Applying FBD-power theory to analysing effective lighting devices' impact on power quality and electric grid efficiency

Aplicación de la Teoría de Potencia FBD al análisis del impacto de los dispositivos eficientes de iluminación sobre la Calidad de la Potencia y la Eficiencia de una red eléctrica

Andrés Pavas¹, Ana María Blanco², Estrella Parra³

¹ Electrical Engineer, Magister and PhD candidate in Electrical Engineering of the National University of Colombia. Professor of the National University of Colombia, Colombia. fapavasm@bt.unal.edu.co

² Electrical Engineer and Electric Power Systems Especialist of the National University of Colombia. National University of Colombia, Colombia. eeparral@unal.edu.co

³ Electrical Engineer and Magister in Electrical Engineering of the National University of Colombia, PhD candidate of the Teknische Universität Dresden - Germany. amblancoc@bt.unal.edu.co

A. Pavas, A. M. Blanco and E. Parra are with the Program of Acquisition and Analysis of Electromagnetic Signals (PAAS-UN) of the National University of Colombia.

ABSTRACT

Index terms: FBD-power theory, CFL, LED, orthogonal decomposition, efficiency, power quality.

Palabras clave: Teoría de potencia FBD, CFL, LED, descomposición ortogonal, eficiencia, calidad de potencia.

1. Introduction

Nowadays a movement from incandescent devices to newly-developed high-efficiency lighting devices has taken place, where compact fluorescent lamps (CFL) and lighting emitting diodes (LED) have been the most commonly used devices in household installations. This change has been motivated by technical and economic reasons (Blanco, 2010)(Blanco & Parra, 2010). The technical ones mainly concern reducing power consumption and improving lighting efficiency. Reduced power consumption has a direct impact on electrical energy billing and the widespread use of these devices worldwide represent a business opportunity, for producers as well as for lighting device sellers (Pileggi et al, 1993)(Watson et al, 2009).

Despite the technical and economic advantages of CFLs and LEDs, their power electronics-based drivers produce power quality disturbances that may prejudice neighbouring devices and the system where the lamps are connected. Another negative effect should be noted; CFLs and LEDs involve a pretty low power factor which means that they use electric energy inefficiently, although they transform it into light in a more effective manner than incandescent lamps. According to resolution 182544 (19th December 2010) the Colombian government will ban the production, import, sale and use of inefficient incandescent bulbs from the 31st December 2013. Consequently, a residential customer must replace incandescent bulbs with CFLs or LEDs during the next 2 years (Ministerio Minas y Energía, 2010). Widespread use of CFLs and LEDs may have a negative impact on electrical grid efficiency and power quality (Blanco & Parra, 2010)(Koch et al, 2010); Colombia is not an exception.

The use of FBD-power theory has been proposed for analysing these devices' possible impact on an electrical network. This power theory has been used recently to assess responsibilities regarding power quality (Pavas et al, 2008)(Pavas et al, 2009)(Pavas et al, 2010), showing that different phenomena may be assigned to current components, thereby allowing what exists inside the current of a CFL or a LED to be separated and quantified.

This paper presents a current decomposition proposal (Pavas et al, 2010) based on FBD-theory (DIN 40110-1, 1994)(Staudt, 2008). Measurements previously made on efficient lighting devices (Blanco & Parra, 2010) were used to carry out an efficiency and power quality analysis.

2. Measurments on CFLS and LEDS

Seventy-two samples from different manufactures were tested to obtain the CFL and LED electrical signals. The test circuit is shown in Figure 1, where a Fluke 43B power analyzer was used to measure the electrical variables and a Fluke 190B oscilloscope to obtain the lamps' voltage and current signals. Three signal periods were recorded using a 200µs sampling interval.

1. Compact fluorescent lamps were aged for a period of 100 h of normal operation before the measurements. LEDs did not require any aging prior to testing;
2. Each bulb had a 15 minute stabilisation period for CFLs and 30 minutes for LEDs before taking measurements;
3. The test voltage was stabilised within 0.5% during; stabilisation periods; this tolerance was reduced to 0.2 % when measurements were taken;
4. Supply voltage total harmonic content did not exceed 3.0 %. Harmonic content was defined as the rms summation of the individual harmonic components (100.0%);
5. Tests were carried out at rated frequency (60 Hz) and rated voltage (120V); and
6. Lamps were operated in free air in a vertical base-up position.

