TSC MBRF1040CT

M B R F1030C T THR U M B R F10200C T
Iso la tio n 1 0 .0 A M P S . S ch o ttky B a rrie r R e ctifie rs
V o lta g e R a n g e
3 0 to 2 0 0 V o lts
C u rre n t
1 0 .0 A m p e re s
IT O -2 2 0 A B
F e a tu re s
P la s tic m a te ria l u s e d c a rrie s U n d e rw rite rs L a b o ra to ry
C la s s ifica tio n s 9 4 V -0
M e ta l s ilic o n ju n c tio n , m a jo rity c a rrie r c o n d u c tio n
L o w p o w e r lo s s , h ig h e ffic ie n c y
H ig h c u rre n t c a p a b ility , lo w fo rw a rd v o lta g e d ro p
H ig h s u rg e c a p a b ility
F o r u s e in lo w v o lta g e , h ig h fre q u e n c y in v e rte rs , fre e
w h e e lin g , a n d p o la rity p ro te c tio n a p p lic a tio n s
G u a rd rin g fo r o v e rv o lta g e p ro te c tio n
H ig h te m p e ra tu re s o ld e rin g g u a ra n te e d :
2 6 0 o C /1 0 s e c o n d s ,0 .2 5 ”(6 .3 5 m m )fro m c a s e
.1 34 (3 .4) D IA
.112 (2 .85 )
.11 3 ( 3 .0 )D I A
.10 0 ( 2 .5 5)
. 2 72 ( 6 .9 )
. 2 48 ( 6 .3 )
. 6 06 (1 5. 5)
. 5 83 (1 4. 8)
M e c h a n ic a l D a ta
. 5 43 (1 3. 8)
. 11 0 (2 .8 )
C a s e s : IT O -2 2 0 A B m o ld e d p la s tic
T e rm in a ls : L e a d s s o ld e ra b le p e r M IL -S T D -7 5 0 , M e th o d
2026
P o la rity : A s m a rk e d
M o u n tin g p o s itio n : A n y
M o u n tin g to rq u e : 5 in . - lb s. m a x
W e ig h t: 0 .0 8 o u n c e , 2 .2 4 g ra m s
. 5 12 (1 3. 2)
.09 8 ( 2 . 5 )
PIN 1
PIN 3
PIN 2
D im e n s io n s in in c h e s a n d (m illim e te rs )
M a x im u m R a tin g s a n d E le c tric a l C h a ra c te ris tic s
R a tin g a t 2 5 ℃ a m b ie n t te m p e ra tu re u n le ss o th e rw ise sp e cifie d .
S in g le p h a se , h a lf w a ve , 6 0 H z , re sistive o r in d u ctive lo a d .
F o r ca p a citive lo a d , d e ra te cu rre n t b y 2 0 %
S y m b o l MBRF MBRF MBRF
Type N um ber
M a xim u m R e cu rre n t P e a k R e ve rse V o lta g e
M a xim u m R M S V o lta g e
M a xim u m D C B lo ckin g V o lta g e
M a xim u m A ve ra g e F o rw a rd R e ctifie d C u rre n t
o
at T C= 133 C
P e a k R e p e titive F o rw a rd C u rre n t (R a te d V R ,
o
S q u a re W a ve , 2 0 K H z) a t T c= 1 3 3 C
P e a k F o rw a rd S u rg e C u rre n t, 8 .3 m s S in g le
H a lf S in e -w a ve S u p e rim p o se d o n R a te d
L o a d (JE D E C m e th o d )
P e a k R e p e titive R e ve rse S u rg e C u rre n t
(N o te 1 )
M a xim u m In sta n ta n e o u s F o rw a rd V o lta g e a t
O
(N o te 2 )
I F = 5 A , T c= 2 5 C
O
I F = 5 A , T c= 1 2 5 C
O
I F = 1 0 A , T c= 2 5 C
O
I F = 1 0 A , T c= 1 2 5 C
M a xim u m In sta n ta n e o u s R e ve rse C u rre n t
a t R a te d D C B lo ckin g V o lta g e @ T c= 2 5 ℃
@ T c= 1 2 5 ℃
V o lta g e R a te o f C h a n g e , (R a te d V R )
R M S Is o la tio n V o lta g e (t= 1 .0 se co n d , R .H .
