Realization of a 10 kW MES power to methane plant based on unified AC/DC converter

This paper presents a galvanic isolated multi output AC/DC topology that is suitable for Microbial electrosynthesis (MES) based Power to Methane energy storage systems. The presented scheme utilizes a three phase back to back converters, a single-input and multiple-output three phase transformer, single diode rectifiers and buck converters that employ a proper interconnection between MES cells and the mains. The proposed topology merges all the required single phase AC/DC converters as a unified converter which reduces the overall system size and provides system integrity and overall controllability. The proposed control scheme allows to achieve the following desired goals:1) Simultaneous control of all cells; 2) Absorbing power from the grid and covert to methane when the electricity price goes down; 3) the power factor and the quality of grid current is under control; 4) Supplying MES cells at the optimal operating point. For verification of system performance, Real time simulation results that are obtained from a 10-kW MES energy storage are presented.Postprint (author's final draft

Multi-megawatt inverter/converter technology for space power applications

Large power conditioning mass reductions will be required to enable megawatt power systems envisioned by the Strategic Defense Initiative, the Air Force, and NASA. Phase 1 of a proposed two phase interagency program has been completed to develop an 0.1 kg/kW DC/DC converter technology base for these future space applications. Three contractors, Hughes, General Electric (GE), and Maxwell were Phase 1 contractors in a competitive program to develop a megawatt lightweight DC/DC converter. Researchers at NASA Lewis Research Center and the University of Wisconsin also investigated technology in topology and control. All three contractors, as well as the University of Wisconsin, concluded at the end of the Phase 1 study, which included some critical laboratory work, that 0.1-kg/kW megawatt DC/DC converters can be built. This is an order of magnitude lower specific weight than is presently available. A brief description of each of the concepts used to meet the ambitious goals of this program are presented

Pushing the Boundary of the 48 V Data Center Power Conversion in the AI and IoT Era

openThe increasing interest in cloud-based services, the Internet-of-Things and the take-over of artificial intelligence computing require constant improvement of the power distribution network. Electricity consumption of data centers, which drains a consistent slice of modern world energy production, is projected to increase tremendously during the next decade. Data centers are the backbone of modern economy; as a consequence, energy-aware resource allocation heuristics are constantly researched, leading the major IT services providers to develop new power conversion architectures to increase the overall webfarm distribution efficiency, together reducing the resulting carbon footprint and maximizing their investments. As higher voltage distribution yields lower conduction losses, vendors are moving from the 12 V rack bus to 48 V solutions together with research centers and especially data center developers. As mentioned, efficiency is crucial to address in this scenario and the whole conversion chain, i.e. from the 48 V bus to the CPU/GPU/ASIC voltage, must be optimized to decrease wasted energy inside the server rack. Power density for this converters family is also paramount to consider, as the overall system must occupy as less area and volume as possible. LLC resonant converters are commonly used as IBCs (intermediate bus converters), together with their GaN implementations because of their multiple advantages in efficiency and size, while multiphase-buck-derived topologies are the most common solution to step-down-to and regulate the final processor voltage as they're well-know, easy to scale and design. This dissertation proposes a family of non-isolated, innovative converters capable of increasing the power density and the efficiency of the state-of-the-art 48 V to 1.8/0.9 V conversion. In this work three solutions are proposed, which can be combined or used as stand-alone converters: an ASIC on-chip switched-capacitor resonant voltage divider, two unregulated Google-STC-derived topologies for the IBC stage (48 V to 12 V and 48 V to 4.8 V + 10.6 V dual-output) and a complete 48 V to 1.8 V ultra-dense PoL converter. Each block has been thoroughly tested and researched, therefore mathematical and experimental results are provided for each solution, together with state-of-the-art comparisons and contextualization.The increasing interest in cloud-based services, the Internet-of-Things and the take-over of artificial intelligence computing require constant improvement of the power distribution network. Electricity consumption of data centers, which drains a consistent slice of modern world energy production, is projected to increase tremendously during the next decade. Data centers are the backbone of modern economy; as a consequence, energy-aware resource allocation heuristics are constantly researched, leading the major IT services providers to develop new power conversion architectures to increase the overall webfarm distribution efficiency, together reducing the resulting carbon footprint and maximizing their investments. As higher voltage distribution yields lower conduction losses, vendors are moving from the 12 V rack bus to 48 V solutions together with research centers and especially data center developers. As mentioned, efficiency is crucial to address in this scenario and the whole conversion chain, i.e. from the 48 V bus to the CPU/GPU/ASIC voltage, must be optimized to decrease wasted energy inside the server rack. Power density for this converters family is also paramount to consider, as the overall system must occupy as less area and volume as possible. LLC resonant converters are commonly used as IBCs (intermediate bus converters), together with their GaN implementations because of their multiple advantages in efficiency and size, while multiphase-buck-derived topologies are the most common solution to step-down-to and regulate the final processor voltage as they're well-know, easy to scale and design. This dissertation proposes a family of non-isolated, innovative converters capable of increasing the power density and the efficiency of the state-of-the-art 48 V to 1.8/0.9 V conversion. In this work three solutions are proposed, which can be combined or used as stand-alone converters: an ASIC on-chip switched-capacitor resonant voltage divider, two unregulated Google-STC-derived topologies for the IBC stage (48 V to 12 V and 48 V to 4.8 V + 10.6 V dual-output) and a complete 48 V to 1.8 V ultra-dense PoL converter. Each block has been thoroughly tested and researched, therefore mathematical and experimental results are provided for each solution, together with state-of-the-art comparisons and contextualization.Dottorato di ricerca in Ingegneria industriale e dell'informazioneopenUrsino, Mari

