NCP1910B65DWR2G ON Semiconductor, NCP1910B65DWR2G Datasheet - Page 23

AC/DC Switching Converters GREENM COMBO 2GND N/SKIP

NCP1910B65DWR2G

Manufacturer Part Number

NCP1910B65DWR2G

Description

AC/DC Switching Converters GREENM COMBO 2GND N/SKIP

Manufacturer

ON Semiconductor

Type

Combo Controllerr

Datasheet

1.NCP1910A65DWR2G.pdf (37 pages)

Specifications of NCP1910B65DWR2G

Input / Supply Voltage (max)

20 V

Switching Frequency

500 KHz

Operating Temperature Range

- 60 C to + 150 C

Mounting Style

SMD/SMT

Package / Case

SO-24

Maximum Operating Temperature

+ 150 C

Minimum Operating Temperature

- 60 C

Number Of Outputs

Output Current

5 mA

Lead Free Status / RoHS Status

Lead free / RoHS Compliant

Available stocks

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Manufacturer

Quantity

Price

Company:

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Part Number:

NCP1910B65DWR2G

Manufacturer:

ON Semiconductor

Quantity:

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Part Number:

NCP1910B65DWR2G

Manufacturer:

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Quantity:

20 000

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and a 980 mV voltage source, V

the LBO pin to maintain the pin level near 1 V. Then a 50 ms

blanking delay, t

fault is detected. The main goal of the 50 ms lag is to help

meet the hold−up requirements. In case of a short mains

interruption, no fault is detected and hence, both PFC and

LLC keep operating. In addition, LBO pin being kept at

980 mV, there is almost no extra delay between the line

recovery and the occurrence of a proper voltage applied to

LBO pin, that otherwise would exist because of the large

capacitor typically placed between LBO pin and ground to

filter the input voltage ripple. As a result, the NCP1910

effectively “blanks” any mains interruption that is shorter

than 25 ms (minimum guaranteed value of the 50 ms timer).

timer is activated that sets a 50 ms window during which a

fault can be detected. This is the role of the t

Figure 46:

•

When the PFC_BO signal is high:

•

voltage remains below when: V

is released open or UVP or Thermal Shutdown. This is to

guarantee that the circuit starts operation in the right state,

which is “PFC_BO” high. When the NCP1910 is ready to

work, the pnp transistor turns off and the circuit enables the

but at startup, I

Line Brown−Out Network Calculation

after bridge diode, the monitored voltage can be very

different depending on the phase:

•

LBOH

Conversely, if V

At the end of this blanking delay (t

At startup, a pnp transistor ensures that the LBO pin

Also, I

If the line brown−out network is connected to the voltage

If V

and PFC_BO signal is asserted high.

If V

The PFC driver is disabled, and the V

grounded to recover operation with a soft−start when

the fault has gone.

The V

pin.

The I

that lowers the LBO pin voltage for hysteresis purpose.

Before operation, the PFC stage is off and the input

bridge acts as a peak detector. As a consequence, the

input voltage is approximately flat and nearly equates

the ac line amplitude: <V

is the rms voltage of the line. As depicted in previous

section, the I

purpose of adjustable line brown−out hysteresis; hence,

the average voltage applied to LBO pin is:

LBO(window)

LBOcomp

LBOH

LBO(clamp)

LBOH

current source (7 mA typically) is enabled

LBOH

, no fault is detected.

is enabled whenever the part is in off mode,

LBOH

is high during the second 50 ms delay

remains low for the duration of the

), a line brown−out condition is confirmed

LBO(blank)

LBO

voltage source is removed from LBO

is disabled until V

turns on before PFC operates for the

goes below 1 V, V

, is activated during which no

> = √2 V

LBO(clamp)

< UVLO or ON/OFF pin

ac,rms

LBO(blank)

LBOcomp

CTRL

reaches V

, is connected to

, where V

LBO(window)

pin is

), another

turns high

http://onsemi.com

CC(on)

ac,rms

•

Where:

account the LBO pin voltage ripple (first approximation).

Re−arranging the Equation 9 and 10, the network connected

to LBO pin can be calculated with the following equations:

Where:

The term

If as a rule of the thumb, we will assume that

After the PFC stage has started operation, the input

voltage becomes a rectified sinusoid and the average

voltage becomes <V

decays 2/π of the peak value of rms input voltage.

Hence, the average voltage applied to LBO pin is:

And because of the ripple on the LBO pin, the

minimum value of V

♦

LBOL

If R

LBO

between LBO pin and ground.

between V

LBO

line

LBOL

LBOU

LBOL

LBOU

LBO

+ 2 V

] 2 V

> = (2/p) √2 V

is the line frequency.

is the sensing network pole frequency.

1 *

0.967

is low side resistor of the dividing resistors

is upper side resistor of the dividing resistors

<< R

2 V

2pR

LBOU

ac,rms

1 *

LBO

and LBO pin.

line

LBOU

LBOH

ac,rms

LBOU

line

LBOU

) R

@ R

of Equation 10 enables to take into

LBO

LBOU

line

ac,rms

> = (2/p) √2 V

) R

2 @ V

LBOL

ac,on

ac,off

LBOU

is around:

ac,on

ac,off

LBOL

) R

ac,on

) V

* 1 @

LBOL

) R

LBO

* 1 @

LBOL

LBOT

LBOL

/(R

* I

ac,rms

LBOH

* 1 R

LBOU

LBOT

LBOH

LBOT

, which

+ R

LBO

LBOL

(eq. 10)

(eq. 12)

(eq. 11)

(eq. 9)

line

NCP1910B65DWR2G ON Semiconductor, NCP1910B65DWR2G Datasheet - Page 23

NCP1910B65DWR2G

Specifications of NCP1910B65DWR2G

Available stocks

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