One valuable thing to understand about the buck circuit is ...



Simulations with the BUCK Topology

EE562 POWER ELECTRONICS I

COLORADO STATE UNIVERSITY

Modified by Colorado State University student

Minh Anh Thi Nguyen

EXTRA CREDIT QUESTIONS

One valuable thing to understand about the buck circuit is the input current from the source and how we can make it better.

Simulate the following circuit to steady state:

[pic]

Look at the current from the source V1:

[pic]

Look a little closer:

[pic]

Note: this is only ½ the load current (obviously because the current only flows when the switch is on…. And this case is a 50% duty cycle).

Just to verify, let’s look at the diode current:

[pic]

You can see it supplies the rest of the inductor load current.

Now – returning to the current through V1. This choppy current will likely upset other devices if they are also powered from V1. The current pulses are also a prime source of EMI since the current can be large and the edge transitions are fast. For both of these reasons, we would add a filter.

Let’s add an LC filter just to see what it does.

[pic]

Now looking at the input current from V1 and we see:

[pic]

Why is this ringing like this? What is difference between the input current before and after the filter? Can we change the frequency of this ringing? How?

Now let’s add a typical ESR to the input capacitor and see what happens:

[pic]

[pic]

The ringing is damped this time. What are other ways the ringing could be damped? (The inductor likely will have some resistance in the wires) Why would we WANT the ESR for this cap? (Instead of a ceramic with extremely low ESR)

Now let’s look at the current in the inductor and the current in the capacitor:

[pic]

A little closer:

[pic]

Note: The inductor current is the same as the current from V1. We can say that the inductor supplies the DC current and the capacitor is delivering the AC current. So – how would we select the component ratings for this filter? Hint: Let’s change the traces to look at the Irms of the capacitor and the Iavg (average current) of the inductor:

[pic]

The steady state average current through the inductor is 1.17A

The steady state rms current through the capacitor is 1.4Arms.

Inductors are sized based on the max DC current. We would probably add some margin and pick an inductor that was at least capable of 2A, maybe more depending how conservative we want to be.

Capacitors (aluminum electrolytics) data sheets specify the maximum ripple current rating (Irms). This can also be called the self heating loss. The lifetime of the part will depend on the Irms, the ESR, the package size, and the temperature.

For this capacitor, we would want to choose the Irms rating at least at 2A. We could use two capacitors with each having an RMS rating of 1A. This would depend on how much the capacitors cost and what is available.

Find a capacitor that would work in our input filter: (Hint, Rubycon ZL series has some. You can find the specification sheet at: ). Make sure that the rated voltage of the part is at least 1.5 times the input voltage (or at least 36V). Some people use 2x.

I found a Rubycon ZL 470 cap:

V=50V

C=470uF

Irms=2050mA

ESR=27mohms

What changes when we put this cap in vs. the 100uF cap we initially started with?

(Hint: resonant frequency, Irms changes a bit due to lower ESR)

What is the input voltage at the top of the switch? (It isn’t perfect DC anymore --- which in real life it never is). How will that affect our converter and the output? Look at the output voltage ripple at steady state and compare to the peak to peak ripple you measured on page 6 (question 3). Is there any difference?

[pic]

-----------------------

4.0A

2.0A

0A

-2.0A

- I(V1)

1.0ms

0.9ms

0.8ms

0.7ms

0.6ms

0.5ms

0.4ms

0.3ms

0.2ms

0.1ms

0s

6.0A

Time

Time

400us

420us

440us

460us

480us

500us

520us

540us

560us

580us

600us

- I(V1)

0A

1.0A

2.0A

3.0A

4.0A

Time

4.0A

2.0A

0A

-2.0A

- I(V1)

4.0ms

3.5ms

3.0ms

2.5ms

2.0ms

1.5ms

1.0ms

0.5ms

0s

Time

Time

0s

0.1ms

0.2ms

0.3ms

0.4ms

0.5ms

0.6ms

0.7ms

0.8ms

0.9ms

1.0ms

I(D1)

-2.0A

0A

2.0A

4.0A

6.0A

0s

0.5ms

1.0ms

1.5ms

2.0ms

2.5ms

3.0ms

3.5ms

4.0ms

- I(V1)

-2.0A

0A

2.0A

4.0A

6.0A

Time

0s

0.5ms

1.0ms

1.5ms

2.0ms

2.5ms

3.0ms

3.5ms

4.0ms

I(C6)

-4.0A

0A

4.0A

I(L7)

-4.0A

0A

4.0A

SEL>>

Time

2.00ms

2.05ms

2.10ms

2.15ms

2.20ms

2.25ms

2.30ms

2.35ms

2.40ms

2.45ms

2.50ms

I(C6)

-4.0A

0A

4.0A

SEL>>

I(L7)

1.00A

1.25A

1.50A

Time

0s

0.5ms

1.0ms

1.5ms

2.0ms

2.5ms

3.0ms

3.5ms

4.0ms

RMS(I(C6))

0A

2.0A

4.0A

SEL>>

AVG(I(L7))

0A

1.0A

2.0A

Time

3.60ms

3.62ms

3.64ms

3.66ms

3.68ms

3.70ms

3.72ms

3.74ms

3.76ms

3.78ms

V(C1:1)

11.00V

12.00V

10.01V

12.69V

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