مرکز منطقه ای اطلاع رساني علوم و فناوري - Thermal and Electrical Evaluation of SiC GTOs for Pulsed Power Applications

DocumentCode :

1136493

Title :

Thermal and Electrical Evaluation of SiC GTOs for Pulsed Power Applications

Author :

Geil, B.R. ; Bayne, S.B. ; Ibitayo, D. ; Koebke, M.G.

Author_Institution :

Army Res. Lab., Adelphi, MD, USA

Volume :

Issue :

fYear :

2005

Firstpage :

1226

Lastpage :

1234

Abstract :

For applications which require high peak current and fast rise time, silicon carbide (SiC) material is ideal because of its ability to tolerate high localized temperatures generated during switching. This research was performed to investigate SiC devices for pulse power applications and to analyze the failure of the devices. Seven 2 mm $,\\times,$ 2 mm SiC gate turn-off thyristors (GTOs) manufactured by Cree, Inc., Durham, NC, were evaluated. The devices were tested at single shot and under repetitive stress using a ring-down capacitor discharge circuit. The current pulsewidth was 2 $\\mu\\hbox {s}$ with a peak current of 1.4 kA (current density of 94.6 $kA/\\hbox {cm$^2$}$ ) and a maximum $di$ / $dt$ of 2.36 $kA/\\mu\\hbox {s}$ . The maximum power dissipated within the devices was 240 kW. Thermal modeling of these devices was done using ANSYS to analyze the heating and cooling. A two-dimensional model was used that included the device package and bonding materials. The maximum amount of power dissipated was calculated from the 1000-A, 2- $\\mu\\hbox {s}$ pulse. No further power input was added to the model and the heat transfer was plotted on an exponential scale. It was found that heat applied to a 2- $\\mu\\hbox {m}$ -thick region of the fingers yielded a temperature greater than 800 $^\\circ \\hbox {C}$ in the device. It took $1.0 E ^-02$ s for this heat to dissipate and for the device to return to 23 $^\\circ \\hbox {C}$ . The minimum and maximum stresses were found to be $-2.83 E ^+09~ Pa$ and $4.06 E ^+08~ Pa$ , respectively.

Keywords :

capacitors; cooling; heating; power semiconductor switches; pulsed power switches; silicon compounds; thermal analysis; thyristors; wide band gap semiconductors; 1.4 kA; 1000 A; 1E-2 s; 2 mm; 2 mum; 2 mus; 23 degC; 240 kW; ANSYS; GTO; SiC; cooling; electrical evaluation; gate turn-off thyristors; heat transfer; heating; pulsed power applications; repetitive stress; ring-down capacitor discharge circuit; silicon carbide; switching; thermal evaluation; Capacitors; Circuit testing; Failure analysis; Manufacturing; Performance analysis; Silicon carbide; Space vector pulse width modulation; Stress; Temperature; Thyristors; Gate turn-off thyristors (GTOs); pulse power; silicon carbide (SiC); thermal analysis; thermal modeling;

fLanguage :

English

Journal_Title :

Plasma Science, IEEE Transactions on

Publisher :

ieee

ISSN :

0093-3813

Type :

jour

DOI :

10.1109/TPS.2005.854304

Filename :

1495562

Link To Document :

https://search.ricest.ac.ir/dl/search/defaultta.aspx?DTC=49&DC=1136493