SGL160N60UFDTU_技术文档

IGBT

SGL160N60UF

Ultra-Fast IGBT

General Description

Features

Fairchild's UF series of Insulated Gate Bipolar Transistors

(IGBTs) provides low conduction and switching losses.

The UF series is designed for applications such as motor

control and general inverters where high speed switching is

a required feature.

•

High speed switching

Low saturation voltage : V (sat) = 2.1 V @ I = 80A

High input impedance

CE

C

Applications

AC & DC motor controls, general purpose inverters, robotics, servo controls, and power supplies.

C

G

TO-264

E

G

E

C

Absolute Maximum Ratings

T = 25°C unless otherwise noted

C

Symbol

Description

SGL160N60UF

Units

V

Collector-Emitter Voltage

600

± 20

V

CES

GES

Gate-Emitter Voltage

Collector Current

@ T

=

25°C

160

A

C

I

C

Collector Current

@ T = 100°C

80

A

C

Pulsed Collector Current

300

A

CM (1)

P

M a x i m u m P o w e r D i s s i p a t i o n

Maximum Power Dissipation

Operating Junction Temperature

Storage Temperature Range

Maximum Lead Temp. for Soldering

Purposes, 1/8” from Case for 5 Seconds

@ T

=

25°C

250

W

°C

D

C

@ T = 100°C

100

C

T

-55 to +150

J

T

stg

T

300

°C

L

Notes :

(1) Repetitive rating : Pulse width limited by max. junction temperature

Thermal Characteristics

Symbol

Parameter

Typ.

--

Max.

Units

°C/W

R

Thermal Resistance, Junction-to-Case

0.5

25

θJC

θJA

Thermal Resistance, Junction-to-Ambient

--

SGL160N60UF Rev. A1

Electrical Characteristics of the IGBT

T = 25°C unless otherwise noted

C

Symbol

Parameter

Test Conditions

Min.

Typ.

Max.

Units

Off Characteristics

BV

Collector-Emitter Breakdown Voltage

Temperature Coefficient of Breakdown

Voltage

V

= 0V, I = 250uA

600

--

V

CES

GE

C

∆B

/

VCES

J

= 0V, I = 1mA

0.6

V/°C

GE

C

∆T

I

Collector Cut-Off Current

G-E Leakage Current

V

= V

, V = 0V

--

250

uA

nA

CES

GES

CE

CES

GE

, V = 0V

± 100

GE

GES

CE

On Characteristics

V

G-E Threshold Voltage

I

= 80mA, V = V

GE

3.5

--

4.5

2.1

2.6

6.5

2.6

--

V

GE(th)

C

CE

= 80A, V = 15V

Collector to Emitter

Saturation Voltage

GE

V

CE(sat)

= 160A, V = 15V

--

GE

Dynamic Characteristics

C

Input Capacitance

--

5000

600

--

pF

ies

V

= 30V V = 0V,

, GE

CE

Output Capacitance

oes

res

f = 1MHz

Reverse Transfer Capacitance

200

Switching Characteristics

t

Turn-On Delay Time

--

40

101

90

--

ns

uJ

ns

uJ

nC

nH

d(on)

Rise Time

r

Turn-Off Delay Time

Fall Time

130

150

--

V

R

= 300 V, I = 80A,

C

d(off)

f

CC

= 3.9Ω, V =15V

75

G

GE

Inductive Load, T = 25°C

E

Turn-On Switching Loss

Turn-Off Switching Loss

Total Switching Loss

Turn-On Delay Time

Rise Time

2500

1760

4260

45

C

on

off

--

5000

--

ts

t

d(on)

r

105

140

122

2785

3100

5885

345

60

--

Turn-Off Delay Time

Fall Time

200

250

--

V

= 300 V, I = 80A,

C

d(off)

f

CC

R

= 3.9Ω, V = 15V

G

GE

Inductive Load, T = 125°C

E

Turn-On Switching Loss

Turn-Off Switching Loss

Total Switching Loss

Total Gate Charge

Gate-Emitter Charge

Gate-Collector Charge

Internal Emitter Inductance

C

on

off

ts

--

Q

520

100

150

--

g

V

= 300 V, I = 80A,

CE

GE

C

ge

gc

= 15V

95

L

Measured 5mm from PKG

18

e

SGL160N60UF Rev. A1

500

400

300

200

100

0

240

200

160

120

80

15V

Common Emitter

V_GE= 15V

20V

Common Emitter

℃

T_C= 25

12V

℃

T_C

= 25

T

_C= 125

V_GE= 10V

40

0

2

4

6

8

0.5

1

10

Collector - Emitter Voltage, V_CE[V]

