Your search keyword '"Benjamin Leyrer"' showing total 11 results

1. GaAs Diode Rectifier Power Module in mixed Ag- and Large Area Cu-Sintering Technology for Ultra-Fast and Wireless Electric Vehicle Battery Charging

Author

Thomas Blank, Dai Ishikawa, Helge Wurst, Bao Ngoc An, Benjamin Leyrer, Marc Weber, Volker Dudek, and Matthias Luh

Subjects

010302 applied physics, Materials science, business.industry, Thermal resistance, 05 social sciences, chemistry.chemical_element, Substrate (electronics), 01 natural sciences, Copper, Rectifier, chemistry, Power module, 0103 physical sciences, MOSFET, Optoelectronics, 0501 psychology and cognitive sciences, business, Layer (electronics), 050104 developmental & child psychology, Diode

Abstract

This paper describes the properties of GaAs PIN power diodes and demonstrates their utilization in a 650V 10kW LLC converter for fast charging of electric vehicles. The module comprises two SiC MOSFET half-bridges equipped with Rohm S4101 MOSFETs and the GaAs rectifier module packaged in an EconoPACK2 housing. The SiC half-brides and the GaAs rectifier are assembled on 0.38 mm thick zirconia-toughened alumina (ZTA) substrate with a bending strength of 700 MPa and a thermal conductivity of 27 W/mK. The SiC and GaAs semiconductors are silver-sintered onto a 0.3 mm measuring copper thick film layer on the top and bottom side of the substrate. The substrate is pressure sintered by a novel low temperature copper paste to the three mm thick copper base plate. The bow of the base plate with copper sintered substrates measures 200 μm and is comparable to the bow of soldered substrates. The thermal resistance of the GaAs module is calculated to 0.73 K/W. First electrical measurement at an output power of 0.5 kW reveal the extremely fast switching characteristic of the diode, which were validated by double pulse measurements.

Published

2019

2. Radiation hard active pixel sensor with 25μm × 50μm pixel size designed for capacitive readout with RD53 ASIC

Author

U. Bauer, Michele Caselle, Benjamin Leyrer, P. Pfistner, Ivan Peric, and H. Zhang

Subjects

Physics, Nuclear and High Energy Physics, CMOS sensor, Comparator, Pixel, 010308 nuclear & particles physics, business.industry, Chip, 01 natural sciences, Particle detector, 030218 nuclear medicine & medical imaging, 03 medical and health sciences, 0302 clinical medicine, CMOS, Application-specific integrated circuit, 0103 physical sciences, Electrode, Hardware_INTEGRATEDCIRCUITS, Optoelectronics, business, Instrumentation

Abstract

A new concept for a capacitively coupled particle detector (CCPD) is described. Sensor and readout chips are attached using a small number of large bumps. A sensor chip for such a CCPD has been designed and tested. The sensor chip is based on the HVCMOS structure. Deep n-well is used as the charge collecting electrode . To allow strong amplification, which is necessary for chip to chip signal transmission , a novel CMOS based comparator with rail to rail output swing has been implemented in each pixel. The pixel outputs are connected to transmitting electrodes implemented in the top metal layer of the sensor chip. Using special address encoding a group of 16 pixels is connected to 8 transmitting electrodes. The pixel size is 25 μ m × 50 μ m and the transmitting electrode pitch is 50 μ m × 50 μ m . Therefore a standard HL-LHC readout chip developed by RD53 collaboration can be used for readout of the sensor.

Published

2020

3. High density flex-cable and interconnection technologies for large silicon detector modules

Author

Benjamin Leyrer, C. Simons, Thomas Blank, C. J. Schmidt, P. Pfistner, Marc Weber, and Michele Caselle

Subjects

Interconnection, Materials science, Silicon, business.industry, 020208 electrical & electronic engineering, chemistry.chemical_element, 020206 networking & telecommunications, Tracking system, 02 engineering and technology, Signal, Core (optical fiber), chemistry, Soldering, 0202 electrical engineering, electronic engineering, information engineering, Optoelectronics, SMT placement equipment, FLEX, business

Abstract

The Compressed Baryonic Matter Experiment (CBM) investigates highly compressed nuclear matter, utilizing a Silicon Tracking System comprising 896 silicon sensors modules packed in eight layers with an overall area of four sqm. Each module consists of one sensor, 16 Read-Out Chips and 16 double-layer micro flex-cables, which are connected to the top and bottom side of the sensor. The cables are up to 50 cm long. They carry 128 signal traces on two layers at a pitch of 100 μm and a line-width of 25 μm. The layers are separated by a meshed core to reduce the cable capacity to 0.44 pF/cm. The cables are bonded onto one sensor by a pick and place flip-chip machine. The interconnection is realized by gold stud-bumps on the silicon and SAC solder bumps on the cable. The status of the sensor module and cable production process are presented.

