Thematische Bibliographien / Artillery shell

Inhaltsverzeichnis

  1. Zeitschriftenartikel
  2. Dissertationen
  3. Bücher
  4. Buchteile
  5. Konferenzberichte
  6. Berichte der Organisationen

Auswahl der wissenschaftlichen Literatur zum Thema „Artillery shell“

Autor: Grafiati
Veröffentlicht am 28. Juni 2021
Zuletzt aktualisiert am 8. Februar 2022

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Zeitschriftenartikel zum Thema "Artillery shell"

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Didenko, Ye, und O. Stepanenko. „APPLICATION OF THE METHOD SPRINGY DEFORMATIONS OF BARREL DURING SHOT FOR DETERMINING THE INITIAL VELOCITY OF THE SHELL (MINE)“. Collection of scientific works of Odesa Military Academy 1, Nr. 12 (27.12.2019): 75–80. http://dx.doi.org/10.37129/2313-7509.2019.12.1.75-80.

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One of the indicators of the effective use of artillery is the accuracy of the fire impact on the objects of enemy. The accuracy of the artillery is achieved by completing the implementation of all measures for the preparation of shooting and fire control. Main measures of ballistic preparation are to determine and take into account the summary deviation of the initial velocity. The existing procedure for determining the summary deviation of the initial velocity for the check (main) cannon of battery leads to accumulation of ballistic preparation errors. The supply of artillery units with means of determining the initial speed of the projectile is insufficient. Among the many known methods for measuring the initial velocity, not enough attention was paid to the methods of analyzing the processes that occur during a shot in the "charge-shell-barrel" system. Under the action of the pressure of the powder gases in the barrel channel and the forces of the interaction of the projectile with the barrel there are springy deformations in the radial direction. To measure springy deformations it is advisable to use strain gauge sensors. Monitoring of deformation in a radial direction by time can be used to determine the moment of passing a projectile past the strain gauge mounted on the outer surface of the barrel. In the case of springy deformations, the initial resistance of the sensor varies in proportion to its value. The speed of the shell (mine) in the barrel can be determined by time between pulses of signals obtained from strain gauges located at a known distance from each other. The simplicity of the proposed method for measuring the initial velocity of an artillery shell provides an opportunity for equipping each cannon (mortar) with autonomous means for measuring the initial velocity. With the simultaneous puting into action of automatic control systems can be automatically taking into account the measurement results. This will change the existing procedure for determining the total deviation of the initial velocity and improve the accuracy, timeliness and suddenness of the opening of artillery fire, which are components of its efficiency.
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Ghosh, A. K., S. C. Raisinghani und S. K. Dehury. „Modeling of Performance of an Artillery Shell Using Neural Networks“. Journal of Spacecraft and Rockets 39, Nr. 3 (Mai 2002): 470–72. http://dx.doi.org/10.2514/2.3832.

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3

Ruhl, Charles M., Sung Jin Park, Olumide Danisa, Raymond F. Morgan, Bruno Papirmsister, Frederick R. Sidell, Richard F. Edlich, Lee S. Anthony und Harvey N. Himel. „A serious skin sulfur mustard burn from an artillery shell“. Journal of Emergency Medicine 12, Nr. 2 (März 1994): 159–66. http://dx.doi.org/10.1016/0736-4679(94)90693-9.

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4

Otter, Jenna, Alveena Dawood und Joseph D'Orazio. „Sulfur Mustard Exposure from Dredged Artillery Shell in a Commercial Clammer“. Clinical Practice and Cases in Emergency Medicine 1, Nr. 4 (16.11.2017): 283–86. http://dx.doi.org/10.5811/cpcem.2017.5.34034.

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Krysinski, Bogdan, und Piotr Zych. „FACTORS INITIATING THE ACTIVATION OF FIRING CHAIN IN ARTILLERY FUSES“. PROBLEMY TECHNIKI UZBROJENIA 149, Nr. 1 (28.08.2019): 115–27. http://dx.doi.org/10.5604/01.3001.0013.4055.

