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Gap Analysis towards A Design Qualification Standard Development for Grid-Connected Photovoltaic InvertersJanuary 2011 (has links)
abstract: The high penetration of photovoltaic (PV) both at the utility and at the distribu-tion levels, has raised concerns about the reliability of grid-tied inverters of PV power systems. Inverters are generally considered as the weak link in PV power systems. The lack of a dedicated qualification/reliability standard for PV inverters is a main barrier in realizing higher level of confidence in reliability. Development of a well-accepted design qualification standard specifically for PV inverters will help pave the way for significant improvement in reliability and performance of inverters across the entire industry. The existing standards for PV inverters such as UL 1741 and IEC 62109-1 primarily focus on safety. IEC 62093 discusses inverter qualification but it includes all the balance of sys-tem components and therefore not specific to PV inverters. There are other general stan-dards for distributed generators including the IEEE1547 series of standards which cover major concerns like utility integration but they are not dedicated to PV inverters and are not written from a design qualification point of view. In this thesis, some of the potential requirements for a design qualification standard for PV inverters are addressed. The IEC 62093 is considered as a guideline and the possible inclusions in the framework for a dedicated design qualification standard of PV inverter are discussed. The missing links in existing PV inverter related standards are identified by performing gap analysis. Dif-ferent requirements of small residential inverters compared to large utility-scale systems, and the emerging requirements on grid support features are also considered. Electric stress test is found to be the key missing link and one of the electric stress tests, the surge withstand test is studied in detail. The use of the existing standards for surge withstand test of residential scale PV inverters is investigated and a method to suitably adopt these standards is proposed. The proposed method is studied analytically and verified using simulation. A design criterion for choosing the switch ratings of the inverter that can per-form reliably under the surge environment is derived. / Dissertation/Thesis / M.S. Electrical Engineering 2011
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High Power Density, High Efficiency Single Phase Transformer-less Photovoltaic String InvertersJanuary 2017 (has links)
abstract: Two major challenges in the transformer-less, single-phase PV string inverters are common mode leakage currents and double-line-frequency power decoupling. In the proposed doubly-grounded inverter topology with innovative active-power-decoupling approach, both of these issues are simultaneously addressed. The topology allows the PV negative terminal to be directly connected to the neutral, thereby eliminating the common-mode ground-currents. The decoupling capacitance requirement is minimized by a dynamically-variable dc-link with large voltage swing, allowing an all-film-capacitor implementation. Furthermore, the use of wide-bandgap devices enables the converter operation at higher switching frequency, resulting in smaller magnetic components. The operating principles, design and optimization, and control methods are explained in detail, and compared with other transformer-less, active-decoupling topologies. A 3 kVA, 100 kHz single-phase hardware prototype at 400 V dc nominal input and 240 V ac output has been developed using SiC MOSFETs with only 45 μF/1100 V dc-link capacitance. The proposed doubly-grounded topology is then extended for split-phase PV inverter application which results in significant reduction in both the peak and RMS values of the boost stage inductor current and allows for easy design of zero voltage transition. A topological enhancement involving T-type dc-ac stage is also developed which takes advantage of the three-level switching states with reduced voltage stress on the main switches, lower switching loss and almost halved inductor current ripple.
In addition, this thesis also proposed two new schemes to improve the efficiency of conventional H-bridge inverter topology. The first scheme is to add an auxiliary zero-voltage-transition (ZVT) circuit to realize zero-voltage-switching (ZVS) for all the main switches and inherent zero-current-switching (ZCS) for the auxiliary switches. The advantages include the provision to implement zero state modulation schemes to decrease the inductor current THD, naturally adaptive auxiliary inductor current and elimination of need for large balancing capacitors. The second proposed scheme improves the system efficiency while still meeting a given THD requirement by implementing variable instantaneous switching frequency within a line frequency cycle. This scheme aims at minimizing the combined switching loss and inductor core loss by including different characteristics of the losses relative to the instantaneous switching frequency in the optimization process. / Dissertation/Thesis / Doctoral Dissertation Electrical Engineering 2017
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Couplage onduleurs photovoltaïques et réseau, aspects contrôle / commande et rejet de perturbations / Grid connected PV systems, control / command aspects and disturbances decouplingLe, Thi Minh Chau 25 January 2012 (has links)
Cette thèse concerne le couplage des systèmes photovoltaïques (PV) au réseau de distribution du point de vue contrôle/commande et rejet de perturbation. Le raccordement au réseau induit des couplages aux effets parfois indésirables. Le problème majeur est dû aux creux de tension provoqué par des court-circuits, à la foudre ou encore à certaines manœuvres. Dans ce contexte, des déconnexions apparaissent et parfois sont non-jutifiées, tout particulièrement en cas de défaut sur un départ adjacent BT/HTA; en cas d'un fort taux de pénétration de systèmes PV, une telle déconnexion qui serait généralisée peut avoir des conséquences néfastes. Les travaux de cette thèse se sont focalisés sur ce problème de couplage : effet des systèmes PV sur le réseau et réaction des systèmes PV face aux perturbations du réseau. A cet effet, des adaptations aux protections découplage sont proposées pour une intégration harmonieuse du système PV. Des stratégies de gestion de l'énergie ont été également mises au point participation à l'amélioration de la qualité de l'énergie localement et pour la tenue des systèmes PV aux perturbations. / This thesis concerns the coupling of photovoltaic (PV) to the distribution network in terms of control/command and disturbance decoupling. The connection of PV system to the grid induces the coupling some unwanted effects. The major problem is due to voltage sags caused by short circuits, lightning or some operations. In this context, disconnections occur and sometimes are unjustifies, especially in case of fault on LV/MV adjacent feeder and in case of a high penetration of PV systems, a such disconnection can provoke adverse consequences. The work of this thesis focused on the problem of coupling: effect of PV systems on the network and reaction of PV system facing network disturbance. For this purpose, adaptations to the decoupling protections are proposed for harmonious integration of PV. Strategies for energy management were also developed participation in improving the quality of local energy and for the holding of PV systems to disturbances.
