Fuji Electric P642 series Small Intelligent Power Module User Manual
- May 15, 2024
- Fuji Electric
Table of Contents
Fuji Electric P642 series Small Intelligent Power Module
Cautions
This Instruction contains the product specifications, characteristics,
data, materials, and structures as of August 2023. The contents are subject to
change without notice for specification changes or other reasons. When using a
product listed in this Instruction be sure to obtain the latest
specifications. The application examples in this note show the typical
examples of using Fuji products and this note shall neither assure to
enforcement of the industrial property including some other rights nor grant
the license.
Although Fuji Electric Co., Ltd. continually strives to enhance product quality and reliability, a small percentage of semiconductor products may become faulty. When using Fuji Electric semiconductor products in your equipment, be sure to take adequate safety measures such as redundant, flame retardant and fail-safe design to prevent a semiconductor product failure from leading to a physical injury, property damage or other problems. The products described in this application manual are manufactured to be used in the following industrial electronic and electrical devices that require normal reliability.
- Compressor motor inverter
- Fan motor inverter for room air conditioner
- Compressor motor inverter for heat pump applications, etc.
If you need to use a semiconductor product in this application note for equipment requiring higher reliability than normal, such as listed below, be sure to contact Fuji Electric Co., Ltd. to obtain prior approval. When using these products, take adequate safety measures such as a backup system to prevent the equipment from malfunctioning when a Fuji EElectricproduct is incorporated into the equipment becomes faulty.
- Transportation equipment (mounted on vehicles and ships)
- Trunk communications equipment
- Traffic-signal control equipment
- Gas leakage detectors with an auto-shutoff function
- Disaster prevention/security equipment
- Safety devices, etc.
Do not use a product in this application note for equipment requiring extremely high reliability such as:
- Space equipment
- Airborne equipment
- Atomic control equipment
- Submarine repeater equipment
- Medical equipment
All rights reserved. No part of this application note may be reproduced without permission in writing from Fuji Electric Co., Ltd. If you have any questions about any portion of this application note, ask Fuji Electric Co., Ltd. or its sales agencies. Neither Fuji Electric Co., Ltd. nor its agencies shall be liable for any injury or damage caused by any use of the products, not by instructions set forth herein.
This manual describes the following contents for the Fuji IGBT Intelligent Power Module “Small IPM”
- Product outline
- Explanation of terminal symbols and terminology
- Detailed description and design guidelines for control and power terminals
- Recommended wiring and layout, along with mounting guidelines
Introduction
< Product overview>
- IGBT modules used in inverters for compressors and air conditioner fans are developing rapidly in response to the growing demand for energy saving, equipment miniaturization and weight reduction.
- IGBTs are devices that combine the high-speed switching performance of power MOSFETs and the high-voltage, high-current capabilities of bipolar transistors and are expected to further develop in the future.
- Among them, the IPM (Intelligent Power Module) is a 3-phase IGBT inverter bridge circuit with integrated gate drive circuits and protection circuits.
-
7th gen. IGBT/FWD technology realizes low loss and energy saving of equipment. - Guaranteed Top =150°C allows expansion of output current.
- High High-accuracy short-circuit protection detection expands the overload operation range.
- Compatible pin assignments, footprints, and mounting dimensions with conventional Small IPM.
- The product lineup of 650V/15A to 35A.
- The lower total loss against conventional products by improving the trade-off between Collector-Emitter saturation voltage VcE(sat) and switching loss.
- Achieves low dv/dt and low switching loss compared to conventional products.
- Optimally designed IGBT drive circuit.
- The high-side control IC (HVIC) contains a high-voltage level shift circuit.
- This product can be driven directly by an MCU (microcontroller) on both the high-side and low-side arms. The voltage level of the input signals is 3.3V or 5V.
- Since the wiring length between the internal drive circuit and IGBT is short the impedance of the drive circuit is low, and no reverse bias power supply is required.
- Normally, an IPM device requires a total of four isolated control power supplies: one for the lower sides and three for the upper sides.
- However, since this IPM has built-in bootstrap diodes (BSD), isolated power supplies for the high sides are not needed.
< Built-in protection circuits>
- The following built-in protection circuits are incorporated in the product:
- OC: Over current protection
- UV: Under voltage protection for power supplies of the control IC
- LT: Temperature sensor output function
- OH: Overheating protection (only applied to some products)
- FO: Fault alarm signal output
- The OC protection circuits protect the IGBT against overcurrent, load short-circuit or arm short-circuit.