Analysis and Design of a Hybrid Dickson Switched Capacitor Converter for Intermediate Bus Converter Applications

By 2020 it is predicted that 1/3 of all data will pass through the cloud. With society\u27s growing dependency on data, it is vital that data centers, the cloud\u27s physical house of content, operate with optimal energy performance to reduce operating costs.Unfortunately, today\u27s data centers are inefficient, both economically and environmentally. This has led to an increase in demand for energy-efficient servers. One opportunity for improved efficiency is in the power delivery architecture which delivers power from the grid to the motherboard. In this dissertation, the main focus is the intermediate bus converter (IBC), used for the intermediate conversion, typically 48-12V/5V, in server power supplies. The IBC requires compact design so that it can be placed as close to the load as possible to enable more space for computing power and high efficiency to reduce the need for external cooling. Most commonly used converter topologies today include expensive bulky magnetics hindering the converter\u27s power density. Furthermore, high output current of an IBC makes the efficiency very sensitive to any resistance, such as magnetic parasitic resistance or PCB trace resistance. In this work, analytical loss models are used to review the advantages and disadvantages of frequently used IBC topologies such as the phase-shifted full bridge and LLC. The Hybrid Dickson Switched Capacitor (HDSC) topology is also analyzed. The HDSC\u27s high step-down conversion ratio and low dependence on magnetics due to the reduced applied volt-seconds, provides a new opportunity for applications such as the intermediate bus converter. The HDSC designs the on-time of devices in order to achieve soft-charging between flying capacitors. Other advantages of the HDSC include low switch stress, small magnetics and adjustable duty cycle for voltage regulation. Challenges, such as minimizing parasitic inductance and resistance between flying capacitors, are addressed and recommendations for PCB layout are provided. In this paper, a 4:1 24-5V and 8:1 48-5V, 100W GaN-based HDSC is designed and tested. The influences of capacitor mismatch and limitations placed on soft-charging operation for the HDSC is also modeled. This analysis can be used as a tool for designers when selecting flying capacitors

Design Space Evaluation for Resonant and Hard-charged Switched Capacitor Converters

USB Power Delivery enables a fixed ratio converter to operate over a wider range of output voltages by varying the input voltage. Of the DC/DC step-down converters powered from this type of USB, the hard-charged Switched Capacitor circuit is of interest to industry for its potential high power density. However implementation can be limited by circuit efficiency. In fully resonant mode, the efficiency can be improved while also enabling current regulation. This expands the possible applications into battery chargers and eliminates the need for a two-stage converter.In this work, the trade-off in power loss and area between the hard-charged and fully resonant switched capacitor circuit is explored using a technique that remains agnostic to inductor technology. The loss model for each converter is presented as well as discussion on the restrained design space due to parasitics in the passive components. The results are validated experimentally using GaN-based prototype converters and the respective design spaces are analyzed

Design Techniques of Highly Integrated Hybrid-Switched-Capacitor-Resonant Power Converters for LED Lighting Applications