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High Efficiency Single-stage Grid-tied PV Inverter for Renewable Energy SystemZhao, Zheng 21 May 2012 (has links)
A single-phase grid connected transformerless photovoltaic (PV) inverter for residential application is presented. The inverter is derived from a boost cascaded with buck converter along with a line frequency unfolding circuit. Due to its novel operating modes, high efficiency can be achieved because there is only one switch operating at high frequency at a time, and the converter allows the use of power MOSFET and ultra-fast reverse recovery diode. This dissertation begins with theoretical analysis and modeling of this boost-buck converter based inverter. And the model indicates small boost inductance will leads to increase the resonant pole frequency and decrease the peak of Q, which help the system be controlled easier and more stable. Thus, interleaved multiple phases structure is proposed to have small equivalent inductance, meanwhile the ripple can be decreased, and the inductor size can be reduced as well. A two-phase interleaved inverter is then designed accordingly.
The double-carrier modulation method is proposed based on the inverter's operation mode. The duty cycle for buck switch is always one if the inverter is running in boost mode. And the duty cycle for boost switches are always zero if the inverter is running in buck mode. Because of this, the carrier for boost mode is stacked on the top of the carrier for buck mode, as a result, there is no need to compare the input and output voltage to decide which mode the inverter should operate in. And the inverter operates smoothly between these two modes. Based on similar concept, three advanced modulation methods are proposed. One of them can help further improve the efficiency, and one of them can help increase the bandwidth and gain, and the last one takes the advantage of both.
Based on similar concept, another three dual-mode double-carrier based SPWM inverters are proposed. With both step-up and step-down functions, this type of inverter can achieve high efficiency in a wide range because only one switch operates at the PWM frequency at a time.
Finally, the simulation and experiment results are shown to verify the concept and the tested CEC (California Energy Commission) efficiency is 97.4%. It performs up to 2% more efficiently better than the conventional solution. / Ph. D.
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Kiselkarbidtransistorer i växelriktare för solcellerShafai, Adam, Zhao, Wei January 2014 (has links)
Since the first commercial silicon carbide (SiC) transistor was released, the interest in SiC has grown exponentially [1]. The wide energy band gap, high critical electric field and thermal conductivity of silicon carbide allow it to withstand higher voltage/current gains than conventional semiconductor materials [2]. The electrical properties of SiC enable integrated devices and circuits to operate at higher voltages and temperatures. One of the most attractive applications for SiC is in inverters for photovoltaic systems, where switching time is of great importance. This thesis presents the study of two bipolar junction transistors (BJT), FSICBH15A120 of SiC and BUV48A of conventional silicon (Si). The transistors were simulated and validated experimentally, then tested in a DC/AC pv inverter with a polycrystalline solar module of 36 solar cells as power source. The simulation results showed high efficiency and low power losses. / Sedan den första kommersiella transistorn av kiselkarbid (SiC) släpptes har intresset för SiC ökat exponentiellt [1]. Det breda energibandgapet, höga kritisk elektriska fältstyrkan och termiska ledningsförmågan i SiC gör att den klarar en högre kombination av spänning/strömförstärkning än konventionella halvledarmaterial [2]. De elektriska egenskaperna av SiC gör det möjligt för integrerade komponenter och kretsar att arbeta i högre spänningar och temperaturer. Ett av de största användningsområdena för SiC är i växelriktare för solceller, där switch-tid har stor betydelse. I detta examensarbete presenteras studien av två bipolära transistorer (BJT), FSICBH15A120 av SiC och BUV48A av konventionellt kisel (Si). Transistorerna simulerades och valideras experimentellt, och slutligen jämfördes med varandra i en DC/AC-omvandlare med en polykristallin solpanel av 36 solceller som strömkälla. Hög verkningsgrad och låga energiförluster påvisades.
