Buck converter inductor current at start up

In summary, when the switch is turned off, the inductor current ramps up to a high value and then starts to decay back to the base value over a period of 0.5ms. After 0.5ms, the inductor current will be the same as the load current.
  • #1
likephysics
636
2
I am trying to understand the inductor current ramp up to steady state in a buck converter.

I don't understand why the inductor current slope is not steep in the beginning.

Let's say Vin=12v, Vo desired across the capacitor is 5V.

Switch turns ON, Inductor current ramps up. Switch goes OFF, Inductor current starts charging the capacitor for a time interval Δt. Now the cap is charged to say, 1v. In the next cycle, the inductor current has increased, it again charges the cap for Δt. Now the cap voltage goes to 2v. This goes on.
But I don't understand why the current slope becomes steeper.
 

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  • #2
likephysics said:
I am trying to understand the inductor current ramp up to steady state in a buck converter.

I don't understand why the inductor current slope is not steep in the beginning.

Let's say Vin=12v, Vo desired across the capacitor is 5V.

Switch turns ON, Inductor current ramps up. Switch goes OFF, Inductor current starts charging the capacitor for a time interval Δt. Now the cap is charged to say, 1v. In the next cycle, the inductor current has increased, it again charges the cap for Δt. Now the cap voltage goes to 2v. This goes on.
But I don't understand why the current slope becomes steeper.

What is the voltage at the input side of the inductor during the OFF portion of the cycle?

The slope of the OFF portion of the current waveform is determined by the voltage across the inductor during the OFF portion of the cycle...
 
  • #3
berkeman said:
What is the voltage at the input side of the inductor during the OFF portion of the cycle?

The slope of the OFF portion of the current waveform is determined by the voltage across the inductor during the OFF portion of the cycle...

How do you find out the voltage across the inductor during the off portion?
The ckt is same as - http://en.wikipedia.org/wiki/File:Buck_circuit_diagram.svg
Load is capacitor.
At the moment the switch is turned OFF, inductor voltage is 12V.
 
  • #4
likephysics said:
At the moment the switch is turned OFF, inductor voltage is 12V.
Inductor voltage = voltage across the inductor
One side of the inductor is held at either 12v or -0.7v, the other side is the load voltage. Subtract the two to find the difference.
 
  • #5
NascentOxygen said:
Inductor voltage = voltage across the inductor
One side of the inductor is held at either 12v or -0.7v, the other side is the load voltage. Subtract the two to find the difference.

Okay. Inductor one side is 12V, connected to a capacitor and a diode in series. The diode voltage is 0.7v, what about the capacitor voltage?
 
  • #6
3 things to keep in mind:

1) You can not instantaneously change the current in an indutor. At the moment you "turn on" the inductor sees the full voltage and has 0 current.
2) There is always some other resistance / impedance - esp from the supply to the circuit, this is usually a critical limit.
3) Also the pulse width - should be much less than the time constant (over which you will see the effect of the inductor. If you look at the V and I for the inductor over time ( many on-off cycles / pulses) the curve will look more like an typical inductor curve. The model typically used within one pulse is a triangle - not a curve.

During the off portion - the current wants to stay the same - and decreases as the load absorbs the energy now stored in the inductor.

A capacitor is used to stabilize voltage ( by being an instantaneous current source) only makes sense here before the switch or after the inductor ( parallel with the load).

The trick is to realize that the VOLTAGE of the inductor can instantaneously change - so the instant the switch opens - it goes from absorbing energy to releasing energy - so what happens to the voltage across the inductor?? it should be clear - it reverses if there is any load current.

If the load is a capacitor - when the circuit reaches steady state the I goes to 0 ( cap is fully charged), then the diode is reverse biased and the cap just sits there charged.
 
  • #7
When the circuit operates correctly, the capacitor voltage gets pumped up in steps, until it levels out at its final value.
 
  • #8
Okay. Let me plug in some numbers.

Lets say input voltage is 12v, L=100mH, C=1uF, switching freq=1KHz ( ignore diode drop).
Let's say Ton=Toff=0.5ms (is this valid)?

So final inductor volage after Ton will be 12v.

V = L Δi/Δt
12 = 0.1 (di/0.5m)

Δi= 60mA.

Toff is 0.5ms.

capacitor voltage Vc = 1/c ∫I dt

Vc = 1E6 (60mA*0.5mS)
Vc = 30V ?
 
  • #9
The V ind after T on is coming to 0, not 12 V ( Assuming we are at steady state)

Here is a good reference : http://www.ti.com/lit/sg/sluw001d/sluw001d.pdf [Broken]

Basic Buck and Boost converter voltages are relative to the duty cycle ( Ton:Toff)
 
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  • #10
likephysics said:
So final inductor volage after Ton will be 12v.
At any time while switch is closed, for inductor voltage =12v the load voltage must =0.
If load voltage is not equal to 0, then inductor voltage cannot be 12v.
 
  • #11
Okay okay. VL is 0 at the end of Ton.
But it's limited to (Vo+Vd) when the switch opens, right?

Also capacitor voltage can only go upto Vo (5V).

Vc = ΔI ΔT /C

5 = 60mA (ΔT)/1E6

ΔT = 5m/60 = 83uSecs

So the cap gets charged really quickly compared to Toff.
 
  • #12
likephysics said:
Okay okay. VL is 0 at the end of Ton.
Probably not 0, but certainly heading that way. Dropping away.
But it's limited to (Vo+Vd) when the switch opens, right?
Yes

Also capacitor voltage can only go upto Vo (5V).

