1N4001 THRU 1N4007,BY133

SF11G THRU SF18G
1.0AMP .Glass Passivated Super Fast Recitifiers
DO-41
FEATURE
.High current capability,
.Low forward voltage drop
.Low power loss, high efficiency
.High surge capability
.High temperature soldering guaranteed
260°C /1 0sec/0.375" lead length at 5 lbs tension
Superfast recovery time for high efficiency.
.787(20.0)
MIN.
.107(2.7)
.080(2.0)
+
.205(5.2)
.166(4.2)
-
MECHANICAL DATA
.787(20.0)
MIN.
.Case: Molded plastic
.Epoxy: UL94V-0 rate flame retardant
.Lead: MIL-STD- 202E, Method 208 guaranteed
.Polarity:Color band denotes cathode end
.Packaging:12mm tape per EIA STD RS-481
.Mounting position: Any
DIA.
.032(0.8)
.025(0.65)
DIA
Dimensions in inches and (millimeters)
MAXIMUM RATINGS AND ELECTRICAL CHARACTERISTICS
(single-phase, half-wave, 60HZ, resistive or inductive load rating at 25°C, unless otherwise stated)
SF
11G
50
SF
12G
100
SF
13G
150
SF
14G
200
SF
15G
300
SF
16G
400
SF
17G
500
SF
18G
units
Maximum Recurrent Peak Reverse Voltage
SYM
BOL
VRRM
600
V
Maximum RMS Voltage
VRMS
35
70
105
140
210
280
350
420
V
Maximum DC blocking Voltage
VDC
50
100
150
200
300
400
500
600
V
Type Number
Maximum Average Forward Rectified
Current .375"(9.5mm)lead length at TL =55°C
IF(AV)
1.0
A
IFSM
30.0
A
Peak Forward Surge Current 8.3ms single
half sine-wave superimposed on rated load
(JEDEC method)
Maximum Forward Voltage at 1.0A DC
Maximum DC Reverse Current
Ta =25°C
at rated DC blocking voltage
Ta =125°C
Maximum Reverse Recovery Time (Note 1)
Typical Junction Capacitance (Note 2)
Typical Thermal Resistance (Note 3)
Storage Temperature
Operation Junction Temperature
VF
0.95
1.3
1.7
5.0
IR
µA
100.0
trr
CJ
R(JA)
TSTG
TJ
35
50
Note:
1. Reverse Recovery test Condition: If=0.5A,IR=1.0A,IRR=0.25A;
2. Measured at 1.0 MHz and applied reverse voltage of 4.0Vdc
3. P.C.B.Mounted on0.2×0.2”(5.0×5.0mm)[0.013mm thick]Copper Pad Area.
- 385 -
V
ns
25
pF
75
°C/W
-55 to +150
°C
-55 to +150
°C
RATING AND CHARACTERISTIC CURVES (SF11G THRU SF18G)
FIG .1-TY PIC A L FO R W A R D C U R R EN T
D ER A TIN G C U R V E
FIG .2-TY PIC A L IN STA N TA N EO U S FO R W A R D
C H A R A C T E R IST IC S
0.5
Single Phase H alf
W ave 60H z
R esistive or
inductive Load
0
0
50
150
100
0V
20
V1.0
0V
40
0V
50
0
6
V-
00
V
TJ=25 ℃
Pulse W idth=300 μ s
1% D uty Cycle
.1
.01
200
30
50
INSTANEOUS FORWARD
CURRENT,(A)
AVERGE FORWARD
RECTIFIED CURRENT,(A)
10
1.0
.6
1. 4
1.0
1. 8
2.2
A M B IEN T TEM PER TU RE,( ℃ )
IN STA N EO U S FO R W A R D V O LTA G E,(V )
FIG .3-M A X IM U N N O N -R EPETITIV E
FO R W A R D SU R G E C U R R EN T
FIG .4-TY PICA L R EV ER SE
C H A R A C TER ISTIC S
40
INSTANEOUS REVERSE
CURRENT,(μA)
PEAK FORWARD SURGE
CURRENT,(A)
10
8.3m s Single H alf
Sine-W ave (JED EC
M ethod)
30
20
10
0
0
TJ=25 ℃
.1
.01
100
10
1.0
0
20
40
60
N U M B ER O F C Y C LES A T 60H z
FIG .5-TEST C IR C U IT D IA G R A M A N D R EV ER SE
R EC O V ER Y TIM E C H A R A C TER SITIC
50 Ω
N O N IN D U C TIV E
(+)
25V dc
(approx)
(-)
80
100
120
PER C EN T O F R A TED PEA K R EV ER SE
V O LTA G E,(% )
10 Ω
N O N IN D U C TIV E
+0.5A
(+)
0
PU L SE
G EN ER A TO R -0.25A
(N O TE 2)
1Ω
(N O TE 1)
N O N - O SC IL O SC O PE
IN D U CTIV E
(-)
-1.0A
N O T E S:1. R ise Tim e=7ns m ax, Input
Im pedance= 1 m egohm .22pF.
2. R ise T im e=10ns m ax,
Souce Im pedance= 50 ohm s.
- 386 -
trr
140