IRAMX16UP60A_08_技术文档

PD-94684 RevD

IRAMX16UP60A

Series

Integrated Power Hybrid IC for

Appliance Motor Drive Applications.

Description

16A, 600V

International Rectifier's IRAMX16UP60A is an Integrated Power Module developed and optimized for elec-

tronic motor control in appliance applications such as washing machines and variable speed compressor

drives for in-room air-conditioning systems and commercial refrigerators. Plug N Drive technology offers an

extremely compact, high performance AC motor-driver in a single isolated package for a very simple design.

An open emitter configuration of the low side IGBT switches offer easy current feedback and overcurrent

monitor for high precision and reliable control.

A built-in temperature monitor and over-current protection, along with the short-circuit rated IGBTs and

integrated under-voltage lockout function, deliver high level of protection and fail-safe operation.

The integration of the bootstrap diodes for the high-side driver section, and the single polarity power

supply required to drive the internal circuitry, simplify the utilization of the module and deliver further cost

reduction advantages.

Features

• Integrated Gate Drivers and Bootstrap Diodes.

• Temperature Monitor

• Temperature and Overcurrent shutdown

• Fully Isolated Package.

• Low VCE (on) Non Punch Through IGBT Technology.

• Undervoltage lockout for all channels

• Matched propagation delay for all channels

• Low side IGBT emitter pins for current control

• Schmitt-triggered input logic

• Cross-conduction prevention logic

• Lower di/dt gate driver for better noise immunity

• Motor Power range 0.75~2kW / 85~253 Vac

• Isolation 2000V_RMSmin

Absolute Maximum Ratings

Parameter

Description

Value

Units

V_CES/ V_RRM

V⁺

IGBT/Diode Blocking Voltage

Positive Bus Input Voltage

600

V

450

I_O@ T_C=25°C

RMS Phase Current (Note 1)

Pulsed RMS Phase Current (Note 2)

PWM Carrier Frequency

16

I_O@ T_C=100°C

A

8

30

I_O

F_PWM

20

kHz

W

P_D

Power dissipation per IGBT @ T_C=25°C

Isolation Voltage (1min)

31

V_ISO

V_RMS

2000

T_J(IGBT & Diodes)

Operating Junction temperature Range

Mounting torque Range (M3 screw)

-40 to +150

0.5 to 1.0

°C

T_J(Driver IC)

T

Nm

Note 1: Sinusoidal Modulation at V⁺=400V, T_J=150°C, F_PWM=16kHz, Modulation Depth=0.8, PF=0.6, See Figure 3.

Note 2: t_P<100ms; T_C=25°C; F_PWM=16kHz. Limited by I_BUS-ITRIP, see Table "Inverter Section Electrical Characteristics"

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1

IRAMX16UP60A

Internal Electrical Schematic - IRAMX16UP60A

V+(10)

VRU (12)

VRV (13)

VRW (14)

Rg1

Rg3

Rg5

VB1 (7)

U, VS1 (8)

VB2 (4)

V, VS2 (5)

VB3 (1)

W, VS3 (2)

Rg2

22 21 20 19 18 17

VB2 HO2 VS2 VB3 HO3 VS3

23 VS1

LO1 16

LO2 15

LO3 14

24 HO1

25 VB1

1 VCC

Rg4

R₃

Rg6

Driver IC

2 HIN1

3 HIN2

4 HIN3

HIN1 (15)

HIN2 (16)

HIN3 (17)

LIN2 LIN3

F

8

ITRIP EN RCIN VSS COM

5 LIN1

6

7

9

10

11

12 13

LIN1 (18)

LIN2 (19)

R₁

LIN3 (20)

T/I_TRIP(21)

R₂

R_T

THERMISTOR

C

VCC (22)

VSS (23)

2

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IRAMX16UP60A

Absolute Maximum Ratings (Continued)