- The protection circuit can monitor the emitter current using an external shunt resistor in each low-side
- IGBT and thus it can protect the IGBT against arm short-circuit.
- The UV protection circuit operates when the control power supply voltage drops below the trip voltage level. It is built into all of the IGBT drive circuits.
- The OH protection circuit protects the product from overheating. The OH protection circuit is built into the control IC of the low-side arm (LVIC).
- The temperature sensor output function is built into the LVIC and converts the detected temperature into an analog voltage output.
- The FO function outputs a fault signal when the circuit detects abnormal conditions, thus making it possible to shut down the system reliably and preventing destruction by outputting the fault signal to the microprocessor unit controlling the product.
< Compact package>
- This product uses high heat dissipation aluminium insulated metal substrate (IMS), which improves the heat radiation.
- The control input terminals have a shrink pitch of 1.778mm (70mil).
- The power terminals have a standard pitch of 2.54mm (100).
Product Lineup
Table. 1-1 Lineup
Definition of Type Name and Marking Spec
Table. 1 2 Product code
TYPE NAME
| PRODUCTS CODE
---|---
A1| A2
6MBP15XSJ065-50| L| J
6MBP15XSK065-50| L| K
6MBP20XSJ065-50| M| J
6MBP20XSK065-50| M| K
6MBP30XSJ065-50| O| J
6MBP30XSK065-50| O| K
6MBP35XSJ065-50| P| J
6MBP35XSK065-50| P| K
Outline Dimensions
Note.1
IMS(Insulated Metal Substrate) is deliberately protruded to improve the
thermal conductivity between the IMS and the heat sink.
Note.2
The thickness from the package surface to the back side includes the IMS.
Note.3
The thickness of the case part of the package’s outer wall. (excluding the IMS
and marking surface)
Note.4
Height of the terminal and height of the stopper part including IMS.
Table. 1-3 Pin assignment
Pin No. | Pin Name | Pin No. | Pin Name |
---|---|---|---|
3 | VB(U) | 22 | N(W) |
5 | VB(V) | 23 | N(V) |
7 | VB(W) | 24 | N(U) |
9 | IN(HU) | 26 | W |
10 | IN(HV) | 28 | V |
11 | IN(HW) | 30 | U |
12 | VCCH | 32 | P |
13 | COM | 36 | NC |
14 | IN(LU) | ||
15 | IN(LV) | ||
16 | IN(LW) | ||
17 | VCCL | ||
18 | VFO | ||
19 | IS | ||
20 | COM | ||
21 | TEMP |
Absolute Maximum Ratings
An example of the absolute maximum ratings of 6MBP20XSJ065 50 is shown in
Table 1 4.
Table 1-4
Item | Symbol | Rating | Unit | Description |
---|
DC Bus Voltage
|
V DC(terminal)
|
450
|
V
| DC voltage that can be applied between
P-N(U), N(V), N(W) terminals
Bus Voltage (Surge)
|
V DC(Surge,terminal)
|
500
|
V
| Peak value of the surge voltage that can be applied between P- N(U), N(V), N(W) terminals during switching operation
Collector-Emitter Voltage
|
V CE(chip)
|
650
|
V
| Maximum collector-emitter voltage of IGBT and repeated peak reverse voltage
of FWD.
Collector Current| I C| 20| A| Maximum collector current for the IGBT chip.
T c=25°C
Peak Collector Current| I CP| 40| A| Maximum pulse collector current for
the IGBT chip. T c=25°C
Forward Current| I F| 20| A| Maximum forward current for the FWD chip. T
c=25°C
Peak Forward Current| I FP| 40| A| Maximum pulse forward current for the
FWD chip. T c=25°C
Collector Power Dissipation| P D_IGBT| 41.0| W| Maximum power dissipation
for one IGBT element at T c=25°C
FWD Power Dissipation| P D_FWD| 33.9| W| Maximum power dissipation for one
FWD element at T c=25°C
Self-operation “DC Bus voltage” of circuit protection between upper-arm and
lower-arm|
V DC(sc)
|
400
|
V
| V CC= V B(*)=13.5~16.5V
T vj=125oC, arm short circuit, non-repetitive less than 2us.
Virtual Junction Temperature of Inverter Block
|
T vj
|
+150
|
°C
| Maximum virtual junction temperature of the IGBT chips and the FWD chips.