Published

2018

4. A highly integrated copper sintered SiC power module for fast switching operation

Author

Dai Ishikawa, Benjamin Leyrer, Johannes Kolb, Thomas Blank, Horst Demattio, Torsten Scherer, Ansgar Simon, Marc Weber, Helge Wurst, and Bao Ngoc An

Subjects

Materials science, business.industry, Thermal resistance, 020208 electrical & electronic engineering, 05 social sciences, 02 engineering and technology, law.invention, Capacitor, law, Power module, 0202 electrical engineering, electronic engineering, information engineering, Shear strength, Gate driver, Optoelectronics, 0501 psychology and cognitive sciences, Power semiconductor device, Commutation, business, 050107 human factors, Electronic circuit

Abstract

A novel 1200 V and 110 A SiC pin-fin direct cooled six-pack power module with integrated DC-link capacitor and gate driver circuits is presented. The SiC power devices are sintered on a DCB-thick-film combined substrate using a novel copper sinter paste. The copper sintered connection has a shear strength of 73.2 MPa which is comparable to the shear strength of Ag-sintering. The module has a thermal resistance between chip and coolant of 1.4 K/W. By integrating the DC-link capacitor into the module, the parasitic stray inductance of the commutation loop can be reduced by 3x times to the value of 7.2 nH. The parasitic inductances in the high side and low side gate loop have a value of 3.4 nH.

Published

2018

5. Evaluation of Ag-sinter pastes for the die attachment in power electronic modules using design of experiments

Author

Maurizio Kempf, Johannes Kolb, Marc Weber, Bao Ngoc An, Benjamin Leyrer, and Thomas Blank

Subjects

010302 applied physics, Materials science, business.product_category, business.industry, Design of experiments, Sintering, 02 engineering and technology, Structural engineering, 021001 nanoscience & nanotechnology, 01 natural sciences, Temperature measurement, Power (physics), Shear (sheet metal), Soldering, 0103 physical sciences, Shear strength, Die (manufacturing), Composite material, 0210 nano-technology, business

Abstract

Silver sintering is a potential die attach technology to replace the solder technology for power electronic systems. A design of experiments (DoE) is performed in order to investigate the influences of sinter parameters as sinter pressure, temperature, duration, drying temperature and the interactions of these parameters on the shear strength of the Ag-sinter connection. Four sinter pastes have been evaluated. All significant parameters and parameter interactions are identified in order to derive a quadratic model function used to fit the measured shear values. This fitted function predicts the shear strength as a function of the significant parameters and, moreover, the function is used to determine the optimal sinter parameter space. The shear tests reveal that for three tested sinter pastes an excellent average shear result exceeding 90 MPa is achieved. One sinter paste outperforms these results by an average shear strength of 121 MPa. The DoE shows that all sinter pastes are significantly dependent on the sinter pressure and sinter temperature. However one sinter paste is influenced by the drying temperature and a second sinter paste is independent of the drying temperature as well as the sinter duration.

Published

2016

6. Highly integrated power modules based on copper thick-film-on-DCB for high frequency operation of SiC semiconductors—Design and manufacture

Author

Thomas Blank, Martin Bernd, Michael Meisser, Max Schmenger, Philip Mawby, Dean P. Hamilton, and Benjamin Leyrer

Subjects

Materials science, business.industry, Electrical engineering, Dielectric, Substrate (printing), law.invention, Inductance, Capacitor, law, Power module, visual_art, Logic gate, visual_art.visual_art_medium, Optoelectronics, Inverter, Ceramic, business

Abstract

The Publisher's final version can be found by following the DOI link. This paper encompasses the design and the manufacture of a full-SiC module based on copper thick-film. Both DC-link capacitors as well as gate drives are implemented onto the substrate in order to minimise parasitic inductances. Thus, the module is especially suitable for high-frequency operation such as inductive energy transfer and inverter systems for renewable energies and electrical vehicles. In order to maintain high mechanical strength of the module's substrate, a Direct Copper Bond (DCB) provides the basis for multiple thick-film layers. The used thick-film dielectric insulates the gate-drive islands and also works as solder-stop material. The heat-spreading capabilities of DCB substrates are investigated by simulations.

Published

2015

7. Blue and white light emitting high power density LED modules

Author

Bernhard Osswald, Jurgen B. Brandner, Benjamin Leyrer, Yi-Chung Huang, Jin-Kai Chang, Wood-Hi Cheng, Christian Herbold, Kirsten Eilert, Franziska Herrmann, and Marc Schneider

Subjects

Materials science, business.industry, Doping, chemistry.chemical_element, Optical power, Phosphor, High power density, Nitride, Optics, chemistry, Water cooler, Aluminium, White light, Optoelectronics, business

Abstract

We present optical measurements of an optimized LED module consisting of 98 blue light emitting LED chips silver-sintered onto an aluminum nitride ceramic substrate within an area of 211 mm2. The module is cooled by a high performance microstructured water cooler. Using this cooler a maximum optical power density of 111.6 W/cm2 at a forward current of 3003 mA and 1255.6 W electrical input power could be achieved. Placing sintered glass discs doped with yellow phosphor in different concentrations in front of the module, white light with correlated color temperatures between 3600 K and 4200 K was produced.