Table 1 gives a measurement summary for two selected samples, where voltage and current were effective values. Figure 2 displays the voltage and current waveforms. The results for the full set of bulbs were similar to the results shown below.

Figure 2. Voltage and current waveforms measured for CLS-5 and LED-123

3. Current decomposition

For a single-phase circuit feeding one load or more, voltage u at the point of common coupling (PCC) (IEEE 519, 1992) was taken as reference. Active power absorbed by or delivered to any element composing the circuit, whose current was i, could be calculated according to (1):

The notation was used to represent voltage and current inner product. By definition, the rms effective value of any signal can be evaluated following (2), for example for the voltage:

The apparent power was defined according to (3):

S = UI                            (3)

The equivalent active conductance was defined as follows:

The active current i_a and non-active current i_x components could be extracted from (4):

i_a = Gu       i_x = i -i_a                    (5)

A displaced voltage was proposed in (Pavas et al, 2009) and (Pavas et al, 2010) to take phase displacement disturbances into account (6).

u_d = u(t -T / 4)        U_d = U            (6)

The inner product of u_d and i_x produces the quantity displaced power Q_d (7), as it has been named in (Pavas et al, 2010), that led to calculating displaced susceptance B_d:

From (7) and (5), the non-active current component i_x could be split into two components, the displaced current component içd and the rest, named distorted current component i_d (8).

i_Qd = B_d U_d        i_D = i_x- i_Qd                  (8)

A brief description of each current component is listed:

]]> - Active current i_a contained the whole active power delivered to or absorbed by the circuit; it has the same waveform as reference voltage u;

- Non-active current was related to all non-active power related phenomena; it could not hold the same waveform as reference voltage u and did not transport any active power. This component was orthogonal to the total current i and to the active current i_a, i.e. = 0 and = 0;

- Only in sinusoidal conditions, displaced power Q_d has the same value as Reactive Power (IEEE 1459, 2010), representing a reciprocating power component mainly produced by the presence of inductive and capacitive elements. Displaced current Q_d

- Distorted current component i_D did not transport any active power (if there were any); it did not have the same waveform of the voltage, therefore being distorted.

The previous set of current components was orthogonal

decomposition so that the current and the rms effective values

of its components could be calculated as:

Multiplying (9) by the squared rms effective value of voltage, the apparent power could be split into components (10).

4. Results

The current decomposition method described in the previous section was applied to the measurements. For instance, the current decomposition of signals shown in Figure 2 is shown in Figures 3 and 4. Harmonic spectra for each current component are presented in Figures 5 and 6.

Active and displaced current components have the same voltage waveform and voltage distortion was less than 3.0% meaning that these current components had less than 3.0 % distortion.

The Table 2 shows each current's normalised values divided by their corresponding rms value. Component I_a/I represents the power factor, having the same value reported in Table I. Components I_Qd/I and I_D/I show how much current was non-active regarding displaced and distorted power, respectively. It can be seen from the results that the distorted power had a greater amount compared to displaced power.

The distorted current component did have a direct relationship with the harmonic distortion listed in Table I. Distorted current components contained all frequency components different to voltage frequency components. If the voltage was slightly distorted, the distorted current would be the time domain representation of the harmonic distorting current components. Therefore, the effective value of the distorted current could be used to calculate a distortion index, which would be equal to total harmonic distortion for non-distorted voltages. The distortion index based on the FDB current components was:

and DFF BD distortion factors are listed in Table 3 for the above described efficient lighting devices.

If the comparison of the current components is performed with respect to the active component, the results are as listed in the Table 4. This ratio shows the relative size of displaced and distorted components in comparison to the active one, revealing that the distorted component is higher than the active one.

5. Efficiency and power quality analysis

A typical configuration of low voltage network for Bogotá was considered to calculate impedance values range to quantify the losses caused by effective lighting devices. The Figure 7 shows a diagram of typical low voltage network topology and its components.