The Light-emitting diodes (LEDs) are rapidly emerging as the dominant light source given their high luminous efficacy, long lift span, and thanks to the newly enacted efficiency standards in favor of the more environmentally-friendly LED technology. The LED lighting market is expected to reach USD 105.66 billion by 2025. As such, the lighting industry requires LED drivers, which essentially are power converters, with high efficiency, wide input/output range, low cost, small form factor, and great performance in power factor, and luminance flicker. These requirements raise new challenges beyond the traditional power converter topologies. On the other hand, the development and improvement of new device technologies such as printed thin-film capacitors and integrated high voltage/power devices opens up many new opportunities for mitigating such challenges using innovative circuit design techniques and solutions. Almost all electric products needs certain power delivery, regulation or conversion circuits to meet the optimized operation conditions. Designing a high performance power converter is a real challenge given the market’s increasing requirements on energy efficiency, size, cost, form factor, EMI performance, human health impact, and so on. The design of a LED driver system covers from high voltage AC/DC and DC/DC power converters, to high frequency low voltage digital controllers, to power factor correction (PFC) and EMI filtering techniques, and to safety solutions such as galvanic isolation. In this thesis, we study design challenges and present corresponding solutions to realize highly integrated and high performance LED drivers combining switched-capacitor and resonant converters, applying re-configurable multi-level circuit topology, utilizing sigma delta modulation, and exploring capacitive galvanic isolation. A hybrid switched-capacitor-resonant (HSCR) LED driver based on a stackable switched-capacitor (SC) converter IC rated for 15 to 20 W applications. Bulky transformers have been replaced with a SC ladder to perform high-efficiency voltage step-down conversion; an L-C resonant output network provides almost lossless current regulation and demonstrates the potential of capacitive galvanic isolation. The integrated SC modules can be stacked in the voltage domain to handle a large range of input voltage ranges that largely exceed the voltage limitation of the medium-voltage-rated 120 V silicon technology. The LED driver demonstrates > 91% efficiency over a rectified input DC voltage range from 160 VDC to 180 VDC with two stacked ICs; using a stack of four ICs > 89.6% efficiency is demonstrated over an input range from 320 VDC to 360 VDC . The LED driver can dim its output power to around 10% of the rated power while maintaining >70% efficiency with a PWM controlled clock gating circuit. Next, the design of AC main rectifier and inverter front end with sigma delta modulation is described. The proposed circuits features a pair of sigma delta controlled multilevel converters. The first is a multilevel rectifier responsible for PFC and dimming. The second is a bidirectional multilevel inverter used to cancel AC power ripple from the DC bus. The system also contains an output stage that powers the LEDs with DC and provides for galvanic isolation. Its functional performance indicates that integrated multilevel converters are a viable topology for lighting and other similar applications

Assessment of DC/DC converters for use in DC nodes for offshore grids

With increasing offshore wind generation, there is a strong argument for implementing a multi-terminal DC grid offshore by the interconnection of individual HVDC links. The point of intersection of three or more lines can be used to interconnect projects with different voltage levels and to control power distribution. It is being proposed that these points, or nodes, be implemented using DC devices. A highvoltage, high-power DC/DC converter will therefore be an important component of a DC node. This paper reviews possible DC/DC converter topologies, looking at device requirement, different voltage conversion ratio and fault management. The suitability of the converters considered, for use in a node in a HVDC offshore grid, is discussed. A resonant DC/DC converter topology is considered in detail and is modelled at a conversion ratio of two, and demonstrates high power efficiency

Switched capacitor converters:a new approach for high power applications

High-power, high-voltage and high voltage-conversion ratio DC-DC converters are an enabling technology for offshore DC grids of the future. These converters are required to interface between offshore wind farms and an offshore DC grid and a key design issue is the size and weight of the converter, which significantly impacts the cost of the associated off-shore platform. In addition to this application, some rural communities, particularly in Canada, Australia and South Africa,which are located far away from the electrical power generators, can take the advantages of this technology by tapping into existing HVDC transmission line using a high voltage-conversion ratio DC-DC converter. The work described in this thesis is an investigation as to how such DC-DC converters may be realised for these applications. First a review of existing DC-DC converters was carried out to assess their suitability for the target applications. A classification of DC-DC converters into Direct and Indirect converters was proposed in this work based on the manner in which the energy is transferred from the input to the output terminal of the converter. Direct DC-DC converters, particularly Switched Capacitor(SC) converters are more promising for high-voltage, high-power and high voltage-conversion ratio applications, since the converter can interface between the low-voltage and the high-voltage terminals using low-voltage and low-power power electronic modules. Existing SC topologies were examined to identify the most promising candidate circuits for the target applications. Four SC synthesis techniques were proposed in order to derive new SC circuits from existing topologies. A new 2-Leg Ladder, modular 2-Leg Ladder and bi-pole 2-Leg Ladder were devised, which had significant benefits in terms of size and weight when compared with existing circuits. A scaled power 1 kW converter was built in the laboratory in order to validate the analysis and compare the performance of the new 2-Leg ladder circuit against a conventional Ladder circuit, where it was shown that the new circuit had higher efficiency, smaller size and lower output voltage ripple than the Ladder converter

Overview of the DC power conversion and distribution

Author name used in this publication: K. W. E. ChengPower Electronics Research Center, Department of Electrical EngineeringVersion of RecordPublishe