Capacitive Time Constant

CAPACITANCE DC Circuits Example 3: Find the total capacitance of three capacitors in parallel, if the values are 15 µF-50 V, 10 µF-100 V, and 3 µF-150 V (Figure 17). What would be the working voltage? Figure 17 Example 3 - Capacitors Connected in Parallel C_T C₁ C₂ C₃ 15µ F 10µ F 3µ F C_T 28µ F The working voltage of a group of capacitors in parallel is only as high as the lowest working voltage of an individual capacitor. Therefore, the working voltage of this combination is only 50 volts. Capacitive Time Constant When a capacitor is connected to a DC voltage source, it charges very rapidly. If no resistance was present in the charging circuit, the capacitor would become charged almost instantaneously. Resistance in a circuit will cause a delay in the time for charging a capacitor. The exact time required to charge a capacitor depends on the resistance (R) and the capacitance (C) in the charging circuit. Equation (3-13) illustrates this relationship. T_C = RC (3-13) where T_C = capacitive time constant (sec) R = resistance (ohms) C = capacitance (farad) The capacitive time constant is the time required for the capacitor to charge to 63.2 percent of its fully charged voltage. In the following time constants, the capacitor will charge an additional 63.2 percent of the remaining voltage. The capacitor is considered fully charged after a period of five time constants (Figure 18). ES-03 Page 16 Rev. 0