- Medium voltage equivalent impedance. For Bogotá's 11.4kV MV network an average 7.31kA symmetrical short circuit current was taken into account (2.26kA standard deviation). Such symmetrical fault currents are expected at the transformers' MV connection points; - A 11.4/0.208 kV transformer with rated power from 15

- kVA to 2MVA; - An overhead ACSR section. Swan to Linnet ACSR cables are usually used. At the end of this section the energy measurement device is connected, this point was considered as Point of Common Coupling for power quality purposes. The maximum length was determined according to maximum voltage drop of 2% at the for the conductor's rated current; and

- A section of copper conductor in PVC conduit tubes from the PCC to the lamp's location. Conductors from 6 AWG to 14 AWG were considered. Maximum conductor length was determined considering maximum 3% voltage drop at utilization point for the conductor's rated current.

The minimum and maximum impedance values and resistance values are listed in Table V (all values in mW). Impedance values may have been higher because the conductor's rated current was not always used, thus longer conductors were allowed. The values presented in Table V represent a set of minimum values.

The data in Table V represent a range of resistances and short circuit impedance values for assessing losses and power quality effects, respectively.

The mean number of lamps used per residential unit in Bogotá were 8 incandescent lamps (Gonzalez, 2006), four 60W and four 100W lamps. It was expected that each residential unit would use an equivalent of three 60W and two 100W lamps for five hours a day. This information was used for estimating energy losses.

A. Power and Energy Losses

Losses were determined according to the expected equivalent usage of lamps. Three cases will be considered and described in the following paragraphs:

]]> - Case 1: Three 60W plus two 100W incandescent lamps. This case represented a reference condition to reassessing the effect of CFL or LED lighting on efficiency;

- Case 2: Three 12W plus two 20W CFL lamps. A 12W CFL was expected to provide the same luminous flux as a 60W incandescent lamp, a 20W CFL can replace a 100W incandescent lamp;

- Case 3: Six 7W plus six 7W LED lamps. Although LED devices with higher rated power exist, currently 7W LED devices are commercially available in Bogota´, therefore only 7W LEDs were taken into account in this paper. Two 7W LED were expected to produce the same luminous flux as a 60W incandescent lamp and three 7W LED may substitute a 100W incandescent lamp.

The previous cases were designed bearing in mind that lighting devices usage should provide the same luminous flux for the average residential user.

Figure 8 shows device efficiency for each possible resistance. Each lighting device's efficiency was calculated as the ratio of active power absorbed by a lamp to the sum of this power and electric losses in the equivalent feeding network, mainly depending on current rms value. Efficiency was calculated as follows:

It can be observed that the less efficient lighting device is the 100W incandescent lamp, due to its higher rms current in compared to any lighting device considered in this paper. The 60W incandescent lamp and the 20W CFLs had similar efficiency. It is worth noting that the 20W CFLs had a wide range of efficiency, some of them were less efficient than a 60W incandescent bulb. 11W CFLs and 7W LEDs were more efficient, due to their lower rms current values.

The power losses caused by each type of lamp are depicted in Figure 9. The power losses were calculated from Eq. (12), yielding:

Given the power losses, an estimation of the energy losses caused by substituting incandescent lamps can be calculated. According to the most recent available statistics, there are 1.601.428 residential units in Bogotá (DANE, 2005). Determining each residential customer's precise connection impedance is currently impossible. This paper was not aimed at accurately determining the energy losses caused by efficient lighting devices compared to conventional incandescent bulbs. This paper was aimed at highlighting how different the losses are when efficient devices are used, thus a reasonable approximation would suffice.

If the location of a specific residential customer is not specified, or if its network impedance is not available, a reasonable approximation must be used. In this paper it has been supposed that all customers were distributed uniformly throughout all possible network resistance values. The network resistance values are listed in Table V. As explained before, an equivalent lighting energy consumption per residential customer may be extracted from the energy absorbed by three 60W and two100W incandescent lamps during 5 hours, or by the suitable substitutes described in Case 2 and Case 3 Figure 10.

Taken into account the power losses presented in Figure 9, the energy losses in Figure 10 and the previous considerations, the monthly minimum and maximum energy losses for each Case are listed on Table VI:

The energy losses using efficient lighting devices became reduced to around a tenth to a fourth part of the energy wasted using incandescent lamps.

The powers listed in Table VII are the expected power components absorbed by all residential customers in Bogota´ due to equivalent lighting consumption.

The power values listed in Table VII were calculated according to the following assumptions:

- Each residential installed power had a 600 VA to 1600VA rated value. Not only lighting devices were fed, the resting loads are supposed to be linear non-distorting devices.