Fig 2. Typical Saturation Voltage

Characteristics

Fig 1. Typical Output Characteristics

120

4

V_CC= 300V

Load Current : peak of square wave

Common Emitter

V_GE= 15V

100

80

60

40

20

0

160A

80A

3

2

I_C= 40A

1

0

Duty cycle : 50%

℃

T

_C= 100

Power Dissipation = 130W

0

30

60

90

120

150

0.1

1

10

100

1000

℃

[

Case Temperature, T_C

]

Frequency [KHz]

Fig 3. Saturation Voltage vs. Case

Fig 4. Load Current vs. Frequency

Temperature at Variant Current Level

20

16

12

8

20

Common Emitter

℃

T_C= 25

℃

T_C= 125

16

12

8

160A

4

80A

8

80A

8

I_C= 40A

4

I_C= 40A

4

0

12

16

20

0

12

16

20

Gate - Emitter Voltage, V_GE[V]

Fig 6. Saturation Voltage vs. V

Fig 7. Saturation Voltage vs. V

GE

SGL160N60UF Rev. A1

8000

7000

6000

5000

4000

3000

2000

1000

0

1000

Common Emitter

_GE= 0V, f = 1MHz

T_C= 25℃

Common Emitter

V_CC= 300V, V_GE= ± 15V

I_C= 80A

V

Cies

T_C

= 25℃

Ton

Tr

T_C= 125℃

100

Coes

Cres

20

1

10

80

1

10

Collector - Emitter Voltage, V_CE[V]

30

Gate Resistance, R_G[Ω]

Fig 8. Turn-On Characteristics vs.

Gate Resistance

Fig 7. Capacitance Characteristics

10000

2000

Common Emitter

±

15V

V_CC= 300V, V_GE

_C= 80A

=

±

15V

V

_CC= 300V, V_GE

=

I

I_C= 80A

1000

℃

T_C

= 25

℃

T_C

= 25

T

_C= 125

Eon

T

_C= 125

Toff

Eoff

Tf

100

30

1000

1

10

Gate Resistance, R_G[Ω]

80

1

10

Gate Resistance, R_G[Ω]

80

Fig 10. Switching Loss vs. Gate Resistance

Fig 9. Turn-Off Characteristics vs.

Gate Resistance

500

1000

Common Emitter

±

15V

V_CC= 300V, V_GE

=

R_G= 3.9Ω

℃

T_C

T_C= 125

= 25

Toff

100

Toff

Tf

100

Ton

Common Emitter

±

V_CC= 300V, V_GE

R_G= 3.9Ω

=

15V

Tf

Tr

℃

T_C

T_C= 125

= 25

20

10

20

40

60

80

100

120

140

160

20

40

60

80

100

120

140

160

Collector Current, I_C[A]

Fig 12. Turn-Off Characteristics vs.

Collector Current

Fig 11. Turn-On Characteristics vs.

Collector Current

SGL160N60UF Rev. A1

20000

10000

15

12

9

Common Emitter

R_L= 37.5 Ω

±

15V

V_CC= 300V, V_GE

=

R_G= 3.9Ω

℃

T_C= 25

℃

T_C

= 25

T_C= 125

300 V

1000

6

200 V

V_CC= 100 V

Eoff

Eon

3

100

0

20

40

60

80

100

120

140

160

0

50

100

150

200

250

300

350

Gate Charge, Q_g[ nC ]

Collector Current, I_C[A]

Fig 13. Switching Loss vs. Collector Current

Fig 14. Gate Charge Characteristics

1000

500

100

I_CMAX. (Pulsed)

I_CMAX. (Continuous)

100

50us

100us

㎳

1

10

1

DC Operation

10

Single Nonrepetitive

℃

Pulse T_C= 25

Curves must be derated

linearly with increase

in temperature

Safe Operating Area

V_GE=20V, T_C=100^oC

10

Collector-Emitter Voltage, V_CE[V]

0.1

1

0.3

1

10

100

1000

1

100

1000

Collector-Emitter Voltage, V_CE[V]

Fig 15. SOA Characteristic

Fig 16. Turn-Off SOA Characteristics

1

0.5

0.2

0.1

0.05

0.02

0.01

Pdm

t1

single pulse

t2

Duty factor D = t1 / t2

Peak Tj = Pdm

× Zthjc + T

C

1E-3

10^-5

10^-4

10^-3

10^-2

10^-1

10⁰

10¹

Rectangular Pulse Duration [sec]

