Your search keyword '"pulse loads"' showing total 8 results

1. The deformation rate, atomic mobility and mechanical properties of metals

Author

D.S. Gertsriken, A.M. Husak, V.F. Mazanko, and S. Ye. Bogdanov

Subjects

radioactive isotopes, self- and heterodiffusion, pulse loads, strain rate, mechanical characteristic., Mining engineering. Metallurgy, TN1-997, Mineral industries. Metal trade, HD9506-9624

Abstract

The dependences of diffusion coefficients in metals with different crystal lattice (b.c.c., f.c.c., h.c.p., b.c.t.), subjected to pulse effects by different types of processing in a wide range of strain rates (10-2 - 106 s-1) without heating and at T < 0,5 Tpl. studied by m ethods based on the use of radioactive indicators 55Fe, 95Nb, 60Co, 65Zn, 63Ni, 26Al, 44Ti (layer-by-layer radiometric analysis of residual integral activity, macro- and microautoradiography). Used such types of processing as ultrasonic shock treatment, diffusion welding, shock load, magnetic pulse processing, etc. On the same materials subjected to the same types of processing, mechanical characteristics (impact strength, microhardness, tensile strength, etc.) were determined. In addition, literature data related to the determination of some mechanical characteristics in the deformation of metals at different speeds were used. It turned out that with increasing the rate of plastic deformation there is not only an increase in the mobility of atoms, but also a decrease in differences in the values of the diffusion coefficients of intrinsic atoms and other diffusers in different metals. Despite the large difference in melting temperatures, in particular zinc and niobium, their self-diffusion coefficients in the migration of atoms without heating at a rate of 106 s-1 differ only 1.5 times, while at 1 s-1 the difference in the mobility of atoms is 4 orders of magnitude. It is shown that the velocity dependences of diffusion and mechanical characteristics can be rectilinear, have extremum or inflection, but they will be approximately the same for diffusion coefficients and parameters that characterize the mechanical properties of metals under impulse loads. Establishing the type of velocity dependences for diffusion and mechanical characteristics makes it possible to determine intermediate and extrapolated values for both characteristics, as well as on the schedule of one dependence to predict the shape of the other with a certain accuracy.

Published

2021

2. Upper Bound Performance of Shipboard Power and Energy Systems for Early-Stage Design

Author

Gregory L. Sinsley, Daniel F. Opila, Eun S. Oh, and John D. Stevens

Subjects

Electric ship, energy storage, power flow, power system optimization, power management, pulse loads, Electrical engineering. Electronics. Nuclear engineering, TK1-9971

Abstract

Shipboard power systems that service large-scale dynamic loads and electric propulsion can significantly improve their performance by adding controllable energy storage. These systems require power management controls that consider dynamics like generator ramp rates, along with energy storage capacity and location. In the early-stage design process, many alternative designs are considered, and each requires a unique controller. This article describes a numerical optimization technique that establishes an upper bound performance criteria without manually designing controllers for each system. The solution is a best case performance that assumes perfect future knowledge of the time-varying load. While unrealistic in real-time, this technique yields a fair comparison between competing architectures without the variability of different control methods. To demonstrate the concept, a notional multi-bus power system architecture is evaluated on a representative set of operational duties to illustrate comparisons between system attributes like energy storage power and efficiency ratings. A design trade study shows that the success rate for a baseline ship can improve from under 60% to nearly 100% by increasing generator power by 10% and energy storage capacity by 100%. These automated architecture benchmarks fit into a broader total ship optimization process, or can be used in human-driven trade studies.