- It was supposed that, regardless of the rated apparent power, the power factor for Case 1 was 0.9 lagging;

- The incandescent lighting devices absorbed 380W, no reactive, displaced or distorted power was generated by these bulbs; and

- For Case 2 and Case 3, 380W was subtracted and the respective active, displaced and distorted power added to the count.

Case 1 revealed that the expected power necessary to feed the lighting load energy demands was 608.92 MW for incandescent lamps; the corresponding apparent power had values from 961.45 MVA to 2563.9 MVA, as described above.

The previous conditions were caused because the CFLs and LEDs used in Colombia for residential units are low power factor loads. Regrettably, the power factor for these lighting devices is not regulated by Colombian rules; a suitable power factor is only demanded for lamps having power rated over 80W. Such lamps are rarely used in residential units.

A. Power Quality

Power quality detriment was evaluated according to IEEE 519 standard recommendations (IEEE 519, 1992). In (Blanco, 2010) and (Blanco & Parra, 2010) it has been shown that voltage distortion limits may be exceeded due to efficient lighting devices. In this paper an evaluation of current distortion is presented.

Table V listed the expected short circuit impedances for low voltage residential units are listed. The following assumptions were made to perform a current harmonics assessment:

- Maximum Demand Current I_L could have values from 5A to 15A; and

- Although other devices were able to disturb the current waveform, it was assumed that only the lighting devices cause current distortion. Therefore, the results shall represent a minimum current distortion condition.

The results for the cases proposed in the previous section are shown in Figures 11 and 12. Given that the ratio I_SC/I_L would be different for demand current values and for all possible short circuit currents, the minimum and maximum current distortion limits have been displayed in the Figures.

6. Discussion about the impact of CFLS and LEDS

Efficient lighting devices represent a significant technological advance that allows better lighting conditions which spend a lesser amount of energy. The power consumption reduction has a corresponding energy losses reduction, which also allows the usage of the saved energy in any other applications.

The most CFLs and LEDs distributed in Colombia for residential customers have a very low power factor. The non-active power components caused by efficient lighting devices are the displaced and distorted ones; displaced power components can be compensated by means of a suitable and properly placed capacitor bank.

The distorted power generated by these devices imposes a new condition on a particular system. Although the waveform distortion is a normal problem in low voltage distribution networks, the mass use of CFLs and LEDs would take the distortion to a higher level not handled before. Distorted power cannot be compensated by capacitor banks; harmonic filters and active compensators are required, thereby increasing a distribution utility's operating and maintenance costs. The most suitable solution is that regulatory policies demand the sale of efficient lighting devices having high power factors, i.e. luminously and electrically-efficient lighting devices.

Power quality is affected by efficient lighting devices mainly because of harmonic distortion. It has been shown (Blanco, 2010) (Koch et al, 2010) (Pileggi et al, 1993) that voltage distortion can be easily exceeded by CFLs and LEDs. It has been shown in this paper that current distortion limits may also be exceeded. However, if efficient lighting devices represent a limited portion of total capacity, their effect on waveform distortion can be controlled. Devices having higher power factors will cause lower distortion, so luminously and electrically efficient lighting devices will have less negative impact on energy efficiency and power quality as well.

7. Conclusions

Efficient lighting devices' current components have been analysed, providing a new approach to analysing the impact of the widespread use of CFLs and LEDs on electrical networks.

The results revealed that electrical losses related to the presence of high-efficient lighting devices were lower than those related to traditional inefficient lighting devices. Non-active power components appeared to be displaced and distorted components increasing rated power and demanding additional compensation devices in a particular system. It has been shown that a limited amount of efficient lighting devices compared to rated demand current contribute to holding harmonics within distortion limits. Efficient lighting devices must be efficient regarding both luminous source and electrical energy; a minimal impact on power usage and power quality can thus be achieved.

The authors would like to thank the Universidad Nacional de Colombia and the Research Group on Acquisition and Analysis of Electromagnetic Signals (PAAS-UN) for their support in developing this paper.