All voltages are absolute referenced to COM

Conditions

Symbol

Parameter

Min

Max

Units

t_P= 10ms,

Bootstrap Diode Peak Forward

Current

I_BDF

---

4.5

A

T_J= 150°C, T_C=100°C

t_P=100ꢂs, T_C=100°C

ESR / ERJ series

Bootstrap Resistor Peak Power

(Single Pulse)

P_{BR Peak}

V_S1,2,3

V_B1,2,3

V_CC

---

_B1,2,3- 25

-0.3

25.0

V_B1,2,3+0.3

600

W

V

High side floating supply offset

voltage

V

High side floating supply voltage

V

Low Side and logic fixed supply

voltage

-0.3

20

V

Lower of

(V_SS+15V) or

V_CC+0.3V

V

_IN,V_EN

Input voltage LIN, HIN, EN

-0.3

V

Inverter Section Electrical Characteristics @T_J= 25°C

Conditions

Symbol

Parameter

Min

Typ

Max

Units

Collector-to-Emitter Breakdown

Voltage

V_IN=5V, I_C=250ꢂA

V_(BR)CES

600

---

V

V_IN=5V, I_C=1.0mA

(25°C - 150°C)

Temperature Coeff. Of

Breakdown Voltage

ꢀV_(BR)CES/ ꢀT

---

0.3

---

V/°C

V

I_C=8A, V_CC=15V

---

--

1.55

1.80

5

1.85

2.10

80

Collector-to-Emitter Saturation

Voltage

V_CE(ON)

I_C=8A, V_CC=15V, T_J=150°C

V_IN=5V, V⁺=600V

V_IN=5V, V⁺=600V, T_J=150°C

I_C=8A

Zero Gate Voltage Collector

Current

I_CES

μA

V

165

2.0

1.4

--

---

2.4

1.9

1.25

1.10

---

V_FM

Diode Forward Voltage Drop

I_C=8A, T_J=150°C

I_F=1A

Bootstrap Diode Forward Voltage

Drop

V_BDFM

V

I_F=1A, T_J=125°C

T_J=25°C

---

R_BR

Bootstrap Resistor Value

22

ꢁ

T_J=25°C

ꢀR_BR/R_BR

Bootstrap Resistor Tolerance

---

5

%

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3

IRAMX16UP60A

Inverter Section Switching Characteristics @ T_J= 25°C

Conditions

Symbol

Parameter

Min

---

Typ

315

150

465

30

Max

435

180

615

60

Units

E_ON

I_C=8A, V⁺=400V

V_CC=15V, L=2mH

Energy losses include "tail" and

diode reverse recovery

Turn-On Switching Loss

Turn-Off Switching Loss

Total Switching Loss

E_OFF

E_TOT

E_REC

t_RR

ꢂJ

Diode Reverse Recovery energy

Diode Reverse Recovery time

Turn-on Switching Loss

Turn-off Switching Loss

Total Switching Loss

See CT1

70

90

ns

I_C=8A, V⁺=400V

V_CC=15V, L=2mH, T_J=150°C

Energy losses include "tail" and

diode reverse recovery

E_ON

500

270

770

60

700

335

1035

100

150

84

E_OFF

E_TOT

E_REC

t_RR

ꢂJ

Diode Reverse Recovery energy

Diode Reverse Recovery time

Turn-On IGBT Gate Charge

See CT1

120

56

ns

Q_G

I_C=15A, V⁺=400V, V_GE=15V

nC

T_J=150°C, I_C=8A, V_P=600V

V⁺= 450V

FULL SQUARE

RBSOA

SCSOA

I_CSC

Reverse Bias Safe Operating Area

Short Circuit Safe Operating Area

Short Circuit Collector Current

V_CC=+15V to 0V

See CT3

T_J=150°C, V_P=600V,

V⁺= 360V,

10

---

ꢂs

A

V_CC=+15V to 0V

See CT2

T_J=150°C, V_P=600V, t_SC<10ꢂs

V⁺= 360V, V_GE=15V

140

V_CC=+15V to 0V

See CT2

Recommended Operating Conditions Driver Function

The Input/Output logic timing diagram is shown in Figure 1. For proper operation the device should be used within the

recommende conditions. All voltages are absolute referenced to COM. The V_Soffset is tested with all supplies biased at 15V

differential (Note 3)