Published

2015

8. High power density LED modules with silver sintering die attach on aluminum nitride substrates

Author

Stefan Maikowske, Benjamin Leyrer, Christian Herbold, and Marc Schneider

Subjects

Materials science, business.industry, Metallurgy, Sintering, chemistry.chemical_element, Optical power, Substrate (electronics), Nitride, Die (integrated circuit), law.invention, chemistry, Aluminium, law, Soldering, Optoelectronics, business, Light-emitting diode

Abstract

Current research studies deal with the investigation of the thermal and optical properties of four LED modules on different substrate materials. The LED modules consist of arrays of 98 blue emitting LEDs with an emission wavelength of 457 nm within an area of 2.11 cm 2 . The modules are based on aluminum oxide or aluminum nitride substrates and the LED chips are attached by using a soldering or a pressureless silver sintering process. The modules are mounted on a high performance microstructured heat exchanger. By using the water driven cooler a maximum optical power density of 106.2 W/cm 2 at a forward current of 2100 mA and 837.5 W electrical input power is achieved. A saturation of the optical power density over the input current due to thermal degradation is not observed.

Published

2014

9. Index matched fluidic packaging of high power UV LED clusters on aluminum substrates for improved optical output power

Author

Christian Herbold, Benjamin Leyrer, Stefan Maikowske, Marc Schneider, and Jürgen Brandner

Subjects

Materials science, business.industry, Electronic packaging, chemistry.chemical_element, Heat sink, Temperature measurement, law.invention, chemistry, Water cooler, Aluminium, law, Optoelectronics, Fluidics, business, Power density, Light-emitting diode

Abstract

We present an improved cooling for a high power density UV LED module for a wavelength of 395 nm. The module consists of 98 LED chips soldered on a thick film printed alumina substrate on an area of 2.11 cm2. We investigated cooling by a commercial water cooler as well as by a surface micro cooler developed by our own. Further we describe a technology to replace alumina by aluminum as substrate material. A module consisting of 25 UV LEDs was optically characterized without and with liquid encapsulation. Finally we conducted numerical studies to develop an easily producible, sufficiently powerful, and robust water cooler. Based on the results we present a water cooler design with cooling channels embedded in the aluminum substrate of an LED module, removing the interface between LED substrate and heat sink.

Published

2012

10. Thermal improvements for high power UV LED clusters

Author

Christian Herbold, Klaus Trampert, Jürgen Brandner, Benjamin Leyrer, and Marc Schneider

Subjects

Materials science, business.industry, Thermal grease, Substrate (electronics), Heat sink, Thermal management of high-power LEDs, Barrier layer, Thermal conductivity, visual_art, visual_art.visual_art_medium, Optoelectronics, Ceramic, business, Power density

Abstract

We present a high power density UV LED module for a wavelength of 395 nm with an optical power density of 27.3 W/cm2. The module consists of 98 densely packed LED chips soldered onto an Al 2 O 3 ceramic board. Thermal and optical measurements were conducted. The module was cooled by a forced air heat sink for the characterization experiments. A room temperature liquid gallium alloy was used as thermal interface material between substrate and heat sink with a TiN barrier layer to prevent corrosion. Further a technology to replace Al 2 O 3 ceramics by aluminum as substrate is presented. An initial characterization shows that aluminum with a dielectric layer for electrical insulation is a competitive substrate material for efficient heat removal.

Published

2011

11. Packaging of high power UV-LED modules on ceramic and aluminum substrates

Author

Benjamin Leyrer, Marc Schneider, Stefan Maikowske, and Christian Herbold

Subjects

Materials science, business.industry, Thermal resistance, Thermal grease, Heat sink, Thermal management of high-power LEDs, Thermal conductivity, visual_art, Automotive Engineering, visual_art.visual_art_medium, Electronic engineering, Water cooling, Optoelectronics, Ceramic, Forced-air, business

Abstract

An LED module consisting of 98 UV-LEDs with an emission wavelength of 395 nm placed on a ceramic substrate of 211 mm2 is presented. The module is cooled by a forced air heat sink as well as a high performance microstructured water cooler to lower the thermal resistance. For high thermal conductance a liquid metal as the thermal interface material between substrate and heat sink is used. With the forced air heat sink a maximum irradiance of 27.3 W/cm2 at a forward current of 700 mA and 220 W electrical input power was achieved. The microstructured water cooler enabled an almost doubling of the electrical input power (430 W) while maintaining the chip's maximum temperature. For a reduction of the module's thermal resistance a thick film process for aluminum sheet metal substrates was developed. A prototype LED module with 25 UV-LED chips on an area of 54 mm2 achieved a maximum optical power density of 31.6 W/cm2 at a forward current of 900 mA using a forced air heat sink. For an improved cooling of the LED chips a chip-on-heat sink-technology with embedded water cooling channels is developed to eliminate the thermal interface between substrate and heat sink.