Sunday, July 19, 2026
ComponentsPower Semiconductors

Fuji 2MBI1400VXB-170E-50: A Technical Review of a High-Power V-Series IGBT

2MBI1400VXB-170E-50 | Fuji 1700V 1400A V-Series IGBT Module

High-Power V-Series IGBT Module for Megawatt-Scale Systems

The Fuji Electric 2MBI1400VXB-170E-50 is a high-power IGBT module engineered for the most demanding power conversion applications. As a cornerstone of Fuji Electric’s 6th Generation V-Series, this device provides a robust solution for developing highly efficient and reliable megawatt-scale systems. It integrates a half-bridge configuration, leveraging an advanced trench gate and field-stop structure to achieve superior performance in applications where power density, thermal stability, and long-term reliability are critical.

  • Core Specifications: 1700V | 1400A | VCE(sat) 2.10V (typ)
  • Key Advantages: Substantially reduced conduction losses, high thermal stability with a maximum junction temperature of 175°C.
  • System Impact: Enables smaller heatsink designs and enhances overall system reliability under heavy load conditions.

Download Official Datasheet (PDF)

Technical Analysis of the V-Series Advantage

The performance of the 2MBI1400VXB-170E-50 is rooted in Fuji Electric’s V-Series chip technology. This design addresses the core engineering challenges of minimizing power losses and enhancing durability in high-current applications. A key parameter is the low collector-emitter saturation voltage (VCE(sat)), specified as 2.10V (typical) at the nominal current of 1400A. This low on-state voltage is crucial for system efficiency. Think of VCE(sat) as the resistance of a valve when it’s fully open; a lower value means less pressure (voltage) is lost, and consequently, less energy is wasted as heat. This directly reduces the thermal load on the cooling system.

Furthermore, the module is specified for a maximum operating junction temperature (Tj(op)) of 150°C under switching conditions, with an absolute maximum rating of 175°C. This high thermal tolerance provides a significant design margin, allowing for robust operation in harsh industrial environments and under demanding load cycles. This enhanced thermal headroom contributes to a longer operational lifetime, a vital consideration for applications like wind turbines and large-scale solar inverters where system uptime is paramount. The module’s construction is designed to manage the mechanical stress associated with repeated temperature fluctuations.

Optimized Application Scenarios

The robust specifications of this module make it a primary choice for a range of high-power industrial and renewable energy applications:

  • Wind Turbine Inverters: The module’s high current rating and exceptional thermal cycling capability ensure reliable operation in the variable-load environment of wind-to-grid power conversion systems.
  • Megawatt-Scale Motor Drives: Its ability to efficiently control 1400A makes it suitable for heavy industrial equipment, such as mining excavators, rolling mills, and marine propulsion systems.
  • High-Power Converters: For grid-tied energy storage systems (ESS) and other large-scale power conversion tasks, this module provides a dependable switching component.
  • Uninterruptible Power Supplies (UPS): The high power density supports the development of compact and reliable UPS systems for critical infrastructure like data centers.

Its high current capacity and low VCE(sat) make it a prime candidate for megawatt-class inverters where efficiency and thermal stability are critical parameters.

Key Specifications of the 2MBI1400VXB-170E-50

All specifications are derived from the official Fuji Electric datasheet at Tj = 25°C unless otherwise noted.
Absolute Maximum Ratings
Collector-Emitter Voltage (Vces) VGE = 0V 1700V
Gate-Emitter Voltage (VGES) VCE = 0V ±20V
Continuous Collector Current (Ic) Tc = 80°C 1400A
Max. Junction Temperature (Tj(max)) 175°C
Isolation Voltage (Visol) AC, 1 minute 4000V
Electrical & Thermal Characteristics
Collector-Emitter Saturation Voltage (VCE(sat)) Ic = 1400A, VGE = 15V, Tj=150°C 2.10V (typ)
Gate-Emitter Threshold Voltage (VGE(th)) Ic = 1400mA, VCE = 20V 6.5V ± 0.5V
FWD Forward Voltage (VF) IF = 1400A, VGE = 0V, Tj=150°C 2.10V (typ)
Short-Circuit Withstand Time (tsc) Vcc=1200V, VGE=15V, Tj=150°C ≥ 10µs
Thermal Resistance (Rth(j-c)) IGBT Junction to Case 0.0134 K/W

Engineer’s FAQ

1. How does the low VCE(sat) of the 2MBI1400VXB-170E-50 affect thermal management?
The typical VCE(sat) of 2.10V at 1400A (Tj=150°C) directly reduces conduction power loss (P = VCE(sat) * Ic). Lower power loss means less heat is generated, which can allow for a smaller, more cost-effective heatsink or enable higher power output with an existing cooling solution. Further insights can be found in our guide to mastering IGBT thermal design.

2. What are the recommended mounting torque specifications?
According to the datasheet, the recommended torque for the main terminals is 18 ± 2 Nm, and for the mounting screws, it is 8 ± 1 Nm. Applying the correct torque is critical for ensuring low thermal resistance and long-term mechanical reliability. Incorrect torque can lead to poor thermal contact or mechanical stress, as detailed in our analysis of IGBT failure modes.

3. What is the specified short-circuit withstand time (tsc) for this module?
The datasheet specifies a short-circuit withstand time of at least 10 microseconds (µs) under the condition of Vcc=1200V, VGE=15V, and a junction temperature of 150°C. This level of robustness is essential for protecting the module during fault conditions in the system.

4. Can this module be used in parallel for higher current applications?
While the datasheet does not provide specific instructions for paralleling, high-current modules like the 2MBI1400VXB-170E-50 are often designed for such use. Successful paralleling requires careful attention to symmetrical busbar layout to equalize stray inductances and ensure balanced current sharing. The positive temperature coefficient of VCE(sat) inherent in IGBTs aids in this balancing. For deeper insights, explore our article on mastering high-power IGBT paralleling.

Enabling Efficient High-Power Designs

The Fuji Electric 2MBI1400VXB-170E-50 provides system designers with a high-current, high-voltage switching component that prioritizes efficiency and thermal robustness. By integrating V-Series technology, this IGBT module delivers the low conduction losses and high-temperature stability necessary to build compact, reliable, and powerful inverters and converters. This allows engineers to meet the stringent performance demands of modern renewable energy and industrial drive systems.