Symbol

V_B1,2,3

V_S1,2,3

V_CC

Definition

Min

V_S+12

Note 4

12

Max

V_S+20

450

Units

High side floating supply voltage

High side floating supply offset voltage

Low side and logic fixed supply voltage

T/I_TRIPinput voltage

V

20

V

V_T/ITRIP

V_IN

V_SS

V_SS+5

V_SS

Logic input voltage LIN, HIN

Note 3: For more details, see IR21365 data sheet

Note 4: Logic operational for V_sfrom COM-5V to COM+600V. Logic state held for V_sfrom COM-5V to COM-V_BS.

(please refer to DT97-3 for more details)

4

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IRAMX16UP60A

Static Electrical Characteristics Driver Function

V_BIAS(V_CC, V_BS1,2,3)=15V, unless otherwise specified. The V_INand I_INparameters are referenced to COM and are applicable

to all six channels. (Note 3)

Symbol

V_IH

Definition

Min

3.0

---

Typ

---

Max

---

Units

V

Logic "0" input voltage

V_IL

Logic "1" input voltage

---

0.8

11.6

11.4

---

V

_CCUV+,V_BSUV+

V_CCand V_BSsupply undervoltage Positive going threshold

V_CCand V_BSsupply undervoltage Negative going threshold

V_CCand V_BSsupply undervoltage lock-out hysteresis

Input Clamp Voltage (HIN, LIN, T/I_TRIP) I_IN=10ꢂA

Quiescent V_BSsupply current V_IN=0V

Quiescent V_CCsupply current V_IN=0V

Offset Supply Leakage Current

Input bias current V_IN=5V

10.6

10.4

---

11.1

10.9

0.2

5.2

---

V

V_CCUV-,V_BSUV-

V_CCUVH,V_BSUVH

V_{IN, Clamp}

I_QBS

V

4.9

---

5.5

165

3.35

60

V

ꢂA

mA

ꢂA

V

I_QCC

---

I_LK

---

I_IN+

---

200

100

30

300

220

100

1

I_IN-

Input bias current V_IN=0V

---

T/I_TRIP+

T/I_TRIP-

T/I_TRIPbias current V_ITRIP=5V

---

T/I_TRIPbias current V_ITRIP=0V

---

0

V(T/I_TRIP

)

T/I_TRIPthreshold Voltage

3.85

---

4.30

0.07

4.75

---

V(T/I_TRIP,HYS)

T/I_TRIPInput Hysteresis

V

Dynamic Electrical Characteristics

Driver only timing unless otherwise specified.

Symbol

Parameter

Min

Typ

Max

Units Conditions

Input to Output propagation turn-

on delay time (see fig.11)

T_ON

---

590

---

ns

V_CC=V_BS= 15V, I_C=8A,

V⁺=400V

Input to Output propagation turn-

off delay time (see fig. 11)

T_OFF

---

660

---

ns

T_FLIN

T_BLT-Trip

D_T

V_IN=0 & V_IN=5V

V_BS=V_CC=15V

Input Filter time (HIN, LIN)

I_TRIPBlancking Time

100

220

200

150

290

ns

Dead Time (V_BS=V_DD=15V)

360

75

V_CC= V_BS= 15V, external dead

time> 400ns

V_CC=V_BS= 15V, I_C=8A,

V⁺=400V

Matching Propagation Delay Time

(On & Off)

M_T

---

40

---

ns

ꢂs

I_Tripto six switch to turn-off

propagation delay (see fig. 2)

T_ITrip

1.75

T_C= 25°C

---

7.7

6.7

---

Post I_Tripto six switch to turn-off

clear time (see fig. 2)

T_FLT-CLR

ms

T_C= 100°C

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5

IRAMX16UP60A

Thermal and Mechanical Characteristics

Symbol

R_th(J-C)

R_th(C-S)