Published

2020

3. Fracture delay effect: Analogy between crack initiation due to short pulse loads and mass-spring system failure.

Author

Kazarinov, N.A., Petrov, Y.V., and Utkin, A.A

Subjects

*SYSTEM failures, *HARMONIC oscillators, *FRACTURE mechanics, *ANALOGY

Abstract

• Fracture delay effect is considered. • Crack initiation problem is studied using incubation time approach. • Linear oscillator failure due to pulse loads is investigated. • Analogies between the two problems are drawn. • Importance of threshold load cases is highlighted. The incubation time fracture criterion (ITFC) is used to analytically investigate dynamic crack initiation under short pulse loads. Particular attention is paid to the phenomenon of delayed fracture – a fundamental fracture effect which can be observed in experiments with short pulse loads. The effect can be described in the following way: the material failure occurs after local stresses reached their maximum values, meaning that the fracture takes place at a drop stage of the local stress field and thus delay is present. It is shown that the fracture delay effect manifests itself when minimal required critical loads are applied to the system. Such loads are called threshold loads being a key tool for experimental investigation of the dynamic fracture effects. It is found that the experimentally registered fracture delay can be clearly explained within the incubation time framework. The conditions for the delay are found, threshold load parameters are evaluated and the corresponding analytical formulas are given. Additionally, a simple analogy based on a mass-spring model is discussed. Analytical formulas available for the oscillator model are used to find some non-obvious similarities between the crack instability under short pulse loads and the oscillator failure when analogous loads are applied: the dynamic fracture process in the crack vicinity appears to exhibit inertial behavior. [Display omitted] [ABSTRACT FROM AUTHOR]

Published

2023

4. Upper Bound Performance of Shipboard Power and Energy Systems for Early-Stage Design

Author

Daniel F. Opila, Eun S. Oh, Gregory L. Sinsley, and John D. Stevens

Subjects

Power management, General Computer Science, energy storage, Computer science, 020209 energy, 020208 electrical & electronic engineering, General Engineering, 02 engineering and technology, pulse loads, power system optimization, Energy storage, Power (physics), Reliability engineering, Electric power system, Control theory, Control system, Electric ship, power flow, 0202 electrical engineering, electronic engineering, information engineering, General Materials Science, power management, lcsh:Electrical engineering. Electronics. Nuclear engineering, lcsh:TK1-9971

Abstract

Shipboard power systems that service large-scale dynamic loads and electric propulsion can significantly improve their performance by adding controllable energy storage. These systems require power management controls that consider dynamics like generator ramp rates, along with energy storage capacity and location. In the early-stage design process, many alternative designs are considered, and each requires a unique controller. This article describes a numerical optimization technique that establishes an upper bound performance criteria without manually designing controllers for each system. The solution is a best case performance that assumes perfect future knowledge of the time-varying load. While unrealistic in real-time, this technique yields a fair comparison between competing architectures without the variability of different control methods. To demonstrate the concept, a notional multi-bus power system architecture is evaluated on a representative set of operational duties to illustrate comparisons between system attributes like energy storage power and efficiency ratings. A design trade study shows that the success rate for a baseline ship can improve from under 60% to nearly 100% by increasing generator power by 10% and energy storage capacity by 100%. These automated architecture benchmarks fit into a broader total ship optimization process, or can be used in human-driven trade studies.

Published

2020

5. Coordination of Large Pulsed Loads on Future Electric Ships.

Author

Domaschk, Lori N., Ouroua, Abdeihamid, Hebner, Robert E., Bowlin, Oscar E., and Colson, W. B.

Subjects

*ELECTRIC vehicles, *AUTOMOBILE power trains, *SIMULATION methods & models, *FREE electron lasers, *POWER electronics

Abstract

Part of the technical versatility of future all-electric ships is the potential ability to share large amounts of power among a variety of high-power loads. To help evaluate this potential and to provide information to help guide technology selection, a physics-based model of a power train for an electric ship has been developed and implemented on three modeling platforms. Using this model, three different investigations have been carried out to explore aspects of the behavior of a rotating machine power source for a shipboard rail launcher. These were: 1) influence of rapid charging of the rotating machine system on the ship power system; 2) use of the stored energy in the rotating machines to improve ship power quality; and 3) use of the stored energy in the rotating machines to power a pulsed free-electron laser. Each study highlighted different integration opportunities and challenges. The first showed that, because the charging of the rail launchers was through 5-MW motors, there could be a voltage sag for a few cycles, but this could easily be managed so that the sag could be reduced to an inconsequential level. The second study showed that, with appropriate power electronics, the stored energy in the rail launcher power supply can be used to correct power quality problems introduced by other ship systems. Finally, the stored energy in the launcher power supply can be used to fire a free electron laser for ship defense. This feature opens the possibility of routine operation of the entire ship at highest efficiency, i.e., with the smallest number of gas turbines operating near full power, while providing stored energy needed for ship defense. [ABSTRACT FROM AUTHOR]

