1.1 The Distribution System

FIGURE 1.1
Major power system components.

1.2 Distribution Substations

1. High-side and low-side switching: In Figure 1.2, the high-voltage switching is done with a simple switch. Substations that are more extensive may use high-voltage circuit breakers (CBs) in a variety of high-voltage bus designs. The low-voltage switching in Figure 1.2 is accomplished with relay-controlled CBs. In many cases, reclosers will be used in place of the relay–CB combination. Some substation designs include a low-voltage bus CB in addition to the CBs for each feeder. As is the case with the high-voltage bus, the low-voltage bus can take on a variety of designs.
2. Voltage transformation: The primary function of a distribution substation is to reduce the voltage down to the distribution voltage level. In Figure 1.2, only one transformer is shown. Other substation designs will call for two or more three-phase transformers. The substation transformers can be three-phase units or three single-phase units connected in a standard connection. There are many “standard” distribution voltage levels. Some of the common ones are 34.5, 23.9, 14.4, 13.2, 12.47 kV, and, in older systems, 4.16 kV.
3. Voltage regulation: Because the load on the feeders vary, the voltage drop between the substation and the user will vary. In order to maintain the user’s voltages within an acceptable range, the voltage at the substation needs to vary as the load varies. In Figure 1.2, the voltage is regulated by a “step-type” regulator that will vary the voltage plus or minus 10% on the low-side bus. Sometimes this function is accomplished with a “load tap changing” (LTC) transformer. The LTC changes the taps on the low-voltage windings of the transformer as the load varies. Many substation transformers will have “fixed taps” on the high-voltage winding. These are used when the source voltage is always either above or below the nominal voltage. The fixed tap settings can vary the voltage plus or minus 5%. Mostly, instead of a bus regulator, each feeder will have its own regulator. This can be in the form of a three-phase gang-operated regulator or individual phase regulators that operate independently.
4. Protection: The substation must be protected against the occurrence of short circuits. In the simple design in Figure 1.2, the only automatic protection against short circuits inside the substation is by way of the high-side fuses on the transformer. As the substation designs become more complex, more extensive protective schemes will be employed to protect the transformer, the high- and low-voltage buses, and any other piece of equipment. Individual feeder CBs or reclosers are used to provide interruption of short circuits that occur outside the substation.
5. Metering: Every substation has some form of metering. This may be as simple as an analog ammeter displaying the present value of substation current as well as the minimum and maximum currents that have occurred over a specific time period. Digital recording meters are becoming very common. These meters record the minimum, average, and maximum values of current, voltage, power, power factor, etc., over a specified time range. Typical time ranges are 15 min, 30 min, and 1 h. The digital meters may monitor the output of each substation transformer and/or the output of each feeder.

FIGURE 1.2
Simple distribution substation.

1. Circuit breakers closed: X, Y, 1, 3, 4, 6
2. Circuit breakers open: Z, 2, 5