C_D

Parameter

Min

Typ

3.5

5.0

0.1

---

Max

4.0

5.5

---

Units Conditions

Flat, greased surface. Heatsink

°C/W compound thermal conductivity

1W/mK

Thermal resistance, per IGBT

Thermal resistance, per Diode

Thermal resistance, C-S

Creepage Distance

---

mm

3.2

See outline Drawings

Internal NTC - Thermistor Characteristics

Parameter

Definition

Min

Typ

Max

103

Units Conditions

R₂₅

R₁₂₅

B

T_C= 25°C

Resistance

97

100

kꢁ

T_C= 125°C

Resistance

2.25

4165

-40

2.52

4250

2.80

4335

125

B-constant (25-50°C)

k

R₂= R₁e ^{[B(1/T2 - 1/T1)]}

Temperature Range

°C

T_C= 25°C

Typ. Dissipation constant

1

mW/°C

Input-Output Logic Level Table

V⁺

I_TRIP

FLT- EN

HIN1,2,3 LIN1,2,3 U,V,W

V⁺

Ho

Hin1,2,3

1

0

1

X

0

1

X

1

0

1

X

(15,16,17)

U,V,W

(8,5,2)

0

IC

Driver

Off

Lin1,2,3

Lo

(18,19,20)

6

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IRAMX16UP60A

HIN1,2,3

LIN1,2,3

T/I_TRIP

U,V,W

HIN1,2,3

LIN1,2,3

50%

T/I_TRIP

U,V,W

50%

T_T/ITRIP

T_FLT-CLR

Note 5: The shaded area indicates that both high-side and low-side switches are off and therefore the

half-bridge output voltage would be determined by the direction of current flow in the load.

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7

IRAMX16UP60A

Module Pin-Out Description

1

Name

V_B3

Description

High Side Floating Supply Voltage 3

Output 3 - High Side Floating Supply Offset Voltage

none

U, V_S3

NA

2

3

V_B2

4

High Side Floating Supply voltage 2

Output 2 - High Side Floating Supply Offset Voltage

none

V,V_S2

NA

5

6

V_B1

7

High Side Floating Supply voltage 1

Output 1 - High Side Floating Supply Offset Voltage

none

W,V_S1

8

9

NA

V⁺

10

11

12

13

14

15

16

17

18

19

20

21

22

23

Positive Bus Input Voltage

NA

none

L_E1

Low Side Emitter Connection - Phase 1

Low Side Emitter Connection - Phase 2

Low Side Emitter Connection - Phase 3

Logic Input High Side Gate Driver - Phase 1

Logic Input High Side Gate Driver - Phase 2

Logic Input High Side Gate Driver - Phase 3

Logic Input Low Side Gate Driver - Phase 1

Logic Input Low Side Gate Driver - Phase 2

Logic Input Low Side Gate Driver - Phase 3

Temperature Monitor and Shut-down Pin

+15V Main Supply

L_E2

L_E3

H_IN1

H_NI2

H_IN3

L_IN1

L_IN2

L_IN3

T/I_TRIP

V_CC

V_SS

Negative Main Supply

1

23

8

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IRAMX16UP60A

Typical Application Connection IRAMX16UP60A

BOOT-STRAP

CAPACITORS

V_B3

Cb

V_S3

U

V_B2

V_S3

3-Phase AC

MOTOR

V

CURRENT SENSING CAN USE A

SINGLE SENSE RESISTOR OR PHASE

LEG SENSING AS SHOWN

V_B1

V_S1

W

V+

DC BUS

CAPACITORS

L_E1

L_E2

L_E3

PHASE LEG

CURRENT

SENSE

PGND

H_IN1

H_IN2

H_IN3

L_IN1

L_IN2

L_IN3

I^TRIP

CONTROLLER

V_cc(15 V)

V_SS

5k

10.2k

TEMP

SENSE

6.8K

0.1mF

1mF

3.3 V

O/C

SENSE

10mF

(ACTIVE LOW)

O/C

SENSE

(ACTIVE LOW)

DGND

1. Electrolytic bus capacitors should be mounted as close to the module bus terminals as possible to reduce ringing and

EMI problems. Additional high frequency ceramic capacitor mounted close to the module pins will further improve perfor-

mance.