Operating life is limited by junction temperature and power cycle.
Operating Virtual Junction Temperature of Inverter Block
|
T vjop
|
-40 ~
+150
|
°C
| Junction temperature of the IGBT and FWD chips during continuous operation.
Operating life is limited by junction temperature and power cycle.
Absolute Maximum Ratings at T vj =25 C, V CC =15V (unless otherwise
Table
Absolute Maximum Ratings at T vj =25 C, V CC =15V (Continued
Item | Symbol | Rating | Unit | Descriptions |
---|---|---|---|---|
High-side Supply Voltage | V CCH | -0.5 ~ 20 | V | Voltage that can be applied |
between COM and VCCH terminal
Low-side Supply Voltage| V CCL| -0.5 ~ 20| V| Voltage that can be applied
between COM and VCCL terminal
High-side Bias Absolute Voltage| V B(U)-COM
V B(V)-COM
V B(W)-COM
|
-0.5 ~ 670
|
V
| Voltage that can be applied between VB(U)-COM, VB(V)- COM,VB(W)-COM terminal
High-side Bias Voltage for IGBT Gate Driving| V B(U)
V B(V)
V B(W)
|
-0.5 ~ 20
|
V
| Voltage that can be applied between U-VB(U), V-VB(V), W-
VB(W) terminal
High-side Bias Offset Voltage| V U V V V W|
-5 ~ 650
|
V
| The voltage that can be applied between U-COM, V-COM, and W- COM terminals.
Input Signal Voltage| V IN| -0.5 ~ V CCH+0.5
-0.5 ~ V CCL+0.5
| V| Voltage that can be applied between IN()-COM terminal
Input Signal Current| I| 3| mA| Maximum input current that flows from
IN() to COM terminal
Fault Signal Voltage| V FO| -0.5 ~ V CCL+0.5| V| Voltage that can be
applied between COM and VFO terminal
Fault Signal Current| INFO| 1| mA| Sink current that flows from VFO to COM
terminal
Over Current Sensing Input Voltage| V IS| -0.5 ~ V CCL+0.5| V| Voltage
that can be applied between IS and COM terminal
Maximum Junction Temperature of Control Circuit Block|
T vj
|
150
|
°C
| Maximum junction temperature of the control circuit block
Operating Case Temperature
|
T c
|
-40 ~ +125
|
°C
| Operating case temperature (temperature of the aluminium plate directly under the IGBT or the FWD)
Storage Temperature
|
T stg
|
-40 ~ +125
|
°C
| Range of ambient temperature for storage or transportation, when there is no electrical load
Isolation Voltage
|
V isol
|
AC 1500
|
Vrms
| Maximum effective value of the sine-wave voltage between the terminals and the heat sink, when all terminals are shorted simultaneously. (Sine wave = 60Hz / 1min)
Mounting torque of screws
|
M S
|
0.59 ~ 0.98
|
N・m
| Maximum torque value when tightening the product and heat sink with M3 screws.
< Absolute
Maximum Rating of Collector-Emitter Voltage>
During
operation, the voltage between P N(U, V, W) is usually applied to the high
side or low side of one phase Therefore, Use the product with the voltage
applied between P N(*) within the absolute maximum ratings The collector-
emitter voltage absolute maximum rating is described below:
CE(chip) Since
VCE(chip) cannot be measured directly, use the product with V DC(terminal)
V DC( Surge, a terminal which is the voltage between P N(*) terminals, within
the absolute maximum ratings
VDC(terminal) DC
bus voltage (between P N(U, V, W terminals)
VDC(Surge, terminal) DC
bus voltage at P N(U, V, W terminals including surge voltage generated during
switching Fig 1 7 shows the waveforms during a short circuit, IGBT turn off
and FWD reverse recovery Since V DC( Surge, terminal is different in each
situation, it is necessary to set V DC(terminal) considering these situations
VCE(chip) is the collector-emitter voltage absolute maximum rating of the IGBT chip V DC(Surge, terminal) is specified considering the margin of surge voltage generated by the wiring inductance inside the Product Also, VDC(terminal) is specified with margin considering the surge voltage generated by the wiring inductance between the P N(*) terminal and the bulk capacitor .
Fig.1-7 Waveforms and Collector-Emitter voltage during IGBT turn off, FWD reverse recovery, and short circuit.
Read User Manual Online (PDF format)
Read User Manual Online (PDF format) >>