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| LMH6321_07 Datasheet, PDF (17/22 Pages) National Semiconductor (TI) – 300mA High Speed Buffer with Adjustable Current Limit | |||
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THERMAL MANAGEMENT
Heatsinking
For some applications, a heat sink may be required with the
LMH6321. This depends on the maximum power dissipation
and maximum ambient temperature of the application. To ac-
complish heat sinking, the tabs on TO-263 and PSOP pack-
age may be soldered to the copper plane of a PCB for
heatsinking (note that these tabs are electrically connected to
the most negative point in the circuit, i. e.,Vâ).
Heat escapes from the device in all directions, mainly through
the mechanisms of convection to the air above it and con-
duction to the circuit board below it and then from the board
to the air. Natural convection depends on the amount of sur-
face area that is in contact with the air. If a conductive plate
serving as a heatsink is thick enough to ensure perfect ther-
mal conduction (heat spreading) into the far recesses of the
plate, the temperature rise would be simply inversely propor-
tional to the total exposed area. PCB copper planes are, in
that sense, an aid to convection, the difference being that they
are not thick enough to ensure perfect conduction. Therefore,
eventually we will reach a point of diminishing returns (as
seen in Figure 5). Very large increases in the copper area will
produce smaller and smaller improvement in thermal resis-
tance. This occurs, roughly, for a 1 inch square of 1 oz copper
board. Some improvement continues until about 3 square
inches, especially for 2 oz boards and better, but beyond that,
external heatsinks are required. Ultimately, a reasonable
practical value attainable for the junction to ambient thermal
resistance is about 30 °C/W under zero air flow.
A copper plane of appropriate size may be placed directly
beneath the tab or on the other side of the board. If the con-
ductive plane is placed on the back side of the PCB, it is
recommended that thermal vias be used per JEDEC Stan-
dard JESD51-5.
Determining Copper Area
One can determine the required copper area by following a
few basic guidelines:
1. Determine the value of the circuitâs power dissipation,
PD
2. Specify a maximum operating ambient temperature, TA
(MAX). Note that when specifying this parameter, it must
be kept in mind that, because of internal temperature rise
due to power dissipation, the die temperature, TJ, will be
higher than TA by an amount that is dependent on the
thermal resistance from junction to ambient, θJA.
Therefore, TA must be specified such that TJ does not
exceed the absolute maximum die temperature of 150°
C.
3. Specify a maximum allowable junction temperature, TJ
(MAX), which is the temperature of the chip at maximum
operating current. Although no strict rules exist, typically
one should design for a maximum continuous junction
temperature of 100°C to 130°C, but no higher than 150°
C which is the absolute maximum rating for the part.
4. Calculate the value of junction to ambient thermal
resistance, θJA
5. Choose a copper area that will guarantee the specified
TJ(MAX) for the calculated θJA. θJA as a function of copper
area in square inches is shown in Figure 4.
The maximum value of thermal resistance, junction to ambi-
ent θJA, is defined as:
θJA = (TJ(MAX) - TA(MAX) )/ PD(MAX)
(6)
where:
TJ(MAX) = the maximum recommended junction temperature
TA(MAX) = the maximum ambient temperature in the userâs en-
vironment
PD(MAX) = the maximum recommended power dissipation
Note: The allowable thermal resistance is determined by the maximum al-
lowable heat rise , TRISE = TJ(MAX) - TA(MAX) = (θJA) (PD(MAX)). Thus, if
ambient temperature extremes force TRISE to exceed the design max-
imum, the part must be de-rated by either decreasing PD to a safe
level, reducing θJA, further, or, if available, using a larger copper area.
Procedure
1. First determine the maximum power dissipated by the
buffer, PD(MAX). For the simple case of the buffer driving
a resistive load, and assuming equal supplies, PD(MAX) is
given by
PD(MAX) = IS (2V+) + V+2/4RL
(7)
where: IS = quiescent supply current
2. Determine the maximum allowable die temperature rise,
TR(MAX) = TJ(MAX)-TA(MAX) = PD(MAX)θJA
(8)
3. Using the calculated value of TR(MAX) and PD(MAX) the
required value for junction to ambient thermal resistance
can be found:
θJA = TR(MAX)/PD(MAX)
(9)
4. Finally, using this value for θJA choose the minimum
value of copper area from Figure 4.
Example
Assume the following conditions:
V+ = Vâ = 15V, RL = 50â¦, IS = 15 mA TJ(MAX) = 125°C, TA
(MAX) = 85°C.
1. From (7)
PD(MAX) = IS (2V+) + V+2/4RL = (15 mA)(30V) +
225V2/200⦠= 1.58W
2. From (8)
TR(MAX) = 125°C - 85°C = 40°C
3. From (9)
θJA = 40°C/1.58W = 25.3°C/W
Examining the plot of Copper Area vs. θJA, we see that we
cannot attain this low of a thermal resistance for one layer of
1 oz copper. It will be necessary to derate the part by de-
creasing either the ambient temperature or the power dissi-
pation. Other solutions are to use two layers of 1 oz foil, or
use 2 oz copper (see Table 1), or to provide forced air flow.
One should allow about an extra 15% heat sinking capability
for safety margin.
17
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