ON DIMENSIONING LVDC NETWORK CAPACITANCIES AND

IMPACT ON POWERLOSSES

Andrey Lana, Tero Kaipia, Tuomo Lindh, Pasi Nuutinen, Jarmo Partanen

LUT Energy, LAPPEENRANTA UNIVERSITY OF TECHNOLOGY (LUT)

Lappeenranta, Finland

Andrey Lana – Finland – RIF Session 2 – Paper ID 1099

Frankfurt (Germany), 6-9 June 2011

Presentation outline

Introduction The LVDC network

Dimensioning of the DC capacitors Technical approach

Modelling, analysis and resulting boundaries Power losses Network transient response

Economical approach

Conclusions

Frankfurt (Germany), 6-9 June 2011

Introduction

Frankfurt (Germany), 6-9 June 2011

21/0.56/0.56 kV

20 kVMV network

PCC

AC/DC+750VDC

-750VDC

LVDC network

0.1MVA

Rectifier sideDC capacitors

Inverter sideDC capacitor

Inverter sideDC capacitor

LVDC network

Introduction

What should be taking into account for dimension of DC capacitors? How network power losses are affected by DC capacitor dimensioning? When the dimensioning from harmonic losses is economical profitable?

Frankfurt (Germany), 6-9 June 2011

Voltage ripple

Standard on low-voltage electrical installations [IEC60364] requires that DC voltage ripple (in the systems up to 1500VDC) is in 10% range of rated DC voltage.

The front-end 3 phase six pulse rectifier produces 300Hz voltage ripple.

DC capacitor on customer end

Frankfurt (Germany), 6-9 June 2011

Momentary interruptions

The voltage hold up time during MV supply interruption gives one more guideline for selecting the size of capacitors.

The difference in the energy stored in the system capacitors in the beginning and in the end of the supply interruption is equal to the energy needed for load feed.

Frankfurt (Germany), 6-9 June 2011

Maximum DC capacitance

After voltage sag etc., large amount of recharge current may flow to the DC network.

Maximum amount of recharge current should be restricted below the trip current of protection and current handling capacity of the rectifier.

Start-up control of the system is required or size of capacitors have to be limited (Nuutinen et al., START-UP OF THE LVDC DISTRIBUTION NETWORK”, CIRED 2011)

Frankfurt (Germany), 6-9 June 2011

DC network stability condition is the requirement for customer side DC capacitor size.

derived from applying Liénard–Chipart conditions on system characteristic polynomial

Boundaries for the size of the system capacitors derived from the stability conditions are less then from dc voltage ripple requirements.

The DC network stability condition

Conditions Ripple Stability

Rectifier 30 µF/kW

Inverter 1p 44 µF/kW12 µF/kW

Inverter 3p 15 µF/kW

Frankfurt (Germany), 6-9 June 2011

The DC network resonance

100

101

102

103

104

0

0.5

1

1.5

2

2.5

3

3.5

4

Mag

nitu

de (a

bs)

Bode Diagram

Frequency (Hz)

Cinv

=250uF

Cinv

=500uF

Cinv

=800uF

Cinv

=1600uF

System frequency response. Inverter DC capacitance is varied; Rectifier DC capacitance is fixed at 500µF.

System frequency response. Rectifier capacitance is varied; Inverter capacitance is fixed at 1600µF.

100

101

102

103

104

0

0.5

1

1.5

2

2.5

Magnitude (

abs)

Bode Diagram

Frequency (Hz)

Crec

=20mF;

Crec

=1mF;

Crec

=500uF;

Crec

=250uF

Crec

=20mF & Cinv

=10mF

Frankfurt (Germany), 6-9 June 2011

The DC network resonance

100

101

102

103

104

105

0

0.5

1

1.5

2

2.5

3

3.5

4

4.5

Ma

gn

itud

e (

ab

s)

Bode Diagram

Frequency (Hz)

Crec

=0uF

Crec

=14uF

Crec

=300uF

Crec

=800uF

System frequency response (from inverter load to rectifier side). Rectifier side DC capacitance is varied. Small size of the rectifier capacitance can cause possible

amplification of the high switching frequency harmonics.

Frankfurt (Germany), 6-9 June 2011

Power Losses in LVDC network

The capacitor placed on the DC terminals of a converter affect directly on the harmonic currents it excites.

The power losses due to current distortion decrease quadratic proportionally to the decrease of harmonic currents

Simulation CASE 1 CASE 2 CASE 3 CASE 4 Capacitors Rated Oversized Undersized Undersized

1.2mF 2.4mF 600µF 1.2mF

720µF 1.4mF 720µF 360µF Power losses in kW

0.485 0.11 1.51 0.54 0.074 0.072 0.067 0.081

1.31 1.31 1.36 1.31 0.31 0.325 0.37 0.355

Total 2.179 1.81 3.3 2.28

Frankfurt (Germany), 6-9 June 2011

Network transient response

Voltage dip @ 1s, t=0.04s

Main : Graphs

0.980 0.990 1.000 1.010 1.020 1.030 1.040 1.050 1.060 ... ... ...

620

820

y (V)

Link voltage at rectifier side + Link voltage at inverter side +

625 650 675 700 725 750 775 800 825

y (V)

Link voltage at rectifier side - Link voltage at inverter side -

-125 -100 -75 -50 -25

0 25 50 75

100

y (A)

Network negative pole current, - Network neutral current Network positive pole current, +

Main : Graphs

0.950 1.000 1.050 1.100 1.150 1.200 1.250 1.300 1.350 1.400 1.450 1.500 1.550 1.600 1.650 ... ... ...

640

660

680

700

720

740

760

y (V)

Link voltage at rectifier side + Link voltage at inverter side +

640

660

680

700

720

740

760

y (V)

Link voltage at rectifier side - Link voltage at inverter side -

-15.0

-10.0

-5.0

0.0

5.0

10.0

15.0 y (

A)

Network negative pole current, - Network neutral current Network positive pole current, +

HSAR from 3p short circuit @ 1s, t=0.5s

Frankfurt (Germany), 6-9 June 2011

Economical approach The increase of capacitance in the DC network to reduce the

losses is justified, if the reduction in the costs of losses is higher than the price of added capacitance.

If the price of losses is 0.05 €/kWh, peak operation time of losses 1000 h, utilisation period 40 a and the interest rate is 5 %, the unit price for power losses over the utilisation period becomes 857.95 €/kW. Thus, the costs of doubling the size of capacitors from the values used in simulation case 1 to the values used in simulation case 2 can be in maximum 323.45 € during the utilisation period regardless of the lifetime of the capacitors.

capacitorlossesh

rtransformeh

networkdc CostpricePP

Frankfurt (Germany), 6-9 June 2011

Conclusions

Voltage ripple (300Hz) due to 6-pulse bridge and due to inverter operation under unbalanced load condition (100 Hz) have to stay in standard range [IEC60364]: 10% of rated DC voltage

Need to ride through possible short MV supply interruptions due to auto-reclosing operations require energy storing in DC capacitors

System stability set requirements on minimum size of capacitors

Capacitor sizing has direct impact on harmonic losses

Resonance situations need to be checked

Charging currents may limit the size of capacitors

System protection have to be considered

Economical profitability of reducing power losses by increasing capacitance size could be estimated

Frankfurt (Germany), 6-9 June 2011

Thank you!

Andrey Lana – Finland – RIF Session 2 – Paper ID 1099