ISL6150CB Intersil, ISL6150CB Datasheet - Page 9

ISL6150CB

Manufacturer Part Number

ISL6150CB

Description

IC CONTROLLER HOT PLUG 8-SOIC

Manufacturer

Intersil

Type

Hot-Swap Controllerr

Datasheet

1.ISL6140CBZ.pdf (19 pages)

Specifications of ISL6150CB

Applications

General Purpose, VoIP

Internal Switch(s)

Voltage - Supply

36 V ~ 72 V

Operating Temperature

0°C ~ 70°C

Mounting Type

Surface Mount

Package / Case

8-SOIC (0.154", 3.90mm Width)

Lead Free Status / RoHS Status

Contains lead / RoHS non-compliant

Available stocks

Company

Part Number

Manufacturer

Quantity

Price

Company:

Bonase Electronics (HK) Co., Limited

Part Number:

ISL6150CB

Manufacturer:

INF

Quantity:

5 745

Current page: 9 of 19
Download datasheet (468Kb)

Applications: Overcurrent

Physical layout of R

the possibility of false overcurrent occurrences. Since it

is in the main input-to-output path, the traces should

be wide enough to support both the normal current,

and up to the overcurrent trip point. Ideally trace

routing between the R

ISL6150 (pin 4 (V

as short as possible with zero current in the sense lines

(see Figure 5).

There is a short filter (3

comparator; current spikes shorter than this will be

ignored. Any longer pulse will shut down the output,

requiring the user to either power-down the system

(below the UV voltage), or pull the UV pin below its

trip point (usually with an external transistor).

If current pulses longer than the 3µs are expected, and

need to be filtered, then an additional resistor and

capacitor can be added. As shown in Figure 29, R

SENSE pin won’t rise as fast, effectively delaying the

shut-down. Since the ISL6140/ISL6150 has essentially

zero current on the SENSE pin, there is no voltage drop

or error associated with the extra resistor. R

recommended to be small, 100Ω is a good value.

The delay time is approximated by the added RC time

constant, modified by a factor relative to the trip point

(see Equation 2).

where V(t) is the trip voltage (nominally 50mV); V(t

is the nominal voltage drop across the sense resistor

before the overcurrent condition; V

across the sense resistor while the overcurrent is

applied.

For example: a system has a normal 1A current load,

and a 20mΩ sense resistor, for a 2.5A overcurrent. It

needs to filter out a 50

Therefore:

V(t) = 50mV (from spec)

TO SENSE

CORRECT

AND V

act as a low-pass filter such that the voltage on the

–

R*C*In [1 - (V(t) - V(t

FIGURE 5. SENSE RESISTOR

SENSE RESISTOR

1 SENSE

) and pin 5 (SENSE) is direct and

CURRENT

) )

s current pulse at 5A.

resistor and the ISL6140 and

s nominal) on the

INCORRECT

⁄

(

resistor is critical to avoid

–

V t

( )

)

]

is the voltage drop

ISL6140, ISL6150

(EQ. 2)

and

)

V(t

If R

Note that the FET must be rated to handle the higher

current for the longer time, since the IC is not doing

current limiting; the RC is just delaying the overcurrent

shutdown.

Applications: OV and UV

The UV and OV input pins are high impedance, so the

value of the external resistor divider is not critical with

respect to input current. Therefore, the next

consideration is total current; the resistors will always

draw current, equal to the supply voltage divided by

the total of R4 + R5 + R6; so the values should be

chosen high enough to get an acceptable current.

However, to the extent that the noise on the power

supply can be transmitted to the pins, the resistor

values might be chosen to be lower. A filter capacitor

from UV to VEE or OV to UV is a possibility, if certain

transients need to be filtered. (Note that even some

transients which will momentarily shut off the gate

might recover fast enough such that the gate or the

output current does not even see the interruption).

Finally, take into account whether the resistor values

are readily available, or need to be custom ordered.

Tolerances of 1% are recommended for accuracy. Note

that for a typical 48V system (with a 36V to 72V

range), the 36V or 72V is being divided down to

1.223V, a significant scaling factor. For UV, the ratio is

roughly 30x; every 3mV change on the UV pin

represents roughly 0.1V change of power supply

voltage. Conversely, an error of 3mV (due to the

resistors, for example) results in an error of 0.1V for

the supply trip point. The OV ratio is around 60. So the

accuracy of the resistors comes into play.

The hysteresis of the comparators (20mV nominal)

is also multiplied by the scale factor of 30 for the UV

pin (30 * 20mV = 0.6V of hysteresis at the power

supply) and 60 for the OV pin (60*20mV = 1.2V of

hysteresis at the power supply).

With the three resistors, the UV equation is based on

the simple resistor divider:

1.223 = V

Similarly, for OV:

1.223 = V

Note that there are two equations, but 3 unknowns.

Because of the scale factor, R

than the other two; chose its value first, to set the

current (for example, 50V/500kΩ draws 100µA), and

then the other two will be in the 10kΩ range. Solve the

two equations for two unknowns. Note that some

iteration may be necessary to select values that meet

= 100mV (V = IR = 5A*20mΩ)

) = 20mV (V = IR = 1A*20mΩ)

= 1.223 (R

= 100Ω, then C

OV*

*(R

)/(R

+ R

is around 1µF.

)/(R

+ R

)/(R

+ R

has to be much bigger

)

) or

+ R

)

) or

FN9039.4

ISL6150CB Intersil, ISL6150CB Datasheet - Page 9

ISL6150CB

Specifications of ISL6150CB

Available stocks

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