Conception et réalisation de fonctions thermiques intégrées dans le<br />substrat de composants électroniques de puissance. Apport de la<br />gestion des flux thermiques par des mini et micro caloducs.

Ivanova, Mariya

01 September 2005

Les modules de puissance ont tendance à devenir de plus en plus compacts et ceci engendre une<br />augmentation significative des densités de flux à évacuer. Un refroidissement plus performant est devenu<br />impératif. Les caloducs plats présentent un intérêt certain lorsque les applications visées intéressent le<br />domaine spatial où les critères de masse, d'encombrement et d'isolation électrique sont primordiaux.<br />L'objectif des travaux de thèse est de réaliser la conception et l'étude des mini et micro caloducs pour le<br />refroidissement de l'électronique embarquée. Dans un premier temps, des études théoriques et<br />expérimentales ont été conduites pour concevoir et réaliser de micro caloducs en silicium. La seconde<br />partie des travaux consiste l'étude de conception, de réalisation et de caractérisation des caloducs intégrés<br />dans un substrat DBC (Direct Bonded Copper). L'ensemble de ces travaux a montré tout l'apport des<br />mini et micro caloducs dans la gestion thermique des systèmes électroniques.

Refroidissement

mini micro caloducs

silicium

Direct Bonded Copper (DBC)

modélisation analytique

<br />thermique

réalisation

études expérimentales

Impact of Device Parametric Tolerances on Current Sharing Behavior of a SiC Half-Bridge Power Module

Watt, Grace R.

22 January 2020

This paper describes the design, fabrication, and testing of a 1.2 kV, 6.5 mΩ, half-bridge, SiC MOSFET power module to evaluate the impact of parametric device tolerances on electrical and thermal performance. Paralleling power devices increases current handling capability for the same bus voltage. However, inherent parametric differences among dies leads to unbalanced current sharing causing overstress and overheating. In this design, a symmetrical DBC layout is utilized to balance parasitic inductances in the current pathways of paralleled dies to isolate the impact of parametric tolerances. In addition, the paper investigates the benefits of flexible PCB in place of wire bonds for the gate loop interconnection to reduce and minimize the gate loop inductance. The balanced modules have dies with similar threshold voltages while the unbalanced modules have dies with unbalanced threshold voltages to force unbalanced current sharing. The modules were placed into a clamped inductive DPT and a continuous, boost converter. Rogowski coils looped under the wire bonds of the bottom switch dies to observe current behavior. Four modules performed continuously for least 10 minutes at 200 V, 37.6 A input, at 30 kHz with 50% duty cycle. The modules could not perform for multiple minutes at 250 V with 47.7 A (23 A/die). The energy loss differential for a ~17% difference in threshold voltage ranged from 4.52% (~10 µJ) to -30.9% (~30 µJ). The energy loss differential for a ~0.5% difference in V_th ranged from -2.26% (~8 µJ) to 5.66% (~10 µJ). The loss differential was dependent on whether current unbalance due to on-state resistance compensated current unbalance due to threshold voltage. While device parametric tolerances are inherent, if the higher threshold voltage devices can be paired with devices that have higher on-state resistance, the overall loss differential may perform similarly to well-matched dies. Lastly, the most consistently performing unbalanced module with 17.7% difference in V_th had 119.9 µJ more energy loss and was 22.2°C hotter during continuous testing than the most consistently performing balanced module with 0.6% difference inV_th. / Master of Science / This paper describes the design, construction, and testing of advanced power devices for use in electric vehicles. Power devices are necessary to supply electricity to different parts of the vehicle; for example, energy is stored in a battery as direct current (DC) power, but the motor requires alternating current (AC) power. Therefore, power electronics can alter the energy to be delivered as DC or AC. In order to carry more power, multiple devices can be used together just as 10 people can carry more weight than 1 person. However, because the devices are not perfect, there can be slight differences in the performance of one device to another. One device may have to carry more current than another device which could cause failure earlier than intended. In this research project, multiple power devices were placed into a package, or "module." In a control module, the devices were selected with similar properties to one another. In an experimental module, the devices were selected with properties very different from one another. It was determined that the when the devices were 17.7% difference, there was 119.9 µJ more energy loss and it was 22.2°C hotter than when the difference was only 0.6%. However, the severity of the difference was dependent on how multiple device characteristics interacted with one another. It may be possible to compensate some of the impact of device differences in one characteristic with opposing differences in another device characteristic.

SiC MOSFET

power module packaging

flexible PCB

current sharing

diode-less module

multi-chip module

device parametric tolerances

package parasitics

vertical GaN