Fig 17. Transient Thermal Impedance of IGBT

SGL160N60UF Rev. A1

Package Dimension

TO-264

20.00 ±0.20

(8.30) (8.30)

(2.00)

(1.00)

(0.50)

(7.00)

4.90 ±0.20

(1.50)

2.50 ±0.20

3.00 ±0.20

+0.25

–0.10

1.00

+0.25

–0.10

0.60

2.80 ±0.30

5.45TYP

[5.45 ±0.30

]

[5.45 ±0.30]

Dimensions in Millimeters

SGL160N60UF Rev. A1

TRADEMARKS

The following are registered and unregistered trademarks Fairchild Semiconductor owns or is authorized to use and is not

intended to be an exhaustive list of all such trademarks.

ACEx™

FAST^®

FASTr™

FRFET™

GlobalOptoisolator™ PACMAN™

GTO™

HiSeC™

I²C™

ISOPLANAR™

LittleFET™

MicroFET™

MICROWIRE™

OPTOLOGIC™

OPTOPLANAR™

SLIENT SWITCHER^®UHC™

SMART START™

SPM™

STAR*POWER™

Stealth™

SuperSOT™-3

SuperSOT™-6

SuperSOT™-8

SyncFET™

Bottomless™

CoolFET™

CROSSVOLT™

DenseTrench™

DOME™

EcoSPARK™

E²CMOS™

EnSigna™

FACT™

UltraFET^®

VCX™

POP™

Power247™

PowerTrench^®

QFET™

QS™

QT Optoelectronics™ TinyLogic™

Quiet Series™ TruTranslation™

FACT Quiet Series™ MicroPak™

STAR*POWER is used under license

DISCLAIMER

FAIRCHILD SEMICONDUCTOR RESERVES THE RIGHT TO MAKE CHANGES WITHOUT FURTHER NOTICE TO ANY

PRODUCTS HEREIN TO IMPROVE RELIABILITY, FUNCTION OR DESIGN. FAIRCHILD DOES NOT ASSUME ANY

LIABILITY ARISING OUT OF THE APPLICATION OR USE OF ANY PRODUCT OR CIRCUIT DESCRIBED HEREIN;

NEITHER DOES IT CONVEY ANY LICENSE UNDER ITS PATENT RIGHTS, NOR THE RIGHTS OF OTHERS.

LIFE SUPPORT POLICY

FAIRCHILD’S PRODUCTS ARE NOT AUTHORIZED FOR USE AS CRITICAL COMPONENTS IN LIFE SUPPORT

DEVICES OR SYSTEMS WITHOUT THE EXPRESS WRITTEN APPROVAL OF FAIRCHILD SEMICONDUCTOR

CORPORATION.

As used herein:

1. Life support devices or systems are devices or systems

which, (a) are intended for surgical implant into the body,

or (b) support or sustain life, or (c) whose failure to perform

when properly used in accordance with instructions for use

provided in the labeling, can be reasonably expected to

result in significant injury to the user.

2. A critical component is any component of a life support

device or system whose failure to perform can be

reasonably expected to cause the failure of the life support

device or system, or to affect its safety or effectiveness.

PRODUCT STATUS DEFINITIONS

Definition of Terms

Datasheet Identification

Product Status

Definition

Advance Information

Formative or In

Design

This datasheet contains the design specifications for

product development. Specifications may change in

any manner without notice.

Preliminary

First Production

This datasheet contains preliminary data, and

supplementary data will be published at a later date.

Fairchild Semiconductor reserves the right to make

changes at any time without notice in order to improve

design.

No Identification Needed

Obsolete

Full Production

This datasheet contains final specifications. Fairchild

Semiconductor reserves the right to make changes at

any time without notice in order to improve design.

Not In Production

This datasheet contains specifications on a product

that has been discontinued by Fairchild semiconductor.

The datasheet is printed for reference information only.

Rev. H5


型号：	SGL160N60UFDTU
厂家：	FAIRCHILD SEMICONDUCTOR
描述：	Insulated Gate Bipolar Transistor, 160A I(C), 600V V(BR)CES, N-Channel, TO-264AA, TO-264, 3 PIN 双极性晶体管
文件：	总7页 (文件大小：576K)
中文：	中文翻译
下载：	下载PDF数据表文档文件

SGL160N60UFDTU [FAIRCHILD]

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