SM015A100JAN120 Datasheet, PDF(48/112 Page) AVX Corporation – AVX Advanced Ceramic Capacitors for Power Supply, High Voltage and Tip and Ring Applications

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SM015A100JAN120 Datasheet, PDF (48/112 Pages) AVX Corporation – AVX Advanced Ceramic Capacitors for Power Supply, High Voltage and Tip and Ring Applications

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SMPS Capacitors

Assembly Guidelines

CAPACITOR

SUBSTRATE

DIMENSIONS

AT AMBIENT

TEMPERATURE

CAPACITOR

BODY

"J" LEADS

"L" LEADS

CAPACITOR

BODY

CAPACITOR

SUBSTRATE

Toper > T amb CTE sub > CTE cap

SUBSTRATE LINEAR

DISPLACEMENT

PUTS SOLDER JOINT

AND CAPACITOR IN

TENSION

CAPACITOR

SUBSTRATE

SUBSTRATE LINEAR

DISPLACEMENT

PUTS SOLDER JOINT

AND CAPACITOR IN

COMPRESSION

Toper > T amb CTE sub < CTE cap

Figure 1. Linear Displacement Between

Component and Substrate

General Processing Guidelines

Figure 2 shows the location of maximum stress in the solder

joint due to positive and negative DCTE and linear displace-

ment.

SOLDER

FILLET

CAPACITOR

MAXIMUM STRESS

SUBSTRATE

Stress for Toper > Tamb CTE sub > CTE cap

CAPACITOR

SUBSTRATE

MAXIMUM STRESS

SOLDER

FILLET

Stress for Toper > Tamb CTE sub < CTE cap

Figure 2

Stress Relief

Leadframes on larger capacitor sizes (greater than 2225) must

be used to minimize mechanical stress on the solder joints dur-

ing temperature cycling which is normal operation for power

supplies (Figure 3). Failing solder joints increase both ESR and

ESL causing an increase in ripple, noise and heat, accelerating

failure.

Layout

Effective solder dams must be used to keep all molten solder

on the solder lands during reflow or solder will migrate away

from the land, causing opens or weak solder joints. High fre-

quency output filters cannot use low power layout techniques

such as necked down conductors because of the stringent

inductance requirements.

SOLDER LAND

SOLDER

FILLETS

SUBSTRATE

Figure 3. âJâ and âLâ Leadframes Mounted on

Capacitors to Relieve Stress

Inductance

Adding leadframes has a small impact on component induc-

tance but this is the price that must be paid for reliable operation

over temperature. Figure 4 shows typical leadframe inductance

that is added for two lead standoff distances (0.020" and 0.050")

versus the number of leads along one side of SupraCapÂ® which

are specifically designed output filter capacitors for 1 MHz and

above switchers. The actual inductance will be somewhat less

because the leadframes flare out from the lead where the lead-

frame is attached to the capacitor body.

0.4

0.3

0.2

0.050"

Standoff

0.1

0.020"

Standoff

Number of leads on one side of Capacitor

Figure 4. Number of Leads on One Side of Capacitor vs. Total

Leadframe Inductance vs. Substrate Standoff Height

Very high frequency switch mode power supplies place

tremendous restrictions on output filter capacitors. In addition

to handling high ripple current (low ESR), ESL must approach

zero nano henrys, part must be truly surface mountable

and be available in new configurations to be integrated into

transmission lines to further reduce inductance with load

currents greater than 40A at 1 MHz and as frequencies move

above 1-2 MHz.

The total inductance is the sum of each side of the part where

the inductance of one side is the parallel combination of each

lead in the leadframe. That inductance is given by:

L (nH) = 5xá [In (2xá) / (B+C) + 1/2]

Where á = lead length in inches

In = natural log

B+C = lead cross section in inches

so L1 (nH) = 2xL (nH) where L1 is the total inductance of the

leadframe.

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