The FZ600R12KS4 IGBT module from Infineon Technologies is built for
heavy-duty industrial and power systems. With high voltage and current
capacity, advanced technology, and strong thermal design, it’s perfect
for applications like motor control, renewable energy, and UPS systems.
This article highlights its features, uses, and benefits for us looking
for reliable, high-performance solutions.
Catalog
The FZ600R12KS4
is a high-performance IGBT module from Infineon Technologies,
designed for industrial and power electronics applications. With a
maximum voltage rating of 1200V and a nominal current rating of 600A, it
delivers exceptional efficiency in high-power environments. Its
advanced IGBT technology ensures fast switching with minimal power loss,
while the integrated freewheeling diode supports reverse current
handling. The module's robust thermal design, featuring a baseplate for
effective heat dissipation, enhances reliability under heavy loads,
making it ideal for demanding applications.
Common applications include industrial motor drives, renewable energy
systems, and high-power inverters for UPS and traction systems. Its
compact design ensures ease of installation, and its ability to handle
high operating temperatures up to 150°C makes it suitable for harsh
environments.
Optimize your systems with the reliable and efficient FZ600R12KS4 IGBT module—contact us today to place your bulk orders!
• High Voltage and Current Capacity:
- Maximum collector-emitter voltage (VCES): 1200V
- Nominal collector current (IC): 600A
• Advanced IGBT Technology: Ensures fast switching with minimal power loss for improved energy efficiency.
• Integrated Freewheeling Diode: Supports reverse current handling, for motor control and inverter circuits.
• Robust Thermal Management: Includes a durable baseplate for efficient heat dissipation, ensuring reliable performance under heavy operational loads.
• Compact and Durable Design: Optimized for easy installation in high-power and space-constrained environments.
• High-Temperature Tolerance: Operates effectively at junction temperatures up to 150°C, suitable for harsh environments.
• Versatile Applications: Widely used in industrial motor drives, renewable energy systems, UPS, and traction systems.
The provided circuit diagram is part of the FZ600R12KS4 power module,
which is a high-power IGBT (Insulated Gate Bipolar Transistor) module.
The diagram includes components such as the IGBT itself and its
anti-parallel diode. The IGBT is represented by the three-terminal
symbol, where terminals 1, 2, and 3 correspond to the collector, gate,
and emitter, respectively. Terminal 5 serves as an auxiliary gate
connection, which helps control the gate signal during switching.
The diode connected in parallel with the IGBT ensures proper
operation during reverse current flow, protecting the device in
applications such as motor drives or inverters. The diagram also shows
the control path for switching operations, emphasizing the role of the
gate (terminal 2) in modulating the current flow between the collector
and emitter (terminals 1 and 3). This module is designed for
high-efficiency and reliable performance in power electronics
applications like industrial motor drives and renewable energy systems.
Condition
|
Condition
|
Symbol
|
Value
|
Unit
|
Collector-emitter voltage
|
Tvj = 25°C
|
VCES
|
1200
|
V
|
Continuous DC collector
current
|
TC = 60°C, Tvj max = 150°C
|
IC nom
|
600
|
A
|
TC = 25°C, Tvj max = 150°C
|
IC
|
700
|
A
|
Repetitive peak collector
current
|
tp = 1 ms
|
ICRM
|
1200
|
A
|
Total power dissipation
|
TC = 25°C, Tvj max = 150
|
Ptot
|
3900
|
W
|
Gate-emitter peak voltage
|
-
|
VGES
|
+/-20
|
V
|
The performance curves provided for the FZ600R12KS4 module illustrate the relationship between the collector-emitter voltage (VCE) and the collector current (IC) under different conditions. In the left graph, the curves compare the behavior of the IGBT at two junction temperatures (Tj),
25°C and 125°C. At higher temperatures, the device exhibits slightly
reduced current capability due to increased thermal resistance and
conduction losses, but the general trend indicates stable performance
under varying thermal conditions.
The right graph displays the IC-VCE characteristics for different gate-emitter voltages (VGE). As VGE
increases, the collector current capability also increases, reflecting
improved conduction due to enhanced gate drive. This demonstrates the
importance of gate voltage control in optimizing the switching and
conduction efficiency of the IGBT. These curves highlight the module's
adaptability to various operating conditions and its ability to handle
high current levels with precise control.
In the left graph, the relationship between the gate-emitter voltage (VGE) and the collector current (IC) is shown for junction temperatures (Tj) of 25°C and 125°C. As VGE increases, IC
also increases, demonstrating the module’s dependence on gate voltage
for current control. At elevated temperatures, the current rises
slightly for the same VGE, reflecting the thermal characteristics of the IGBT.