2. In order to provide good decoupling between V_CC-V_SSand V_B1,2,3-V_S1,2,3terminals, the capacitors shown connected

between these terminals should be located very close to the module pins. Additional high frequency capacitors, typi-

cally 0.1ꢂF, are strongly recommended.

3. Value of the boot-strap capacitors depends upon the switching frequency. Their selection should be made based on

IR design tip DN 98-2a, application note AN-1044 or Figure 9. Bootstrap capacitor value must be selected to limit the

power dissipation of the internal resistor in series with the V_CC. (see maximum ratings Table on page 3).

4. After approx. 8ms the FAULT is reset. (see Dynamic Characteristics Table on page 5).

5. PWM generator must be disabled within Fault duration to garantee shutdown of the system, overcurrent condition

must be cleared before resuming operation.

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9

IRAMX16UP60A

14

12

10

8

6

T_C= 100°C

T_C= 110°C

T_C= 120°C

4

T_J= 150°C

2

Sinusoidal Modulation

0

2

4

6

8

10

12

14

16

18

20

PWM Frequency - kHz

Figure 3. Maximum Sinusoidal Phase Current vs. PWM Switching Frequency

V⁺=400V , T_J=150°C, Modulation Depth=0.8, PF=0.6

10

8

T_J= 150°C

Sinusoidal Modulation

6

F_PWM= 20kHz

F_PWM= 16kHz

4

F

_PWM= 12kHz

2

0

1

10

100

Modulation Frequency - Hz

Figure 4. Maximum Sinusoidal Phase Current vs. Modulation Frequency

V⁺=400V, T_J=150°C, T_C=100°C, Modulation Depth=0.8, PF=0.6

10

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IRAMX16UP60A

150

125

100

75

T_J= 150°C

Sinusoidal Modulation

F_PWM= 12 kHz

F_PWM= 16 kHz

50

F

_PWM= 20 kHz

25

0

1

2

3

4

5

6

7

8

9

10

11

12

Output Phase Current - A_RMS

Figure 5. Total Power Losses vs. PWM Switching Frequency, Sinusoidal modulation

V⁺=400V , T_J=150°C, Modulation Depth=0.8, PF=0.6

150

125

100

75

50

25

0

T_J= 150°C

Sinusoidal Modulation

F_PWM= 12 kHz

_PWM= 16 kHz

F_PWM= 20 kHz

F

0

1

2

3

4

5

6

7

8

9

10

11

12

Output Phase Current - A_RMS

Figure 6. Total Power Losses vs. Output Phase Current, Sinusoidal modulation

_BUS=400V , T_J=150°C, Modulation Depth=0.8, PF=0.6

V

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11

IRAMX16UP60A

160

140

120

100

80

F_PWM= 12 kHz

F_PWM= 16 kHz

F_PWM= 20 kHz

60

40

T_J= 150°C

Sinusoidal Modulation

20

0

2

4

6

8

10

12

14

Output Phase Current - A_RMS

Figure 7. Maximum Allowable Case temperature vs. Output RMS Current per Phase

200

180

160

140

120

100

80

60

40

20

0

20

40

60

80

100

120

140

Thermistor Temperature [°C]

Figure 8. Estimated Maximum IGBT Junction Temperature vs. Thermistor Temperature

12

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IRAMX16UP60A

5.5

5.0

4.5

4.0

3.5

3.0

2.5

2.0

1.5

1.0

0.5

0.0

T_THERM

R_THERM

ꢁ

T_THERM

R_THERM

ꢁ

T_THERM

°C

90

95

100

105

110

115

120

125

R_THERM

ꢁ

°C

-40

-35

-30

-25

-20

-15

-10

-5

0

5

10

15

20

°C

25

30

35

40

45

50

55

60

65

70

75

80

85

4397119

3088599

2197225

1581881

1151037

846579

628988

471632

357012

272500

209710

162651

127080

100000

79222

63167

50677

40904

33195

27091

22224

18322

15184

12635

10566

8873

7481

6337

5384

4594

3934

3380

2916

2522

R

THERM

Min

Avg

12k

Max

V_THERM

6.8k

-40 -30 -20 -10

0

10 20 30 40 50 60 70 80 90 100 110 120 130

Thermistor Temperature - °C

Figure 9. Thermistor Readout vs. Temperature (6.8kohm, 1% pull down resistor)

and Nominal Thermistor Resistance values vs. Temperature Table.

