Cost of 1 meter of cable in euro.

The optimal cross section A of a cable is the point where the curve of this equation goes through its minimum.

It can be proved mathematically that this minimum will always lie at the point where the first part and the

second part of the sum are equal.

This occurs when:

Cc x A = 1/A x Ir2 x 0.02054 x F

Or: A2 = Ir

2 x 0.02054 x F / Cc

AN EXAMPLE OF A CALCULATION

Assume a cable in the Iron Sector that will carry a rated current of 200 A. The average loading in this sector is

65%, while the average operating time is 3,700 hours per year. If the additional assumptions are an interest

rate of 7.5% and an economic lifetime of 10 years, the F factor will be 7.62 euro/W.

At the current copper price, the cost of one meter of cable (3 phases + neutral) can be estimated to be

approximately €0.30 per square millimeter of conductor cross section: €0.30 /(mm2 x m), or €0.075 for each of

the four conductors.

We can calculate the optimal cross section A from:

A = Ir x 0.1433 x (F/Cc)1/2

With Ir the rated current of the connection, F a financial and operational value varying per

sector, and Cc the cable price per meter and per mm2 cross section.

Page 10: Cable Conductor Sizing for Minimum Life Cycle Cost

Publication No Cu0105

Issue Date: July 2011

Page 7

The most economical conductor cross section for this cable will be:

A = 200 x 0.1433 x (7.62/0.30)1/2

= 144.44 mm2

Note that according to the technical standard, the minimum conductor cross section for this cable should only

be 53 mm2.

TABLE WITH OPTIMAL VALUES

There is a table in the annex providing the optimal cross section for a number of representative sectors,

depending on the rated current Ir.

SEARCHING FOR THE CURRENT DENSITY WITH LOWEST LCC

The calculations executed above are relevant for anyone interest in the most economical cross section for a

single connection. However, to develop a general, company-wide policy for cable sizing, the optimum should

be expressed in terms that are independent of the particular rated current of a single connection.

This can be accomplished by setting a general, company-wide figure for the ratio between the current and the

cross section. This figure is also called the current density (A/mm2).

CALCULATING THE LOSSES BASED ON THE CURRENT DENSITY

How can the optimal current density for a company be set?

Remember that the goal is to minimize the Total Present Value of the cables throughout the entire company.

This Total Present Value will be composed of an investment cost paying for the material plus the cost of losses

that are induced in this material over its economic lifetime, recalculated to the present time.

Those losses per amount of conductor material are related to the current density:

Plosses = Ir2 x ρ/A x L

If J = Ir/A is the current density, then it follows that:

Plosses = J2 x A

2 x ρ/A x L

= J2 x A x L x ρ

= J2 x Volume x ρ

In other words, the power loss per volume is:

Plosses / Volume = J2

x ρ

Or with the density of copper being 8.94 ton/m3 and the value of ρ being 2.054 µΩ*cm at an average operating

temperature of 105 °C (1.720 µΩ*cm at 20 °C), we get:

Plosses [kW/ ton] = (J[A/mm2])

2 x 2.3

The power loss per ton of copper conductor is proportional to the square of the current

density.

Page 11: Cable Conductor Sizing for Minimum Life Cycle Cost

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Issue Date: July 2011

Page 8

THE COST OF ENERGY LOSSES PER TON OF CONDUCTOR MATERIAL

If the cable is fully loaded all the time, we must multiply Plosses by 8,760 hours (one year) to get the annual

energy losses. However, while not impossible, this is almost never the case. We therefore need a correction

factor, the Hour-Loss-Equivalent (HLE). This figure is calculated by taking the average over the year of the

(actual power/rated power)2. To give an idea of this figure, the HLE in the electricity distribution grid in France

is 3,050 hours. In most industrial sectors, this figure will probably be lower.

A good estimate for HLE is

HLE = 0.65 x Wannual[TWh] / Ptotal [MW]

= 0.65 x HPE

with Wannual the total annual energy consumption of the site (= Work), Ptotal the total power of the site, and HPE

the Hour-Power-Equivalent.

CHOOSING AN OPTIMAL CURRENT DENSITY FOR A PARTICULAR ECONOMIC LIFETIME

In the optimal economic situation, the sum of the losses that are induced in one ton of copper conductor over

its economic lifetime should be equal to the investment cost, namely the cost of one ton of copper.

This means the optimal current density can be calculated using:

J = (C1ton / (Tariff[€/kWh] x HLE x 2.3 x N(i, n)))0.5

GRAPHICAL REPRESENTATION

A graphical representation of the current density can be derived from the above equation.

Suppose a current density of 1.4 A/mm². Note that this density is consistent with the example in the former

calculation model (page 6), where the optimal conductor cross section was calculated to be 144 mm2 for a

cable of 200 A rated current.

The annual cost of energy losses Cannual energy loss of one ton of copper conductor:

Cannual energy loss / ton = Tariff [€/kW] x HLE x J2 x 2.3

With Tariff the electricity tariff, HLE the Hours of Load Equivalent, and D the current

density.

If:

The cost of 1 ton of copper cable = the cost of the energy losses induced in this ton of

copper over its lifetime

Then:

The economic optimal current density is achieved

Page 12: Cable Conductor Sizing for Minimum Life Cycle Cost

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Issue Date: July 2011

Page 9

Furthermore, suppose an HPE of 3,700 hours, an electricity price of 0.1 €/kWh, and a copper price of 6,000

€/ton. This copper price needs to be multiplied with an adjustment factor to get the actual cable price. A factor

of 1.3 is a good estimate for this ratio, giving a cable price of €7,800 per ton of copper conductor used.