The right graph illustrates the energy losses (E) during turn-on (Eon) and turn-off (Eoff) as a function of IC at 125°C. Both energy losses increase with higher current levels, with turn-off energy losses (Eoff)
being higher due to the switching dynamics. These curves emphasize the
importance of thermal management and efficient gate drive design to
optimize performance and minimize energy losses during operation.
Alternative Model
|
Manufacturer
|
Voltage Rating (V)
|
Current Rating (A)
|
Key Features/Applications
|
FZ600R12KE3
|
Infineon Technologies
|
1200
|
600
|
Advanced thermal management,
high switching efficiency.
|
CM600HA-24H
|
Mitsubishi Electric
|
1200
|
600
|
Robust performance for
industrial and renewable systems.
|
SKM600GB12T4
|
Semikron
|
1200
|
600
|
Ideal for motor drives and
inverters.
|
IXFN600N12T
|
IXYS Corporation
|
1200
|
600
|
Excellent switching
characteristics for power control.
|
GD600H12C2S
|
Global Power Technologies
|
1200
|
600
|
Cost-effective, suitable for
renewable and industrial systems.
|
FF600R12ME4
|
Infineon Technologies
|
1200
|
600
|
Enhanced efficiency, faster
switching in high-load environments.
|
Advantages of FZ600R12KS4
• High Power Capacity: Handles up to 600A and 1200V, making it perfect for demanding uses like industrial motor drives and renewable energy systems.
• Efficient Switching: Uses advanced IGBT technology for fast, low-loss switching, boosting system performance and reducing heat.
• Built-in Freewheeling Diode: Simplifies design and supports reverse current flow, making it versatile for different applications.
• Effective Thermal Management: Comes with a baseplate that efficiently dissipates heat, ensuring reliable performance during heavy use.
• Handles High Temperatures: Operates smoothly at temperatures up to 150°C, ideal for harsh conditions.
• Compact Design: Fits easily into tight spaces without compromising power or performance.
Disadvantages of FZ600R12KS4
• High Cost: Its advanced features make it expensive, which may not suit budget-conscious projects.
• Complex Installation: Needs proper cooling and additional components for best results, adding to system complexity.
• Voltage Limitation: The 1200V rating isn’t suitable for ultra-high voltage applications.
• Overkill for Small Projects: Its high capacity may be unnecessary for smaller tasks, leading to inefficiencies.
• Requires Compatible Components: Needs specific drivers and protective systems, increasing total project costs.
• Motor Control: Used in machines to control motors efficiently in factories and industries.
• Solar and Wind Energy: Helps convert energy from solar panels and wind turbines into usable electricity.
• Power Backup Systems: Used in UPS (Uninterruptible Power Supplies) to ensure a steady power supply during outages.
• Trains and Electric Vehicles: Powers systems in trains, trams, and electric cars for smooth and reliable operation.
• Cooling and Heating Systems: Used in large HVAC (Heating, Ventilation, and Air Conditioning) systems to save energy.
• Electric Grids: Helps manage power in electricity networks and storage systems.
• Welding Machines: Provides stable power for industrial welding equipment.
• Car Charging Stations: Powers fast and efficient chargers for electric cars.
• Elevators and Lifts: Ensures smooth operation of lifts and escalators.
The packaging dimensions of the FZ600R12KS4 IGBT module, as shown in
the provided diagram, detail the physical layout and mounting
specifications of the device. The top and side views include
measurements, such as the overall dimensions of 106.4 mm x 61 mm and the
height of 36.5 mm, ensuring proper space allocation in circuit designs.
The module's screw holes, with specified tolerances and positions, are
designed for secure mounting and efficient electrical connections.
The diagram specifies the terminal locations for the collector,
emitter, and gate connections, ensuring clear identification during
installation. Additional tolerances and thread depth specifications
(maximum screw depths of 8 mm and 10 mm for different regions) highlight
the importance of precision when integrating the module into a system.
These details ensure compatibility with industry standards and simplify
the integration of this high-power device into power electronic
applications.
The FZ600R12KS4 is a durable and efficient module ideal for demanding
industrial needs. It handles high power, works in tough conditions, and
fits compact spaces, making it a great choice for bulk buyers. Upgrade
your systems with this reliable solution—place your orders today!
Datasheet PDF
FZ600R12KS4 Datasheets
FZ600R12KS4 Details PDF
FZ600R12KS4 Details PDF for FR.pdf
FZ600R12KS4 Details PDF for KR.pdf
FZ600R12KS4 Details PDF for ES.pdf
FZ600R12KS4 Details PDF for IT.pdf
FZ600R12KS4 Details PDF for DE.pdf
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