Test No.2

Figure 4.5: Map of the county Skåne (Scania) in the south part of Sweden.

A simplified scheme of the test area is shown in Figure 4.6. It includes the distribution system from the 130 kV-level and downward. At the 130 kV bus, two three windings 100/100/40MVA, 130/50/20 kV tap changing transformers are connected in parallel. They are both operating during winter due to the increase in power demand, while on summer only one of them is active. On the 130 kV bus bar, two manually controlled capacitor banks of 20 and 40 MVar respectively are connected. They make reactive compensation from 20 to 60 MVar possible. The connection and disconnection of the capacitor is controlled from the operation center in Malmö twice a day, morning and evening. However, and based on the recorded data, it will be shown further in this thesis that this switching

operation is quite irregular in typical daily operations. The tap changers, which are controlling the voltage at the 20 kV-level, are placed on the 130 kV windings. The minimum tap size of the tap changers at Tomelilla is equal to 1.67 % of the voltage level.

Figure 4.6: Simplified test system at Tomelilla. Measurements of voltage, active and reactive power, are expressed in kV, MW and MVar respectively.

A load of about 62 MW is connected to the 20 kV side of the transformers.

A large percent of the load corresponds to residential and rural type, around 53%. This residential load includes mainly private houses, block of flats and public service buildings. On the other hand, the rural type aggregates the demand of the countryside, i.e. farms of different sizes with own production, such as corn, milk and meat production. The residential and rural load mainly corresponds to electric heating, radiators and boilers, as well as some heat pumps and electric/oil combined heating. A large industrial customer, around 15 MW, and other minor industries are directly

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fed from the 20 kV level; their load is primarily constituted of induction motors and electric heating.

It has to be taken into account that the load composition will depend not only on the type -- residential, rural, commercial and industrial -- but also on weather conditions and variations in load demand during the measurements. As an example, the effect of electric heating will be larger during cold periods and therefore in wintertime. During the summer time, the heating demand will increase and consequently the electric heating effect in the load, but, and due to air conditioner actions, the percent of induction motors in the total load may increase. Figure 4.7 shows the composition of the load at the 20 kV-level. It is classified in residential, rural, industrial and commercial types. More details about the composition of the load are shown in Appendix I.

Figure 4.7: Composition of load at the 20 kV-level at Tomelilla.

The 50 kV side of the transformers is connected to a 50/20 kV substation at Järrestad. Besides, the 50 kV bus feeds mainly secondary distributors, i.e.

companies supplying power to the cities Ystad and Simrishamn. Part of the load on the 50 kV bus emanates from a converter station for the railway.

Further analysis at this level is not included in this study.

4.3.2. Measurement description

The measurement equipment is a Macintosh computer with 4 GBytes hard disk capacity, which allocates an analog input card, National Instruments

Composition of Load at the 20 kV-level at Tomelilla

8.60%

22.26%

30.99% 38.13%

0.00%

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20.00%

30.00%

40.00%

50.00%

Commercial Rural Residential Industrial Load Types

MIO16, and software for the configuration and activation of the functions of the card (LABVIEW). Thirteen different channels have been used during the acquisition, see Table 4.1.

TOMELILLA MEASUREMENTS

CH OBJECT SIGNAL MEASURE VALUE

OUT [ V ]

VOLTAGE RATIO

CONVERSION FACTORS

0 T1/T2 20 kV U 0-22 V 0-5 22/0.11 0.012695 kV/bit

1 T1/T2 50 kV U 0-55 V 0-5 55/0.11 0.03222 kV/bit

2 TLA-BOY U 0-137.5 V 0-5 132/0.11 0.080566 kV/bit

3 ÅHS V-TLA U 0-137.5 V 0-5 132/0.11 0.080566 kV/bit

4 VBD-TLA U 0-137.5 V 0-5 132/0.11 0.080566 kV/bit

5 T1 20 kV P 0-60 MW 0-5 22/0.11 0.0292 MW/bit

6 T1 20 kV Q -30-0-30 MVar 0-5 22/0.11 0.0292MVar/bit-30 MVar

7 T2 20 kV P 0-60 MW 0-5 22/0.11 0.0292 MW/bit

8 T2 20 kV Q -30-0-30 MVar 0-5 22/0.11 0.0292MVar/bit-30 MVar

9 T1 50 kV P 0-130 MW 0-5 55/0.11 0.063476 MW/bit

10 T1 50 kV Q -70-0-70 MVar 0-5 55/0.11 0.068359MVar/bit-70 MVar

11 T2 50 kV P 0-130 MW 0-5 55/0.11 0.063476 MW/bit

12 T2 50 kV Q -70-0-70 MVar 0-5 55/0.11 0.068359MVar/bit-70 MVar

Table 4.1: Characteristics of the signals chosen for the acquisition, and conversion factors between the substation and the analog input card.

Note that four different signals are necessary for measuring active and reactive load on the 50 kV and 20 kV sides of the three winding transformers. During winter both transformers will be connected, and the active and reactive load consumption will be the sum of the recordings at T1 and T2. During the summer one of the transformers will be disconnected, so two of the signals will be zero. The data is sampled with a frequency of 3 Hz, and it is stored continuously in files of 12 hours duration, labelled with date and time. The program includes a real time monitoring of the size of the files and the recorded values in the substation expressed in binary code. Different transformation factors are necessary to convert directly, on real time, from binary code to real numbers (see Table 4.1). Since the aim is to analyze the load-voltage characteristic in a time frame of about 10 seconds to 10 minutes, the choice of the proper sampling frequency is crucial for the acquisition of significant information during the test. The chosen frequency of 3 Hz is sufficiently fast to capture the transient dynamics of the load. Spontaneous variations due to load switching operations from the customer side are also captured.

4.3.3 Measurement results

The measurements presented in the thesis correspond to recorded voltage, active and reactive load at 130 kV, 20 kV and 50 kV under the period July 2001 to June 2002. Due to the length of the test and to technical problems in the hardware, some periods of time are missing, however the acquired data fulfils the requirements of this project. The available data from the recording process is presented in Figure 4.8.

Figure 4.8: The available data from the recording process.