≦ 30% , TA=25℃ )
(N o te 4 )
(N o te 5 )
(N o te 6 )
T yp ica l T h e rm a l R e sista n ce P e r L e g (N o te 3 )
O p e ra tin g J u n ctio n T e m p e ra tu re R a n g e
V RRM
V RMS
V DC
1030
CT
1035
CT
1040
CT
30
21
30
35
24
35
40
28
40
MBRF MBRF MBRF MBRF MBRF MBRF
1 0 4 5 1 0 5 0 1 0 6 0 10100 10150 10200
CT
CT
CT
CT
CT
CT
45
31
45
50
35
50
60
42
60
100
70
100
150
105
150
200
140
200
U n its
V
V
V
I (A V )
10
A
IF R M
1 0 .0
A
IF S M
150
A
IR R M
0 .5
A
0 .7 0
0 .5 7
VF
IR
0 .8 0
0 .6 5
0 .1
15
0 .8 5 0 .8 8 0 .9 9
0 .7 5 0 .7 8 0 .8 7
0 .9 5
0 .8 5
0 .1 5
150
V
mA
mA
d V /d t
1 0 ,0 0 0
V /u S
V IS O
4500
3500
1500
V
R θ JC
3 .5
℃ /W
TJ
-6 5 to + 1 5 0
℃
S to ra g e T e m p e ra tu re R a n g e
TSTG
-6 5 to + 1 5 0
N o te s: 1 . 2 .0 u s P u lse W id th , f= 1 .0 K H z
2 . P u lse T e st: 3 0 0 u s P u lse W id th , 1 % D u ty C ycle
3 . T h e rm a l R e sista n ce fro m J u n ctio n to C a se P e r L e g .
4 . C lip M o u n tin g (o n ca se ), w h e re le a d d o e s n o t o ve rla p h e a tsin k w ith 0 .1 1 0 ” o ffse t.
5 . C lip m o u n tin g (o n ca se ), w h e re le a d s d o o v e rla p h e a tsin k.
6 . S cre w m o u n tin g w ith 4 -4 0 s cre w , w h e re w a sh e r d ia m e te r is ? 4 .9 m m (0 .1 9 ”)
- 132 -
℃
RATINGS AND CHARACTERISTIC CURVES (MBRF1030CT THRU MBRF10200CT)
FIG.2- MAXIMUM NON-REPETITIVE FORWARD
SURGE CURRENT
FIG.1- FORWARD CURRENT DERATING CURVE
180
RESISTIVE OR
INDUCTIVE LOAD
PEAK FORWARD SURGE CURRENT. (A)
AVERAGE FORWARD CURRENT. (A)
6
5
4
3
2
1
Tj=Tj max.
8.3ms Single Half Sine-Wave
JEDEC Method
150
120
90
60
30
0
0
0
50
100
o
CASE TEMPERATURE. ( C)
0.1
150
1
10
100
NUMBER OF CYCLES AT 60Hz
FIG.4- TYPICAL REVERSE CHARACTERISTICS
FIG.3- TYPICAL INSTANTANEOUS FORWARD
CHARACTERISTICS
50
40
MBRF1050CT-MBRF1060CT
INSTANTANEOUS REVERSE CURRENT. (mA)
INSTANTANEOUS FORWARD CURRENT. (A)
10
10
MBRF1030CT-MBRF1045CT
MBRF10100CT
1
MBRF10150CT
0.1
Tj=125 0C
1
Tj=75 0C
0.1
0.01
MBRF10200CT
0
Tj=25 0C
Tj=25 C
Pulse Width=300 s
1% Duty Cycle
0.01
0
0.1
0.2
0.3
0.001
0
0.5 0.6 0.7 0.8 0.9 1.0 1.1 1.2
FORWARD VOLTAGE. (V)
0.4
60
80
100
120
140
100
TRANSIENT THERMAL IMPEDANCE. ( OC/W)
5,000
JUNCTION CAPACITANCE.(pF)
40
FIG.6- TYPICAL TRANSIENT THERMAL CHARACTERISTICS
PER LEG
FIG.5- TYPICAL JUNCTION CAPACITANCE
Tj=25 0C
f=1.0MHz
Vsig=50mVp-p
1,000
500
100
0.1
20
PERCENT OF RATED PEAK REVERSE VOLTAGE. (%)
1
10
100
REVERSE VOLTAGE. (V)
10
1
0.1
0.01
0.1
1
T, PULSE DURATION. (sec)
- 133 -
10
100