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High-efficiency Transformerless PV Inverter CircuitsChen, Baifeng 01 October 2015 (has links)
With worldwide growing demand for electric energy, there has been a great interest in exploring photovoltaic (PV) sources. For the PV generation system, the power converter is the most essential part for the efficiency and function performance. In recent years, there have been quite a few new transformerless PV inverters topologies, which eliminate the traditional line frequency transformers to achieve lower cost and higher efficiency, and maintain lower leakage current as well.
With an overview of the state-of-the-art transformerless PV inverters, a new inverter technology is summarized in the Chapter 2, which is named V-NPC inverter technology. Based this V-NPC technology, a family of high efficiency transformerless inverters are proposed and detailly analyzed. The experimental results demonstrate the validity of V-NPC technology and high performance of the transformerless inverters.
For the lower power level transformerless inverters, most of the innovative topologies try to use super junction metal oxide semiconductor field effect transistor(MOSFET) to boost efficiency, but these MOSFET based inverter topologies suffer from one or more of these drawbacks: MOSFET failure risk from body diode reverse recovery, increased conduction losses due to more devices, or low magnetics utilization. By splitting the conventional MOSFET based phase leg with an optimized inductor, Chapter 3 proposes a novel MOSFET based phase leg configuration to minimize these drawbacks. Based on the proposed phase leg configuration, a high efficiency single-phase MOSFET transformerless inverter is presented for the PV micro-inverter applications. The PWM modulation and circuit operation principle are then described. The common mode and differential mode voltage model is then presented and analyzed for circuit design. Experimental results of a 250 W hardware prototype are shown to demonstrate the merits of the proposed MOSFET based phase-le and the proposed transformerless inverter.
New codes require PV inverters to provide system regulation and service to improve the distribution system stabilization. One obvious impact on PV inverters is that they now need to have reactive power generation capability. The Chapter 4 improves the MOFET based transformerless inverter in the Chapter 3 and proposed a novel pulse width modulation (PWM) method for reactive power generation. The ground loop voltage of this inverter under the proposed PWM method is also derived with common mode and differential mode circuit analyses, which indicate that high-frequency voltage component can be minimized with symmetrical design of inductors. A 250-W inverter hardware prototype has been designed and fabricated. Steady state and transient operating conditions are tested to demonstrate the validity of improved inverter and proposed PWM method for reactive power generation, high efficiency of the inverter circuit, and the high-frequency-free ground loop voltage.
Besides the high efficiency inverter circuit, the grid connection function is also the essential part of the PV system. The Chapter 5 present the overall function blocks for a grid-connected PV inverter system. The current control and voltage control loop is then analyzed, modeled, and designed. The dynamic reactive power generation is also realized in the control system. The new PLL method for the grid frequency/voltage disturbance is also realized and demonstrate the validity of the detection and protection capability for the voltage/frequency disturbance.
At last, a brief conclusion is given in the Chapter 6 about each work. After that, future works on device packaging, system integration, innovation on inverter circuit, and standard compliance are discussed. / Ph. D.
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Performance evaluation and improvement of grid-connected technologyRaji, Atanda Kamoru January 2012 (has links)
Dissertation (DTech(Electrical Engineering))--Cape Peninsula University of Technology, 2012 / The confluence of the limited resources of fossil fuels (e.g. coal, oil and natural gas), environmental degradations leading to climate change, security of supplies and fossil fuels high costs have demanded a tremendous efforts on humanity to seek for a sustainable and unlimited natural energy sources. Amongst these renewable energy sources stands out solar energy because of its ubiquitousness. Solar energy is converted to DC electricity by the photovoltaic effect. Photovoltaic (PV) power systems installed in commercial and industrial buildings are a good example of distributed power generation. Here the energy consumption and production match and thus electricity taken from the grid during daytime peak hours can be reduced. This is beneficial as the transmission losses in the grid are avoided and also transmission need is reduced. The cost effectiveness of a solar energy system has hindered its wide adoption and deployment in terms of the initial capital cost even though it has a zero energy cost and very minimal operating and maintenance costs. Different governments have instituted many financial incentives for fast adoption of PV systems for both residential and commercial applications. However, all these incentives are not sustainable in the longer term forecast. For PV system to attain grid parity requires more than unsustainable approach of many governments providing time limited subsidies. The technical solution to the problem is to reduce the overall system cost through technical innovations. One such method is the adoption of transformerless inverter technology as the grid interface system. Transformerless inverter topology provides galvanic isolation through innovative inverter topology and switching strategies that eliminates problems created by not employing the service of transformer.
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