9. References

Blanco, A. M., Efecto sobre los circuitos de distribución secundarios debido al uso intensivo de Bombillas Fluorescentes Compactas y LEDs, Electrical Engineering Master Thesis (in Spanish), National University of Colombia, 2010.        [ Links ]

Blanco, A. M., Parra, E., Effects of High Penetration of CFLs and LEDs on the Distribution Networks, XIV ICHQP 2010 Bergamo - Italy, Sept 26 to 29, 2010.        [ Links ]

DANE (National Colombian Statistics Agency), Censo 2005, http://www.dane.gov.co/censo/. 2005        [ Links ]

German Electrotechnical Commission in DIN and VDE (DKE), Alternative Current Quantities in two-conductor electrical circuits, German Institute for Standards. DIN 40110-1. March. 1994.        [ Links ]

Gonzalez, F., Programa Colombiano de Normalización, acreditación, certificación y etiquetado de equipos de uso final de energía -Programa CONOCE, I Workshop Iluminación Eficiente en América Latina: Discutiendo estrategias, November 27-28, Campinas, Brasil, 2006.        [ Links ]

IEC Standard 60696 2001. Testing and measuring equipment/allowed subcontracting Self-ballasted lamps for general lighting services Performance requirements. International Electrotechnical Commission. 2001.        [ Links ]

IEC Standard 62612 2009. Self-ballasted LED-lamps for general lighting services. Performance requirements . International Electrotechnical Commission. 2009        [ Links ]

IEEE Standard 519 - 1992, Reccommended practices and requirements for harmonic control in electric power systems, IEEE-SA Standards Board, 1993.        [ Links ]

IEEE Std 1459-2010, Working Group on Nonsinusoidal Situations, Definitions for the Measurement of Electric Power Quantities under Sinusoidal, Nonsinusoidal, Balanced or Unbalanced Conditions, IEEE-SA Standards Board, March 2010.        [ Links ]

Koch, A. S., Myrzik, J. M. A., Wiesner, T., Jendernalik, L., Harmonics and resonances in the low voltage Grid caused by compact fluorescent lamps, XIV International Conference on Harmonics and Quality of Power. Bergamo, Italy. 2010.        [ Links ]

Ministerio de Minas y Energía (Colombian Energy and Mines Ministry), Resolución 182544 DE 2010 - Por la cual se hacen unas aclaraciones y modificaciones al Reglamento Técnico de Iluminación y Alumbrado Público - Retilap - y se dictan otras disposiciones, Resolution 182544. December. 2010.        [ Links ]

Pavas, A., Staudt, V., Torres-Sánchez, H., Discussion on existing methodologies for the Responsibilities Assignment Problem, International School on Nonsinusoidal Currents and Compensation ISNCC-2008. Lagow, Poland. June 10-13, 2008.        [ Links ]

Pavas, A., Torres, H., Staudt,.V., Experimental Investigation of existing Methodologies for the Responsibilities Assignment Problem, Power Tech 2009 Bucharest, June 28 to July 2, 2009.        [ Links ]

Pavas, A., Torres, H., Staudt, V., Method of Disturbances Interaction: Novel approach to assess responsibilities for stady state power quality disturbances among customers, XIV ICHQP 2010 Bergamo - Italy, Sept 26 to 29, 2010.        [ Links ]

Pileggi, D. J., Gentille, T. J., Emanuel, and A. E., The effect of modern compact fluorescent lights on voltage distortion. IEEE Transactions on Power Delivery, Vol. 8, Num. 3, July, 1993.        [ Links ]

Staudt, V., Fryze - Bucholz - Depenbrock: a time-domain power theory, International School on Nonsinusoidal Currents and Compensation ISNCC-2008. Lagow, Poland. June 10-13, 2008.        [ Links ]

Watson, N. R., Scott, T. L., Hirsch, S. J. J., Implications for distribution networks of high penetration of compact fluorescent lamps. IEEE Trans. Power. Del. vol. 24, Num 3, July 2009, pp. 1521-1528.        [ Links ] ]]> Sept 26 to 29, 2010 Bergamo DANE 2005 German Electrotechnical Commission in DIN and VDE (DKE) Marc h. 1 November 27-28 Campinas IEC 2001 IEC 2009 IEEE 1993 IEEE Marc h 20 2010 Bergamo Ministerio de Minas y Energía Dece mb er June 1 0- June 28 to July 2, 2009 Bucharest Sept 26 to 29, 2010 Bergamo July , 19 8 3 3 June 10-13, 2008 Lagow July 2 00 24 3 3 1521-1528