16.0

15ꢂF

15.0

V⁺

14.0

D_BS

C_BS

R_BS

13.0

12.0

11.0

10.0

9.0

v_B

R_G1

+15V

H_IN

V_CC

H_O

H_IN

L_IN

U,V,W

GND

V_S

L_O

R_G2

L_IN

10ꢂF

V_SS

COM

V_SS

8.0

6.8ꢂF

7.0

6.0

4.7ꢂF

5.0

4.0

3.3ꢂF

15

3.0

2.0

0

5

10

20

PWM Frequency - kHz

Figure 10. Recommended Bootstrap Capacitor Value vs. Switching Frequency

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13

IRAMX16UP60A

Figure 11. Switching Parameter Definitions

V

I_C

CE

I_C

V

CE

90% I

C

50%

_IN/L_IN

90% I_C

H

H /L

IN IN

50%

CE

50%

_IN/L_IN

V

H

H /L

IN IN

50%

CE

V

10% I_C

t_r

t_f

T_ON

T_OFF

Figure 11a. Input to Output Propagation

turn-on Delay Time

Figure 11b. Input to Output Propagation

turn-off Delay Time

I_F

V_CE

H_IN/L_IN

I_rr

t_rr

Figure 11c. Diode Reverse Recovery

14

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IRAMX16UP60A

V⁺

5V

Ho

Lo

IN

IO

Hin1,2,3

Lin1,2,3

IC

Driver

U,V,W

Figure CT1. Switching Loss Circuit

V⁺

Ho

Hin1,2,3

IN

IO

1k

10k

IC

Driver

V

CC

U,V,W

Lin1,2,3

5VZD

Lo

IN

I_o

Figure CT2. S.C.SOA Circuit

V⁺

Ho

Hin1,2,3

IN

IO

1k

10k

V

IC

Driver

CC

U,V,W

I_o

5VZD

Lo

Lin1,2,3

IN

Figure CT3. R.B.SOA Circuit

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15

IRAMX16UP60A

Package Outline IRAMX16UP60A

note 2

note 3

035-Z2L03

IRAMX16UP60A

note 1

M

Notes:

Dimensions in mm

1- Marking for pin 1 identification

2- Product Part Number

3- Lot and Date code marking

4- Convex only 0.15mm typical

5- Tollerances 0.5mm, unless otherwise stated

FormountinginstructionseeAN-1049

16

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IRAMX16UP60A

Package Outline IRAMX16UP60A-2

note 2

note 3

035-Z2L03

IRAMX16UP60A

note 1

M

Notes:

Dimensions in mm

1- Marking for pin 1 identification

2- Product Part Number

3- Lot and Date code marking

4- Convex only 0.15mm typical

5- Tollerances 0.5mm, unless otherwise stated

FormountinginstructionseeAN-1049

Data and Specifications are subject to change without notice

IR WORLD HEADQUARTERS: 233 Kansas St., El Segundo, California 90245, USA Tel: (310) 252-7105

TAC Fax: (310) 252-7903

Visit us at www.irf.com for sales contact information

07/05

www.irf.com

17


型号：	IRAMX16UP60A_08
厂家：	Infineon
描述：	Integrated Power Hybrid IC for Appliance Motor Drive Applications 集成功率混合IC，适用于家电电机驱动应用电机驱动
文件：	总17页 (文件大小：379K)
中文：	中文翻译
下载：	下载PDF数据表文档文件

IRAMX16UP60A_08 [INFINEON]

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