HELP Capacitors in circuit

In summary: At the same time, the time constant of the circuit increases making the time taken for the capacitor voltage to reach its maximum value longer. The addition of a second resistor in series will decrease the charging current even more, increasing the time taken for the voltage to reach 2V. In summary, adding a second resistor in series with a capacitor and a first resistor will result in a longer charging time for the capacitor to reach a voltage of 2V.
  • #1
101nancyma
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HELP!Capacitors in circuit

Hey guys, I have a short question here. If a resistor and a capacitor are connected in a series, it takes 2 seconds for the capacitor to to have a voltage of 2V, what happen to the voltage across the original capacitor if another same resistor is added in series? The answer is that it takes longer time for the voltage to reach 2V. I don't quite understand here since I thought the second resistor is going to consume some voltage, so the voltage of the capacitor will drop.

Thanks
 
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  • #2


Voltage can't be consumed. There is a voltage difference (or drop) across a resistor when current is flowing; the magnitude is proportional to the resistance and the current.

At any finite time, the voltage across the capacitor is always lower in the second case, as you intuited. Eventually, though, the capacitor charges up to essentially the full supply voltage, and the current (and the voltage drops across the resistors) is zero. Does this help in figuring things out?
 
  • #3


101nancyma said:
Hey guys, I have a short question here. If a resistor and a capacitor are connected in a series, it takes 2 seconds for the capacitor to to have a voltage of 2V, what happen to the voltage across the original capacitor if another same resistor is added in series? The answer is that it takes longer time for the voltage to reach 2V. I don't quite understand here since I thought the second resistor is going to consume some voltage, so the voltage of the capacitor will drop.

Thanks

The higher the resistance the smaller the charging current and so the longer the time it takes for the capacitor to charge.As charging proceeds the voltage across the capacitor increases as the current and the voltage across the resistive part of the circuit decrease.
 

1. What is a capacitor and how does it work?

A capacitor is an electronic component that stores electrical energy in the form of an electric field. It consists of two conductive plates separated by an insulating material called a dielectric. When a voltage is applied across the plates, one plate accumulates positive charges while the other accumulates negative charges, creating an electric field. This electric field stores the energy until it is needed, allowing the capacitor to discharge and release the stored energy back into the circuit.

2. How do capacitors help in a circuit?

Capacitors have several uses in a circuit, including energy storage, filtering, and timing. They are used to store energy and provide a quick burst of power when needed, which can be useful in applications such as camera flashes and motor starting. Capacitors can also act as filters, smoothing out fluctuations in voltage and reducing noise in a circuit. In addition, they can be used in timing circuits to control the rate of charge and discharge.

3. What are the different types of capacitors?

There are several types of capacitors, including ceramic, electrolytic, film, and tantalum capacitors. Ceramic capacitors are small and inexpensive, but have lower capacitance values. Electrolytic capacitors have higher capacitance values and are commonly used in power supply circuits. Film capacitors are more stable and have a wider operating temperature range, making them useful in high-performance circuits. Tantalum capacitors have a high energy density and are often used in audio and filtering applications.

4. Can capacitors be connected in series or parallel?

Yes, capacitors can be connected in both series and parallel configurations. When connected in series, the total capacitance decreases while the total voltage rating increases. When connected in parallel, the total capacitance increases while the total voltage rating stays the same. These configurations are often used to achieve specific capacitance and voltage requirements in a circuit.

5. What are some common problems with capacitors in a circuit?

Some common problems with capacitors in a circuit include leakage, breakdown, and aging. Leakage occurs when the dielectric material fails, allowing current to flow between the plates and reducing the capacitor's effectiveness. Breakdown happens when the voltage across the capacitor exceeds its rating, causing it to fail. Aging occurs over time as the materials in the capacitor degrade, reducing its capacitance and effectiveness in the circuit. It is important to choose the appropriate type and rating of capacitor for a circuit to avoid these issues.

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