Advanced Power Technology APT APT6033BN, APT6030BN Datasheet

D

G

S

TO-247

APT6030BN 600V 23.0A 0.30Ω
APT6033BN 600V 22.0A 0.33Ω

POWER MOS IV

N-CHANNEL ENHANCEMENT MODE HIGH VOLTAGE POWER MOSF ETS

MAXIMUM RATINGS All Ratings: T

Symbol

V

I

V

P

TJ,T

DSS

I

D

DM

GS

D

STG

T

L

Parameter

Drain-Source Voltage
Continuous Drain Current @ T
Pulsed Drain Current
Gate-Source Voltage
Total Power Dissipation @ T
Linear Derating Factor
Operating and Storage Junction Temperature Range
Lead Temperature: 0.063" from Case for 10 Sec.

®

= 25°C unless otherwise specified.

C

APT APT

6030BN 6033BN

600 600

= 25°C

C

1

23 22
92 88

±30

= 25°C

C

360

2.9

-55 to 150
300

UNIT

Volts

Amps

Volts

Watts

W/°C

°C

STATIC ELECTRICAL CHARACTERISTICS

Symbol

BV

ID(ON)

R

DS

I

DSS

I

GSS

VGS(TH)

Characteristic / Test Conditions / Part Number

Drain-Source Breakdown Voltage

DSS

(V

= 0V, ID = 250 µA)

GS

On State Drain Current
(V

> ID(ON) x RDS(ON) Max, VGS = 10V)

DS

Drain-Source On-State Resistance

(ON)

(VGS = 10V, 0.5 ID [Cont.])

2

Zero Gate Voltage Drain Current (V
Zero Gate Voltage Drain Current (V
Gate-Source Leakage Current (V
Gate Threshold Voltage (V

= VGS, ID = 1.0mA)

DS

2

= V

DS

= 0.8 V

DS

= ±30V, V

GS

, VGS = 0V)

DSS

, VGS = 0V, TC = 125°C)

DSS

= 0V)

DS

MIN TYP MAX

APT6030BN

600

APT6033BN 600
APT6030BN 23
APT6033BN 22
APT6030BN 0.30
APT6033BN 0.33

250
1000
±100

24

UNIT

Volts

Amps

Ohms

µA

nA

Volts

THERMAL CHARACTERISTICS

Symbol

R
R

USA

405 S.W. Columbia Street Bend, Oregon 97702-1035 Phone: (541) 382-8028 FAX: (541) 388-0364

EUROPE

Avenue J.F. Kennedy Bât B4 Parc Cadéra Nord F-33700 Merignac - France Phone: (33) 5 57 92 15 15 FAX: (33) 5 56 47 97 61

Characteristic

Junction to Case

θJC

Junction to Ambient

θJA

CAUTION: These Devices are Sensitive to Electrostatic Discharge. Proper Handling Procedures Should Be Followed.

MIN TYP MAX

UNIT

0.34

°C/W

40

050-6008 Rev B

DYNAMIC CHARACTERISTICS

APT6030/6033BN

Symbol

C

iss

C

oss

C

rss

Q

g

Q

gs

Q

gd

td(on)

t

r

td(off)

t

f

Characteristic

Input Capacitance
Output Capacitance
Reverse Transfer Capacitance
Total Gate Charge

3

Gate-Source Charge
Gate-Drain ("Miller") Charge
Turn-on Delay Time
Rise Time
Turn-off Delay Time
Fall Time

Test Conditions

V

VDS = 25V

f = 1 MHz

V

GS

VDD = 0.5 V

ID = ID [Cont.] @ 25°C

V

GS

VDD = 0.5 V

ID = ID [Cont.] @ 25°C

RG = 1.8Ω

SOURCE-DRAIN DIODE RATINGS AND CHARACTERISTICS

I

SM

t

Characteristic / Test Conditions / Part Number

Continuous Source Current

S

(Body Diode)
Pulsed Source Current

1

(Body Diode)

2

Diode Forward Voltage

SD

Reverse Recovery Time (I

rr

Reverse Recovery Charge (I

rr

(VGS = 0V, IS = -ID [Cont.])

= -ID [Cont.], dlS/dt = 100A/µs)

S

= -ID [Cont.], dlS/dt = 100A/µs)

S

Symbol

I

V

Q

MIN TYP MAX

GS

= 0V

2905 3500

505 710
190 285

= 10V

DSS

140 210

18 27
75 110

= 15V

DSS

20 40
35 70
90 130
50 100

MIN TYP MAX

APT6030BN
APT6033BN 22
APT6030BN 92
APT6033BN 88

480 960

816

23

1.3

UNIT

pF

nC

ns

UNIT

Amps

Volts

ns

µC

SAFE OPERATING AREA CHARACTERISTICS

Symbol

SOA1
SOA2

I

1

Repetitive Rating: Pulse width limited by maximum junction temperature. See Transient Thermal Impedance Curve. (Fig.1)

2

Pulse Test: Pulse width < 380 µS, Duty Cycle < 2%

3

See MIL-STD-750 Method 3471

APT Reserves the right to change, without notice, the specifications and information contained herein.

050-6008 Rev B

Characteristic

Safe Operating Area
Safe Operating Area

Inductive Current Clamped

LM

0.5

D=0.5

, THERMAL IMPEDANCE (°C/W)

JC

θ

Z

0.1

0.05

0.01

0.005

0.001

0.2

0.1

0.05

0.02

0.01

-5

10

FIGURE 1, MAXIMUM EFFECTIVE TRANSIENT THERMAL IMPEDANCE, JUNCTION-TO-CASE vs PULSE DURATION

SINGLE PULSE

-4

10

Test Conditions / Part Number

V

= 0.4 V

DS

= ID [Cont.], VDS = PD / ID [Cont.], t = 1 Sec.

I

DS

, IDS = PD / 0.4 V

DSS

, t = 1 Sec.

DSS

APT6030BN 92
APT6033BN 88

-3

10

RECTANGULAR PULSE DURATION (SECONDS)

-2

10

10

MIN TYP MAX

360
360

Note:

DM

P

Duty Factor D =

Peak TJ = PDM x Z

-1

1.0 10

UNIT

Watts

Amps

t

1

t

2

t

1

/

t

2

+ T

θJC

C