Add to ORKGThis paper focuses on the causes that lead to the final destruction in standard gate-commutated thyristor (GCT) devices. A new 3-D model approach has been used for simulating the GCT which provides a deep insight into the operation of the GCT in extreme conditions. This allows drawing some conclusions on the complex mechanisms that drive these devices to destruction, previously impossible to explain using 2-D models. © 1963-2012 IEEE
Thyristors are usually three-terminal devices that have four layers of alternating p-type and n-type...
Hybrid DC Breakers (HCBs) are crucial components in modern DC systems. Integrated Gate Commutated Th...
Hybrid DC Breakers (HCBs) are crucial components in modern DC systems. Integrated Gate Commutated Th...
In this paper we present a wafer level three-dimensional simulation model of the Gate Commutated Thy...
The destruction mechanism in large area IGCTs (Integrated Gate Commutated Thyristors) under inductiv...
In this letter, we use a novel 3-D model, earlier calibrated with experimental results on standard g...
This paper presents a physics-based compact model of integrated gate-commutated thyristor (IGCT) wit...
The model of interconnected numerical device segments can give a prediction on the dynamic performan...
This paper presents a physics-based compact model of integrated gate-commutated thyristor (IGCT) wit...
2-D electrothermal simulations of GTO-thyristor turn-off process including a complete chopper circui...
This paper describes the design of a thyristor surge protective device (TSPD) for telecommunication ...
This paper presents a practical destruction-free parameter extraction methodology for a new physics-...
The Bi-mode gate commutated thyristor (BGCT) is a new type of reverse conducting Gate Commutated Thy...
© 2015 IEEE. The Bi-mode gate commutated thyristor (BGCT) is a new type of reverse conducting Gate C...
The Bi-mode Gate Commutated Thyristor (BGCT) is a reverse conducting Gate Commutated Thyristor (GCT)...
Thyristors are usually three-terminal devices that have four layers of alternating p-type and n-type...
Hybrid DC Breakers (HCBs) are crucial components in modern DC systems. Integrated Gate Commutated Th...
Hybrid DC Breakers (HCBs) are crucial components in modern DC systems. Integrated Gate Commutated Th...
In this paper we present a wafer level three-dimensional simulation model of the Gate Commutated Thy...
The destruction mechanism in large area IGCTs (Integrated Gate Commutated Thyristors) under inductiv...
In this letter, we use a novel 3-D model, earlier calibrated with experimental results on standard g...
This paper presents a physics-based compact model of integrated gate-commutated thyristor (IGCT) wit...
The model of interconnected numerical device segments can give a prediction on the dynamic performan...
This paper presents a physics-based compact model of integrated gate-commutated thyristor (IGCT) wit...
2-D electrothermal simulations of GTO-thyristor turn-off process including a complete chopper circui...
This paper describes the design of a thyristor surge protective device (TSPD) for telecommunication ...
This paper presents a practical destruction-free parameter extraction methodology for a new physics-...
The Bi-mode gate commutated thyristor (BGCT) is a new type of reverse conducting Gate Commutated Thy...
© 2015 IEEE. The Bi-mode gate commutated thyristor (BGCT) is a new type of reverse conducting Gate C...
The Bi-mode Gate Commutated Thyristor (BGCT) is a reverse conducting Gate Commutated Thyristor (GCT)...
Thyristors are usually three-terminal devices that have four layers of alternating p-type and n-type...
Hybrid DC Breakers (HCBs) are crucial components in modern DC systems. Integrated Gate Commutated Th...
Hybrid DC Breakers (HCBs) are crucial components in modern DC systems. Integrated Gate Commutated Th...