Published

2007

6. Battery Energy Storage Systems for Mitigating Fluctuations Caused by Pulse Loads and Propulsion Motors in Shipboard Microgrids

Author

Muhammad Umair Mutarraf, Kamran Ali Khan Niazi, Chun-Lien Su, Yacine Terriche, Juan C. Vasquez, and Josep M. Guerrero

Subjects

Battery (electricity), Fuel economy, Computer science, Pulse loads, 020208 electrical & electronic engineering, Environmental pollution, 02 engineering and technology, Propulsion, Reliability, Shipboard microgrids, Energy storage, Flywheel, Automotive engineering, law.invention, Electric power system, Capacitor, Battery energy storage system (BESS), law, Propulsion motor, 0202 electrical engineering, electronic engineering, information engineering, Fuel efficiency, Fuel cells

Abstract

In present times, the concerns over severe environmental pollution, fluctuations, and fossil-fuel consumption caused by immensely dynamic loads (pulsed loads) have captured attention in shipboard microgrids. In order to make such power system stable and reliable, presently, more generators are kept online that operate much below their efficient point. Therefore, in order to boost the fuel efficiency of shipboard microgrids, the minimum generator operation with N-1 safety can be considered as a possible solution, which is a trade off between reliability and fuel economy. For that, one of the efficient solution is to interface an energy storage system (ESS) by removing the backup generator or removing one of generator and operate rest of the generators close to their efficient point. Energy storage devices that have been frequently in use in different applications consist of batteries, flywheel, ultra-capacitor, and fuel cell. Lithium-ion among the different type of batteries is one of the most used battery in fully electric zero-emission commercial ferries that sails on shorter routes. This paper therefore presents Lithium-ion based Battery Energy Storage System (BESS) as a feasible solution to the prior mentioned concerns. At first, in order to cater with the fluctuation caused by the propulsion motor with the varying sea conditions, BESS is interfaced without the use of buck-boost converter in parallel with the DC-link capacitor. Secondly, the same BESS is interfaced with the point of common coupling (PCC) in order to cater with pulsed loads. The proposed methodology is simulated and verified using MATLAB/SIMULINK software environment.