Vc = ΔI ΔT /C

5 = 60mA (ΔT)/1E6

ΔT = 5m/60 = 83uSecs

So the cap gets charged really quickly compared to Toff.
That 60mA is probably an overestimate. You arrived at that value by applying 12v to the inductor and assuming that while the capacitor charges its voltage remains at (or close to) 0.
 
  • #13
Ok, Initially the load voltage is 0v.
But then, max VL is (12-Vo)
 
  • #14
For Vin = 12V and Vout = 6V and RL = 6Ω ( load current = 1A) and F = 1K.
The duty cycle = 0.5 so Ton = Toff = 500us and the L = 10mH

At the beginning Vout is 0V.

When T1 is ON voltage across the coil is equal to 12V.
At the end of time ON time coil current reaches the value.

I _(0.5ms) = ( 12V * 500us) / 10mH = 0.6A So to output voltage will reach 3.6V

So now at time >500us T1 is OFF and we have 3.6V across the coil.
So the current wail drop to

I = ( 3.6V * 500us)/10mH = 0.18A

I_(1ms) = 0.6A - 0.18 = 0.42A and the output voltage will drop to 2.5V

But now at time 1ms T1 is ON.

The voltage across the coil is equal to
12 - 2.5V = 9.5V

and the coil current will ramp up.

I = (9.5V * 500us) / 10mH = 0.475A

So at time 1.5ms Icoil = Iload = 0.42A + 0.475A = 0.895A and the load voltage
V = 5.37V

At T = 1.5ms T1 is OFF and the coil current will ramp down.
The voltage across the coil is now equal to 5.37V.
And at the end of the OFF time (2ms) coil current drop to :

I = ( 5.37 * 500us) / 10mH = 0.268A


I_(2ms) = 0.895A - 0.2685 = 0.626A and the load voltage

V_(2ms) = 3.759V

Now T1 is ON up to 2.5ms

I = ( ( 12V - 3.759V) * 500us)/10mH = 0.412A

I_(2.5ms) = 0.626 + 0.412A = 1.038A and Vout = 6.228V


At time 2.5mS T1 is OFF until 3ms

So the current will drops to

I = ( 6.228V * 500us/10mH = 0.3114A

I_(3ms) = 1.038A - 0.3114A = 0.7266A---> Vout = 4.3596V

T1 --> ON up to 3.5ms

I = (( 12V - 4.3596V) * 500us)/10mH = 0.382A

I_(3.5ms) = 0.382A + 0.7266A = 1.10862A ---> Vout = 6.63172V

And this will continue until a steady state is reach.
 
  • #15
Jony130 said:
For Vin = 12V and Vout = 6V and RL = 6Ω ( load current = 1A) and F = 1K.
The duty cycle = 0.5 so Ton = Toff = 500us and the L = 10mH

At the beginning Vout is 0V.

When T1 is ON voltage across the coil is equal to 12V.
Only at the initial moment is voltage across the inductor 12v; as the capacitor charges the voltage across L falls.
At the end of time ON time coil current reaches the value.

I _(0.5ms) = ( 12V * 500us) / 10mH = 0.6A So to output voltage will reach 3.6V
This is a very rough-and-ready estimation. Using your figures, the inductor voltage is only 8.4v towards the end of the ON period, so relying on 12v gives an overestimate.

Also, you are totally overlooking the fact that some of this inductor current powers the load (the 6Ω resistor) and does not add to the charge on the capacitor. So your figure of 3.6v is going to be way off, and for two reasons you have overlooked/forgotten/not mentioned.
So now at time >500us T1 is OFF and we have 3.6V across the coil.
So the current wail drop to

I = ( 3.6V * 500us)/10mH = 0.18A
Current in the inductor doesn't "drop", it smoothly ramps from one value to another. Apart from this, I don't think your figure of 0.18A is right.
I_(1ms) = 0.6A - 0.18 = 0.42A and the output voltage will drop to 2.5V
How can determine this without even mentioning the load resistorhttps://www.physicsforums.com/images/icons/icon5.gif [Broken]

Your attempt to explain the workings of this are a good start, Jony130, but a shaky start, and would not get even half marks on a test paper. https://www.physicsforums.com/images/icons/icon9.gif [Broken]
 
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  • #16
I know that my analysis is very simplified. I assume RL = 6Ω without output capacitor.
 

1. What is a buck converter inductor?

A buck converter inductor is a type of inductor used in a buck converter circuit. It is responsible for storing energy and releasing it to the load in a controlled manner.

2. How does the inductor current behave at start up in a buck converter?

At start up, the inductor current in a buck converter rises rapidly and then settles to a steady state value. This is known as the inrush current and is necessary for the converter to reach its stable operating point.

3. What factors affect the inductor current at start up in a buck converter?

The inductor value, input voltage, and load resistance all play a role in determining the inductor current at start up in a buck converter. Higher inductance and input voltage result in a higher inrush current, while a higher load resistance leads to a lower inrush current.

4. Why is it important to control the inductor current at start up in a buck converter?

Controlling the inductor current at start up is crucial for the stability and efficiency of a buck converter. Too high of an inrush current can cause damage to components, while too low of an inductor current can result in poor regulation and performance.

5. What methods are used to control the inductor current at start up in a buck converter?

There are several methods for controlling the inductor current at start up in a buck converter, such as using a soft start circuit, adding a pre-charge resistor, or using a current limit circuit. These methods help to gradually increase the inductor current and prevent excessive inrush current.

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