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Chapter 21: Q35CQ (page 773)

When discharging a capacitor, as discussed in conjunction with Figure 21.39, how long does it take for the voltage on the capacitor to reach zero? Is this a problem?

Short Answer

Expert verified

Infinite time, the small remaining charge can leak.

Step by step solution

01

Discharging a capacitor

The discharging of the capacitor is,

\({\rm{V = }}{{\rm{V}}_{\rm{0}}}{{\rm{e}}^{\frac{{{\rm{ - t}}}}{{{\rm{RC}}}}}}\)

Here,\({{\rm{V}}_{\rm{0}}}\)is the voltage across the capacitor when it is charged to the maximum,\({\rm{t}}\)is the time from the initiation of discharging,\({\rm{R}}\)is the resistance in the circuit, and\({\rm{C}}\)is the value of capacitance of the capacitor.

02

 Step 2: Explanation

The capacitor discharges as \({{\rm{e}}^{{\rm{ - t}}}}\), which means that it decays exponentially with time.

However, because it is asymptotic to the zero line on the charge axis, this variable never approaches zero.

This is a concern since a small amount of charge stays in the capacitor, which can lead to problems such as static leakage and other problems.

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Most popular questions from this chapter

A 2.00-anda7.50-μFcapacitor can be connected in series or parallel, as can a 25.0- and a 100- resistor. Calculate the four RCtime constants possible from connecting the resulting capacitance and resistance in series.

A \(160 - \mu F\)capacitor charged to \(450\;V\)is discharged through a \(31.2 - k\Omega \)resistor. (a) Find the time constant.(b) Calculate the temperature increase of the resistor, given that its mass is \(2.50\;g\)and its specific heat is \(1.67\frac{{kJ}}{{kg{ \cdot ^\circ }C}}\), noting that most of the thermal energy is retained in the short time of the discharge. (c) Calculate the new resistance, assuming it is pure carbon. (d) Does this change in resistance seem significant?

Referring to Figure 21.6, (a) CalculateP3and note how it compares withP3found in the first two example problems in this module. (b) Find the total power supplied by the source and compare it with the sum of the powers dissipated by the resistors.

There is a voltage across an open switch, such as in Figure 21.43. Why, then, is the power dissipated by the open switch small.

To measure currents in Figure \({\rm{21}}{\rm{.49}}\), you would replace a wire between two points with an ammeter. Specify the points between which you would place an ammeter to measure the following: (a) the total current; (b) the current flowing through \({{\rm{R}}_{\rm{1}}}\); (c) through \({{\rm{R}}_{\rm{2}}}\) ; (d) through \({{\rm{R}}_{\rm{3}}}\) . Note that there may be more than one answer to each part.
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