SLUA560D June 2011 – March 2022 UCC28950 , UCC28950-Q1 , UCC28951 , UCC28951-Q1

4 Transformer Calculations (T1)

The PSFB uses a transformer to deliver energy from the primary to the secondary. The voltage is stepped up or down through the transformers turns ratio (a1).

Equation 2.

a 1 = \frac{N_{P}}{N_{S}} = \frac{V_{I N}}{V_{O U T}}

Estimated FET voltage drop (V_RDSON):

Equation 3.

V_{R D S O N} = 0.3 V

Select transformer turns based on 70% duty cycle (D_MAX) at minimum specified input voltage. This will give some room for dropout if a PFC front end is used.

Equation 4.

D_{M A X} = 70 %

Equation 5.

a 1 = \frac{(V_{I N M I N} - 2 \times V_{R D S O N}) \times D_{M A X}}{V_{O U T} + V_{R D S O N}} \approx 21

Calculated typical duty cycle (D_TYP) based on average input voltage.

Equation 6.

D_{T Y P} = \frac{(V_{O U T} + V_{R D S O N}) \times a 1}{(V_{I N} - 2 \times V_{R D S O N})} \approx 0.66

To keep the RMS current in the output capacitance to a minimum L_OUT will be selected so the inductor ripple current (ΔI_LOUT) will be 20% of the DC output current. ΔI_LOUT is needed to calculate transformer peak and RMS currents

Equation 7.

Δ I_{L O U T} = \frac{P_{O U T} \times 0.2}{V_{O U T}} = 10 A

Care needs to be taken in selecting a transformer with the correct amount of magnetizing inductance (L_MAG). The following equations calculate the minimum magnetizing inductance of the primary of the transformer (T1) to ensure the converter operates in peak-current mode control. If L_MAG is too small the magnetizing current could cause the converter to operate in voltage mode control instead of peak-current mode control. This is because the magnetizing current is too large, it will act as a PWM ramp swamping out the current sense signal across R_S.

Equation 8.

L_{M A G} \geq \frac{V_{I N} \times (1 - D_{T Y P})}{\frac{Δ I_{L O U T} \times 0.5}{a 1} \times f_{s}} \approx 2.76 m H

Figure 4-1 shows T1 primary current (I_PRIMARY) and synchronous rectifiers currents, (QE (I_QE) and QF (I_QF)), with respect to the synchronous rectifier gate drive currents. Note that I_QE and I_QF are also T1’s secondary winding currents as well. Variable D is the converters duty cycle.

Figure 4-1 T1 Primary and QE and QF FET Currents

Calculate T1 secondary RMS current (I_SRMS):

Equation 9.

I_{P S} = \frac{P_{O U T}}{V_{O U T}} + \frac{Δ I_{L O U T}}{2} \approx 55 A

Equation 10.

I_{M S} = \frac{P_{O U T}}{V_{O U T}} - \frac{Δ I_{L O U T}}{2} \approx 45 A

Equation 11.

I_{M S 2} = I_{P S} - \frac{Δ I_{L O U T}}{4} \approx 50 A

Secondary RMS current (I_SRMS1) when energy is being delivered to the secondary:

Equation 12.

I_{S R M S 1} = \sqrt{(\frac{D_{M A X}}{2}) (I_{P S} \times I_{M S} + \frac{{(I_{P S} - I_{M S})}^{2}}{3})} \approx 29.6 A

Secondary RMS current (I_SRMS2) when current is circulating through the transformer when QE and QF are both on.

Equation 13.

I_{S R M S 2} = \sqrt{(\frac{1 - D_{M A X}}{2}) (I_{P S} \times I_{M S 2} + \frac{{(I_{P S} - I_{M S 2})}^{2}}{3})} \approx 20.3 A

Secondary RMS current (I_SRMS3) caused by the negative current in the opposing winding during freewheeling period, please refer to Figure 4-1.

Equation 14.

I_{S R M S 3} = \frac{Δ I_{L O U T}}{2} \sqrt{(\frac{1 - D_{M A X}}{2 \times 3})} \approx 1.1 A

Total secondary RMS current (I_SRMS):

Equation 15.

I_{S R M S} = \sqrt{{I_{S R M S 1}}^{2} + {I_{S R M S 2}}^{2} + {I_{S R M S 3}}^{2}} \approx 36.0 A

Calculate T1 Primary RMS Current (I_PRMS):

Equation 16.

∆ I_{L M A G} = \frac{V_{I N M I N} \times D_{M A X}}{L_{M A G} \times f_{S}} \approx 0.47 A

Equation 17.

I_{P P} = (\frac{P_{O U T}}{V_{O U T} \times η} + \frac{Δ I_{L O U T}}{2}) \frac{1}{a 1} + ∆ I_{L M A G} \approx 3.3 A

Equation 18.

I_{M P} = (\frac{P_{O U T}}{V_{O U T} \times η} - \frac{Δ I_{L O U T}}{2}) \frac{1}{a 1} + ∆ I_{L M A G} \approx 2.8 A

T1 Primary RMS (I_PRMS1) current when energy is being delivered to the secondary.

Equation 19.

I_{P R M S 1} = \sqrt{(D_{M A X}) (I_{P P} \times I_{M P} + \frac{{(I_{P P} - I_{M P})}^{2}}{3})} \approx 2.5 A

T1 Primary RMS (I_PRMS2) current when the converter is free wheeling.

Equation 20.

I_{M P 2} = I_{P P} - (\frac{Δ I_{L O U T}}{2}) \frac{1}{a 1} \approx 3.0 A

Equation 21.

I_{P R M S 2} = \sqrt{(1 - D_{M A X}) (I_{P P} \times I_{M P 2} + \frac{{(I_{P P} - I_{M P 2})}^{2}}{3})} \approx 1.7 A

Total T1 primary RMS current (I_PRMS)

Equation 22.

I_{P R M S} = \sqrt{{I_{P R M S 1}}^{2} + {I_{P R M S 2}}^{2}} \approx 3.1 A

The transformer calculations were given to Vitec a magnetic manufacturer to design a custom transformer to meet our design requirements. The transformer they designed for this application is part number 75PR8107 and the transformer has the following specifications.

Equation 23.

a 1 = 21

Equation 24.

L_{M A G} = 2.8 m H

Measured leakage inductance on the Primary:

Equation 25.

L_{L K} = 4 u H

Transformer Primary DC resistance:

Equation 26.

{D C R}_{P} = 0.215 Ω

Transformer Secondary DC resistance:

Equation 27.

{D C R}_{S} = 0.58 Ω

Estimated transform losses (P_T1) are twice the copper loss.

Note:

This is just an estimate and the total losses can vary based on magnetic design.

Equation 28.

P_{T 1} \approx 2 \times ({I_{P R M S}}^{2} \times D C R_{P} + 2 \times {I_{S R M S}}^{2} \times D C R_{S}) \approx 7.0 W

Calculate remaining power budget:

Equation 29.

P_{B U D G E T} = P_{B U D G E T} - P_{T 1} \approx 38.1 W