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A Design Methodology for a High Power Density, Voltage Boost, Resonant DC-DC converterGafford, James Robert 06 August 2005 (has links)
A full-bridge, parallel-loaded, resonant, zero current/zero voltage switching converter has been developed for DC-DC voltage transformation. The power supply was used to condition power sourced by a 28-V, 400-A Neihoff alternator installed in a HMMWV that delivered power to a 5-kW mobile radar. This design focuses on achieving maximum power density at reasonable efficiency (i.e. > 80%) by operating at the highest resonant and switching frequencies possible. A resonant frequency of 392-kHz was achieved while providing rated power. The high resonant frequency was facilitated by the development of an extremely low inductance layout (< 20 nH) capable of conducting the high resonant currents associated with this converter topology. A design methodology is presented for parallel-loaded, resonant voltage boost converters utilizing the development of a converter prototype as a basis. The experimental results are presented as validation of the methodology.
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Investigation of Power Semiconductor Devices for High Frequency High Density Power ConvertersWang, Hongfang 03 May 2007 (has links)
The next generation of power converters not only must meet the characteristics demanded by the load, but also has to meet some specific requirements like limited space and high ambient temperature etc. This needs the power converter to achieve high power density and high temperature operation. It is usually required that the active power devices operate at higher switching frequencies to shrink the passive components volume.
The power semiconductor devices for high frequency high density power converter applications have been investigated. Firstly, the methodology is developed to evaluate the power semiconductor devices for high power density applications. The power density figure of merit (PDFOM) for power MOSFET and IGBT are derived from the junction temperature rise, power loss and package points of view. The device matrices are generated for device comparison and selection to show how to use the PDFOM. A calculation example is given to validate the PDFOM. Several semiconductor material figures of merit are also proposed. The wide bandgap materials based power devices benefits for power density are explored compared to the silicon material power devices.
Secondly, the high temperature operation characteristics of power semiconductor devices have been presented that benefit the power density. The electrical characteristics and thermal stabilities are tested and analyzed, which include the avalanche breakdown voltage, leakage current variation with junction temperature rise. To study the thermal stability of power device, the closed loop thermal system and stability criteria are developed and analyzed. From the developed thermal stability criterion, the maximum switching frequency can be derived for the converter system design. The developed thermal system analysis approach can be extended to other Si devices or wide bandgap devices. To fully and safely utilize the power devices the junction temperature prediction approach is developed and implemented in the system test, which considers the parasitic components inside the power MOSFET module when the power MOSFET module switches at hundreds of kHz. Also the thermal stability for pulse power application characteristics is studied further to predict how the high junction temperature operation affects the power density improvement.
Thirdly, to develop high frequency high power devices for high power high density converter design, the basic approaches are paralleling low current rating power MOSFETs or series low voltage rating IGBTs to achieve high frequency high power output, because power MOSFETs and low voltage IGBTs can operate at high switching frequency and have better thermal handling capability. However the current sharing issues caused by transconductance, threshold voltage and miller capacitance mismatch during conduction and switching transient states may generate higher power losses, which need to be analyzed further. A current sharing control approach from the gate side is developed. The experimental results indicate that the power MOSFETs can be paralleled with proper gate driver design and accordingly the switching losses are reduced to some extent, which is very useful for the switching loss dominated high power density converter design.
The gate driving design is also important for the power MOSFET module with parallel dice inside thus increased input capacitance. This results in the higher gate driver power loss when the traditional resistive gate driver is implemented. Therefore the advanced self-power resonant gate driver is investigated and implemented. The low gate driver loss results in the development of the self-power unit that takes the power from the power bus. The overall volume of the gate driver can be minimized thus the power density is improved.
Next, power semiconductor device series-connection operation is often used in the high power density converter to meet the high voltage output such as high power density boost converter. The static and dynamic voltage balancing between series-connected IGBTs is achieved using a hybrid approach of an active clamp circuit and an active gate control. A Scalable Power Semiconductor Switch (SPSS) based on series-IGBTs is developed with built-in power supply and a single optical control terminal. An integrated package with a common baseplate is used to achieve a better thermal characteristic. These design features allow the SPSS unit to function as a single optically controlled three-terminal switching device for users. Experimental evaluation of the prototype SPSS shows it fully achieved the design objectives. The SPSS is a useful power switch concept for building high power density, high switching frequency and high voltage functions that are beyond the capability of individual power devices.
