Potentiometer to measure cell voltage

In summary, for the Experiment to measure the cell voltage, a thin wire is connected into a circuit with a potential difference of Vac or the voltage drop. Depending on the voltage drop, the resistance on the wire changes. With zero current I_2 it is possible to find the voltage drop across the wire. I_3 is also calculated from I_2. If I_1 is known, the voltage across the wire resistor can be calculated. If V0 is changed so as to allow a null current reading, then the equation for Vac can be solved.
  • #1
dba
32
0

Homework Statement


http://meinprojekt.hostzi.com/images/Picture2.jpg
We did an experiment to measure E mf or the cell voltage of bateries. A thin wire (slide-wire potentiometer) is connected into the circuit. From point a to c the resistance along the wire is 36 Ohm. Depending on where the slider is placed (point b) the resistance along the wire changes in the relation
Lb/Lc = Rb/Rc.
Lb: length from a to b
Lc: length from a to c
Rb: resistance on length a-b
Rc: resistance on length a-c

We set the potential difference Vac or the voltage drop for the wire portion to 4V (connected from point a to point c) and slided the contact so that the current I_2 was zero.
With the length of the wire and the voltage drop we could calculate the cell voltage of the batery. the voltage of the power supply was V0=20V. I understood this so far.

Then we decreased V0 to 5V and tried to find the point with the slider where the current was zero. We could not find this point.

The question now is, why we could not find the null current for this setting. We had a batery with 1.5V (1D cell).

My second question is about the given equation:
Vac = [Rc/(R+Rc)] where R is the 150 Ohm resistor.

Where does the Rc/(R+Rc) comes from?


Homework Equations


for I_2 = 0
I_3=I_2

Vac=I_1*Rc

Lb/Lc = [(R+Rc)/Rc] * (E/V0) where E is the cell voltage E= Vac


The Attempt at a Solution



For the first part I was trying to look at the entire circuit. I have two voltage supplies. V0=5V and the batery V=1.5V. I have also resistor R=150 Ohm and the wire with adjustable Rb. The resistors ar in parallel which means that one equivalent resistor would be Req= (R*Rb)/(R+rb). The current I_2 for the lower circuit should be zero. I_3 needs to be zero also, since it is part of the same "loop." So I would have I_1.

But I am stuck how I can explain the question:
For a given V_) it is possible that the unknown E mf may be such that a null current may not be found. How should V0 be changed so as to allow a null current reading?


Thanks for any help.
 
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  • #2
The condition for I2 to be zero is that the slider must contact a point where the potential Vab on the wire is equal to the potential of the cell under test. When these potentials are equal, there is no potential difference to drive current I2.

Consider for a moment just the portion of the circuit that includes the power supply, the 150 Ohm resistor, and the 36 Ohm length of wire. These components form a voltage divider. What is the potential difference, Vac, across the wire when the supply is 20V? How about when it is 4V?
 
  • #3
I am not sure about this but Vac = I_1 * RC with Rc = 36 Ohm but how do I include the 20V and the other 150 Ohm? I think my problem is to understand how two voltage supplies in a circuit are related.
 
Last edited:
  • #4
Can you calculate I1 given the total resistance in the loop?
 
  • #5
V=I*R
I_1 = V/R

V=20V
Resistors R=150 Ohm and Rc=36 Ohm are parallel, so
R_equivalent = R*Rc/R+Rc = (150*36)/(150+36) = 900/31 Ohm

I_1 = 20V/ (900/31)Ohm = 0.68a

I am still not sure about the second voltage supply of the battery. So, i calculated it now as it wasn't there.
 
  • #6
The 150 Ohm resistor and the 36 Ohm resistance are NOT in parallel, they are in series.
 
  • #7
Ok, if they are in series than R_equivalent = R+Rc = 150 + 36 = 186 Ohm
And I_1 = 20V/186 Ohm = 0.1 A
 
  • #8
dba said:
Ok, if they are in series than R_equivalent = R+Rc = 150 + 36 = 186 Ohm
And I_1 = 20V/186 Ohm = 0.1 A

Okay, that's the current in the series circuit consisting of the voltage source and the two resistances alone (we're still ignoring the other cell and its resistance at the moment), when the voltage source is 20V. Given that value for the current, what is the voltage across the wire resistor from end to end?

Now repeat the calculation for when the voltage source is reduced to 4V.
 
  • #9
For V0=20V circuit
Rc=36 Ohm, I_1=0.1A
Vab = 0.1A * 36 Ohm = 3.6 Volt

For V0=4V
I_1 = 4V/186 Ohm = 0.02 A
Vab = 0.02 A * 36 Ohm = 0.72 Volt
 
  • #10
dba said:
For V0=20V circuit
Rc=36 Ohm, I_1=0.1A
Vab = 0.1A * 36 Ohm = 3.6 Volt

So, the slider when moving from point a to point c can "pick off" any potential from 0 to 3.6V when the voltage source is 20V.

What is the range when the voltage source is 4V?
 
  • #11
Any potential from 0 to 0.72 Volt which is smaller than the voltage of the battery of 1.5 Volt. And Vab has to be equal to the battery voltage to allow the current to be zero. Is that correct? is that the reason why I could not find the null current?
 
  • #12
dba said:
Any potential from 0 to 0.72 Volt which is smaller than the voltage of the battery of 1.5 Volt. And Vab has to be equal to the battery voltage to allow the current to be zero. Is that correct? is that the reason why I could not find the null current?

Yes! You've got it.
 
  • #13
Thank you so much for your help!
 

FAQ: Potentiometer to measure cell voltage

1. What is a potentiometer?

A potentiometer is an electronic instrument that measures the voltage of a cell or battery. It consists of a resistive element, a sliding contact, and a measuring device. The sliding contact can be moved along the resistive element to vary the resistance and thus measure the voltage of the cell.

2. How does a potentiometer measure cell voltage?

A potentiometer works by comparing the voltage of the cell to a known voltage. The sliding contact is moved along the resistive element until the two voltages are equal and the measuring device indicates the voltage of the cell.

3. What is the benefit of using a potentiometer to measure cell voltage?

A potentiometer offers a more accurate and precise measurement of cell voltage compared to other methods, such as using a voltmeter. It also allows for adjustments to be made to the cell voltage if necessary.

4. Can a potentiometer be used to measure the voltage of any type of cell?

Yes, a potentiometer can be used to measure the voltage of any type of cell, as long as it is within the range of the instrument. However, the resistive element may need to be adjusted for different types of cells to ensure accurate measurements.

5. Are there any limitations to using a potentiometer to measure cell voltage?

One limitation of using a potentiometer is that it requires a known voltage to compare the cell voltage to. This means it may not be suitable for measuring the voltage of cells with unknown or rapidly changing voltages. Additionally, the potentiometer may introduce some error in the measurement due to factors such as temperature and resistance in the circuit.

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