Distribution transformer data analy

Distribution transformer data analysis
The Bangalore electricity supply company (BESCOM.) has 1, 38,618 distribution transformers (BESCOM. Annual report 2010) covering supply for eight districts. The rating of the transformer depends upon the concentration of load at a given location and they range from 2 kVA. to1000 kVA.
A distribution transformer in a residential locality is taken for study in this article. The details of the transformer are as follows:
• Transformer: TC 86; location: South Bangalore.
• Rating: 250 kVA, 11 kV/415 V, 50 Hz, 3 phase, distribution trans- former.
• Total number of poles = 82.
• Total number of consumers = 386.
• Total connected load = 782 kW.
Data set gives details regarding category of consumer, pole from which he is served and connected load or sanctioned load of individual consumers. The diagram of the distribution transformer network shows connection from the transformer to the poles and pole to pole, type of conductor used and the distance in meters.
Power supplied through distribution transformer is collected once in 30 min, continuously using Electronic Tri-vector Meter (ETVM.). The ETVM. meter constant is 80. The readings are recorded over a period of one month at 30 min interval. The average value of the power corresponding to each time interval over the entire day (0:00–23:30 h) is calculated using the readings for 31 days down- loaded from the meter. The average daily variation of the load on the distribution transformer so obtained is used in this work. The plot of average variation of power with time of the day is shown in F4.
Peaking of the load curve is observed in the morning as well as in the evening hours. It is seen from the graph that maximum peaking takes place in the morning hours between 6.00 am and 8.30 am. One of the reasons for peaking during morning hours is the use of electricity for pumping water to an overhead tank in every domestic consumer premises.
5. Investigations on policy impact
The distribution transformer under study is in a residential local- ity. It is found that 216 domestic consumers are having a connected load of 2 kW and above. A large number of them are having 3 kW which is the typical connected load of one house hold. The domestic consumers, with 2 kW and more connected load, have a motor- pump to fill their overhead tanks. It is a common practice in the city that water-pumps are switched on in the morning hours. This coincides with the peaking on the transformer. These motor pumps for use in houses, are generally 0.37 kW and are operated for about an hour or less. These 0.37 kW motor pumps are commonly used for a vertical lift of 15 m. The following investigations are carried out by replacing the 0.37 kW AC motor pumps by solar DC pumps.
5.1. Impact on peak shaving it is observed from the graph in Fig. 4 that maximum peaking takes place in morning hours between 6.00 am and 8.30 am. With the use of solar water pumps, motor load for pumping water gets eliminated from the grid supply.
It is estimated that out of 216 domestic consumers, if 150 (70%) of them operate their pumps from PV panels, a net reduction of 55.5 kW of total connected load on the transformer is observed. Similarly, if the remaining 66 (30%) pumps, which are generally switched on at night between 7.30 pm and 10 pm, also employ solar water pumps, a further reduction of 24.42 kW in connected load is observed. The resulting load on the distribution transformer during peak load hours is shown in Table 3.
Plot of power in kW and time in hours (0:30–23:30 h) is shown in Fig. 5. Peak load reduction with solar pumps in operation is observed from the graph.
5.2. Impact on line losses
The network of load on the secondary side of the local distribution transformer is very complicated with many poles spread in many streets and inter-connected with other poles. The consumer load is connected to the nearest pole via service mains. The distribution transformer diagram of T-86 is shown in Fig. 6 (service mains not shown). It is a single line diagram showing electrical connection between poles, distance and total connected load on each pole. In this secondary distribution network, three different types of conductors namely rabbit, squirrel and weasel are used. The resistance and reactance of these conductors per kilo meter length of the wire are listed in Table4.
 
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