Published

2019

7. Dynamic Buckling of Composite Shells

Author

Eglītis, E

Subjects

buckling tests, composite shells, imperfections, dynamic buckling, pulse loads

Abstract

Promocijas darbs ir veltīts kompozīto čaulu dinamiskās noturības pētījumiem. Šobrīd pielietotā projektēšanas prakse paredz pieņemt slodzes kā kvazistatiskas, ievērtējot dinamiku ar konservatīviem drošuma koeficientiem. Līdzšinējie pētījumi parāda, ka pie dažādiem īslaicīgiem dinamiskajiem slogojumiem, konstrukcijām kritiskie spēki var būt gan augstāki, gan zemāki nekā statiska slogojuma gadījumā. Tādēļ, īslaicīga slogojuma dinamiskā rakstura precīza ievērtēšana projektēšanas gaitā nākotnē ļautu samazināt konstrukciju svaru, vienlaicīgi nodrošinot nestspēju. Lai realizētu īslaicīgi dinamiski slogotu kompozīto konstrukciju svara samazināšanas potenciālu, nemazinot to drošumu, nepieciešams radīt ticamu, eksperimentāli validētu aprēķinu metodoloģiju. Promocijas darbā veiktā literatūras analīze parāda, ka šobrīd ir pieejami tikai daži kompozīto konstrukciju dinamiskās noturības eksperimentālu pētījumu rezultāti šādu eksperimentu sarežģītības dēļ. Šajā promocijas darbā eksperimentāli un skaitliski tiek pētīta kompozīto čaulu noturība pie īslaicīgiem, dinamiskiem slogojumiem, un tiek piedāvāta atbilstoša, eksperimentāli validēta modelēšanas metodika. Pirmajā nodaļā ir sniegts apskats par līdzšinējos pētījumos uzkrātajām zināšanām plānsienu konstrukciju dinamiskās noturības jomā. Svarīgākie agrīnie pētījumi ir tikuši apskatīti līdz ar jaunākajām publikācijām, kas iezīmē šī brīža zinātnes sasniegumus. Papildus dinamiskās noturības pētījumiem, ir aprakstīta arī kompozīto konstrukciju noturība pie statiska slogojuma. Otrajā nodaļā ir aprakstītas promocijas darbā izmantotās eksperimentālās un skaitliskās metodes. Eksperimentālie pētījumi ir tikuši veikti ar kompozītām cilindriskām čaulām, izmantojot hidrauliskas slogošanas iekārtas, kā arī triecientorni. Visi skaitliskie aprēķini šajā promocijas darbā veikti ar ABAQUS/Explicit galīgo elementu programmatūru. Trešajā nodaļā eksperimentāli un skaitliski pētīta izvēlēto paraugu noturību pie statiska slogojuma, lai vēlāk to salīdzinātu ar noturību pie dinamiska slogojuma. Cilindrisko čaulu jutības pret ģeometriskajām nepilnībām problēma risināta, izmērot šīs nepilnības pielietotajiem paraugiem un papildinot skaitliskos modeļus ar iegūtajiem datiem. Ceturtā nodaļa ir veltīta īslaicīgi, dinamiski slogotu cilindrisku kompozīto čaulu eksperimentāliem un skaitliskiem pētījumiem. Apskatītas vienmērīgi un pēkšņi pieliktas slodzes, kā arī pulsveida slodzes, un ir noteikta to parametru ietekme uz cilindrisko kompozīto čaulu noturību. Piektā nodaļa paplašina pētījumu, apskatot liektu, ribotu kompozīto paneļu dinamisko noturību. Iegūti rezultāti pie dažādiem slogojuma veidiem ar skaitliskiem modeļiem, kas validēti ar statiskās noturības eksperimentu rezultātiem.

Published

2011

8. Coordination of Large Pulsed Loads on Future Electric Ships

Author

O.E. Bowlin, Robert E. Hebner, Abdelhamid Ouroua, W.B. Colson, L.N. Domaschk, and Physics

Subjects

Electric motor, business.industry, Powertrain, energy storage, pulse loads, Energy storage, Automotive engineering, Electronic, Optical and Magnetic Materials, Electric power system, Shipbuilding, power system, Power electronics, Voltage sag, Electric ship, Electric power, Electrical and Electronic Engineering, business

Abstract

The article of record as published may be found at http://dx.doi.org/10.1109/TMAG.2006.887676 Part of the technical versatility of future all-electric ships is the potential ability to share large amounts of power among a variety of high-power loads. To help evaluate this potential and to provide information to help guide technology selection, a physics-based model of a power train for an electric ship has been developed and implemented on three modeling platforms. Using this model, three different investigations have been carried out to explore aspects of the behavior of a rotating machine power source for a shipboard rail launcher. These were: 1) influence of rapid charging of the rotating machine system on the ship power system; 2) use of the stored energy in the rotating machines to improve ship power quality; and 3) use of the stored energy in the rotating machines to power a pulsed free-electron laser. Each study highlighted different integration opportunities and challenges. The first showed that, because the charging of the rail launchers was through 5-MW motors, there could be a voltage sag for a few cycles, but this could easily be managed so that the sag could be reduced to an inconsequential level. The second study showed that, with appropriate power electronics, the stored energy in the rail launcher power supply can be used to correct power quality problems introduced by other ship systems. Finally, the stored energy in the launcher power supply can be used to fire a free electron laser for ship defense. This feature opens the possibility of routine operation of the entire ship at highest efficiency, i.e., with the smallest number of gas turbines operating near full power, while providing stored energy needed for ship defense. This work was supported by the Office of Naval Research.

Published

2007