The graph that follows presents the curves for the cumulative annual losses, recalculated to the present time

with interest rates of respectively 5% (purple), 7.5% (blue), and 10% (orange). The green curve represents the

investment cost. Thus the economic lifetime of the cable will be 8.5 years, 10 years, and 12.5 years

respectively.

Varying the current density causes the economic lifetime to vary as well. The optimal current density can be

found for a specific economic lifetime through iteration.

Note that the payback period of 10 years for an interest rate of 7.5% is exactly the same as given in the

example of the former model (page 6), meaning that both models are consistent.

TAKING THE SCRAP VALUE INTO ACCOUNT

There is still one element missing in the former example. When a copper cable is dismantled, the copper is not

thrown away but recycled. The owner will receive a significant sum for the scrap. This scrap value should be

recalculated according to current prices and subtracted from the investment value.

Suppose for example a scrap value that is 50% of the value of new copper.

INPUT DATA

density (A/sq.mm) 1,4

loss (kw/ton) 4,508

HPE (hours) 3700

HLE/HPE 0,65

HLE/HPE x HPE 2405

electricity price (€/kwh) 0,1

yearly cost of loss (€) 1084

cable price € / ton copper 7800

Scrap value / new value 0

INPUT DATA

density (A/sq.mm) 1,4

loss (kw/ton) 4,508

HPE (hours) 3700

HLE/HPE 0,65

HLE/HPE x HPE 2405

electricity price (€/kwh) 0,1

yearly cost of loss (€) 1084

cable price € / ton copper 7800

Scrap value / new value 0,5

Page 13: Cable Conductor Sizing for Minimum Life Cycle Cost

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Page 10

In this case, the curves of the former example are as follows:

The economic lifetime is reduced to approximately 5.5 years. To achieve a higher economic lifetime, a larger

cable cross-section should be chosen.

TABLE WITH OPTIMAL VALUES

In the annex you can find a table providing the optimal current density depending on the loading (Hour Power

Equivalent) and the chosen economic lifetime n.

ADDITIONAL ADVANTAGES OF LARGER CROSS SECTIONS

The advantages of a larger cable cross section are not limited to economic and ecological benefits. A larger

cable cross section also has certain technical advantages, including increased power quality and the flexibility

of the connection.

IMPROVED POWER QUALITY

When the cross section of a conductor is increased, the voltage drop over the line is reduced. This means that

the voltage variation between a loaded and unloaded cable is reduced as well. As a result, power quality issues

(harmonics, voltage dips, transients, etc.) will be less severe.

Furthermore, since the line will be carrying a lower load, the risk of a power outage caused by an overload will

be lower.

INCREASED FLEXIBILITY

The power of the load has to be estimated when a new connection is designed. This is not always an easy task.

An increased cross section of the cable makes the connection more flexible in regards to a future increase in

the load. As long as the cable remains within safety limits, the load increase will not require an immediate

replacement of the cable.

The higher the scrap value, the lower the current density should be chosen (= higher

cross sections) to achieve a particular economic life-time of the cable.

Page 14: Cable Conductor Sizing for Minimum Life Cycle Cost

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Page 11

ROUND-UP Technical standards prescribing the minimum cross section of cables take only safety and certain

power quality arguments into account. However, the most economical cross-section is several times larger.

This economical cross section follows from the minimum Net Present Value (NPV) of the cable, taking the energy losses over the lifetime of the cable into account.

Calculating the NPV requires the rated current of the connection, as well as a few boundary values,

such as the actual loading, the electricity tariff, the interest rate, and a chosen economic lifetime.

A company-wide policy for choosing economic cable sections can be established by determining a preferred current density. This optimal current density will minimize the NPV of each ton of copper conductor, taking the energy losses over its lifetime into account. Calculating this current density requires the average loading of the cables, the electricity tariff, the interest rate, and a chosen economic lifetime.

Once a company-wide current density is established, the optimal cross-section for each individual

connection follows directly from the rated current.

The optimal current density will be even lower if the scrap value of the copper is taken into account. This means the optimal cross-sections will differ even more from the standard.

Note that economic and environmental advantages are not the only ones derived from using a larger cable cross section. It will also have a positive influence on power quality and increase flexibility regarding future load increases.

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Page 12

ANNEX

TABLE WITH A FEW OPTIMAL CONDUCTOR CROSS SECTIONS

For a cable price of 0.3 €/(mm2 x m)

TABLE WITH A FEW OPTIMAL CURRENT DENSITIES

Standard cross section (mm2)

I rated F = 2.43 (office) F = 7.62 (iron, paper)

20 10 16 1,5

30 16 25 2,5

40 35 35 4

50 35 50 4

60 35 50 6

75 35 70 10

100 50 95 25

150 70 120 35

200 95 150 50

250 120 185 70

300 150 240 95

Economic cross section (mm2)

Standard (approximately)

HPE = 2000 HPE = 3000 HPE = 4000

n = 5 years 1.99 1.63 1.41 6.25

n = 8 years 1.76 1.44 1.25 6.25

n = 10 years 1.68 1.37 1.18 6.25

n = 15 years 1.56 1.27 1.10 6.25

i = 7.5%

HLE/HPE = 0.65

Copper price = € 6000

Cable price = € 6000 x 1.3 = 7800 €/ton of copper conductor

Electricity cost = 0.1 €/kWh

Scrap value = 50% of the value of new copper

Optimal current

density for lowest

NPV of losses

Economic