As conclusions, in this dissertation, the above-mentioned issues and approaches to develop high density power converter from power semiconductor devices standpoint are explored, particularly with regards to high frequency high temperature operation. To realize such power switches the related current sharing, voltage balance and gate driving techniques are developed. The power density potential improvements are investigated based on the real high density power converter design. The power semiconductor devices effects on power density are investigated from the power device figure of merit, high frequency high temperature operation and device parallel operation points of view. / Ph. D.
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A modular compact kW-class IPOS DC-DC converter for pulsed power applicationsThames, Walker Joseph 10 May 2024 (has links) (PDF)
Pulsed power systems are concerned with the delivery of significant amounts of power in a greatly condensed time frame. To achieve this, energy is often stored in a capacitor, where it can be rapidly discharged. Certain applications require repeated charging and discharging of the load capacitor in a specifically modulated manner; special power electronics systems must be developed for these situations. Existing systems on the market sacrifice a small form factor for greater pulsed power output. The proposed design outlines the development of a compact pulsed power capacitor charger capable of charging a load capacitor to high voltages at a pulse repetition frequency of 30 kHz. Due to the compact form factor, the charger features a unique design of four full-bridge converters modularly connected in Input-Parallel Output-Series configuration. Experimental verification shows that the system exceeds expectations and can be utilized and adapted to fit many pulsed power applications.
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Ruggedness of High-Voltage IGBTs and Protection SolutionsBasler, Thomas 28 February 2014 (has links)
IGBTs are today’s most important power-semiconductor switches in the field of medium and high power ranges. The good controllability of this device with a voltage source is advantageous.
The following work investigates the IGBT at short-circuit and surge-current condition. A particular focus is put on the IGBT’s feedback on the gate-control circuit. Special modes during the short circuit are measured and explained. For example the self-turn-off mechanism during short circuit and the collector-emitter voltage-clamping capability during fast short-circuit turn-off. Measurements are done at high-voltage IGBT chips and press-pack devices. The complete IGBT output characteristic up to the breakdown point is measured. Additionally, the short circuit is investigated at the parallel and series connection of IGBTs. Supporting semiconductor simulations of a high-voltage IGBT model, that was specially constructed for this work, analyse the internal behaviour during the mentioned conditions. The impact of different IGBT designs on the short-circuit ruggedness and breakdown behaviour is shown. Solutions for protecting the device from destruction during overload condition are presented. Measurements and simulations explain the surge-current capability of an IGBT and demonstrate the benefit for the application. / IGBTs gehören zu den wichtigsten Halbleiter-Leistungsbauelementen im mittleren und oberen Leistungsbereich. Die einfache Ansteuerbarkeit durch eine Spannungsquelle ist dabei von großem Vorteil.
Nachfolgende Untersuchungen beschäftigen sich mit dem IGBT-Kurzschluss und -Stoßstrom. Ein besonderes Augenmerk wird auf die Rückwirkung des IGBTs auf den Ansteuerkreis gelegt. Spezielle IGBT Modi werden gemessen und erklärt. Hierzu zählen zum Beispiel der Self-Turn-Off Mechanismus während des Kurzschlusses und die selbständige Kollektor-Emitter Spannungsbegrenzung während schnellen Kurzschlussabschaltens. Hierfür werden Messungen an Hochspannungs-IGBT Chips und Press-Pack IGBTs durchgeführt. Des Weiteren wird das komplette Ausgangskennlinienfeld des IGBTs vermessen und das Kurzschlussverhalten in der Parallel- und Reihenschaltung untersucht. Halbleitersimulationen eines Hochspannungs-IGBT Modells zeigen das interne IGBT Verhalten und unterstützen die Analyse der Messungen. Der Einfluss unterschiedlicher IGBT Designs in Bezug auf die Kurzschluss-Robustheit und das Durchbruchverhalten wird aufgezeigt. Möglichkeiten zum Schutz des IGBTs vor Zerstörung werden erörtert. Messungen und Simulationen zeigen die gute Stoßstromfestigkeit von IGBTs bei erhöhter Gatespannung auf. Davon kann die komplette Anwendung profitieren.
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