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Basic function of an artillery fuse is to ef-fectively initiate the activation of the main charge, located in the projectile shell, at a place and time decided by a gunner. The fuse also has a key role for ensuring the safe use of ammunition. Efficient initiation of the first part of so called firing train decides on proper functioning of the fuse. This element generates an impulse stimulating the activation of subsequent components of the train (chain). In the article, the authors will focus on factors initiating the correct activation of first components of the fire train in artillery fuses. These factors, with some pros and cons, will be discussed on examples of fuses which are used up to now.
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Konosevich, Boris I., und Yuliya B. Konosevich. „Comparison of two modified point-mass trajectory models of an artillery shell“. Vestnik of Saint Petersburg University. Mathematics. Mechanics. Astronomy 6(64), Nr. 3 (2019): 463–81. http://dx.doi.org/10.21638/11701/spbu01.2019.311.

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Kang, Shinjae, Chul Park, Woosuk Jung, Taesoo Kwon, Juhyeon Park und Sejin Kwon. „Design of Gun Launched Ramjet Propelled Artillery Shell with Inviscid Flow Assumption“. Journal of the Korean Society of Propulsion Engineers 19, Nr. 4 (01.08.2015): 52–60. http://dx.doi.org/10.6108/kspe.2015.19.4.052.

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Naeem, I., J. Masood und N. Buchholz. „Percutaneous Nephrolithotomy for Removal of a Calcified Intra-Renal Artillery Shell Fragment“. Journal of the Royal Army Medical Corps 155, Nr. 1 (01.03.2009): 30–31. http://dx.doi.org/10.1136/jramc-155-01-09.

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9

Ivanova, Galina. „Innertial Forces with an Impact on the Parts of an Artillery Shell When Fired“. International conference KNOWLEDGE-BASED ORGANIZATION 24, Nr. 3 (01.06.2018): 124–29. http://dx.doi.org/10.1515/kbo-2018-0147.

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Abstract The present work studies the inertial forces arising during the movement of an artillery projectile when it is fired. It describes the effect of these forces on the details of an independent power source that is part of a defence product. In the course of the study, chemical sources of electricity of a new type have been constructed. They are used to study the effect of their mass on the performance of the final product
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Нolovan, V., V. Gerasimov, А. Нolovan und N. Maslich. „REAL CONDITION AND PROSPECTS OF DEVELOPMENT OF THE RADAR STATIONS OF THE COUNTER BATTERY FIGHTINGV“. Collection of scientific works of Odesa Military Academy 1, Nr. 12 (27.12.2019): 30–40. http://dx.doi.org/10.37129/2313-7509.2019.12.1.30-40.

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Fighting in the Donbas, which has been going on for more than five years, shows that a skillful counter-battery fight is an important factor in achieving success in wars of this kind. Especially in conditions where for the known reasons the use of combat aviation is minimized. With the development of technical warfare, the task of servicing the counter-battery fight began to rely on radar stations (radar) to reconnaissance the positions of artillery, which in modern terms are called counter-battery radar. The principle of counter-battery radar is based on the detection of a target (artillery shell, mortar mine or rocket) in flight at an earlier stage and making several measurements of the coordinates of the current position of the ammunition. According to these data, the trajectory of the projectile's flight is calculated and, on the basis of its prolongation and extrapolation of measurements, the probable coordinates of the artillery, as well as the places of ammunition falling, are determined. In addition, the technical capabilities of radars of this class allow you to recognize the types and caliber of artillery systems, as well as to adjust the fire of your artillery. The main advantages of these radars are:  mobility (transportability);  inspection of large tracts of terrain over long distances;  the ability to obtain target's data in near real-time;  independence from time of day and weather conditions;  relatively high fighting efficiency. The purpose of the article is to determine the leading role and place of the counter-battery radar among other artillery instrumental reconnaissance tools, to compare the combat capabilities of modern counter-battery radars, armed with Ukrainian troops and some leading countries (USA, China, Russia), and are being developed and tested in Ukraine. The method of achieving this goal is a comparative analysis of the features of construction and combat capabilities of modern models of counter-battery radar in Ukraine and in other countries. As a result of the conducted analysis, the directions of further improvement of the radar armament, increasing the capabilities of existing and promising counter-battery radar samples were determined.
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Dissertationen zum Thema "Artillery shell"

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Fiot, Aurélien. „Attitude estimation of an artillery shell in free-flight from accelerometers and magnetometers“. Thesis, Université Paris sciences et lettres, 2020. http://www.theses.fr/2020UPSLM039.

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Cette thèse présente une méthode pour estimer l'attitude d'un projectile en vol à partir de mesures de directions. L'estimation d'attitude est une étape essentielle pour le développement de "munitions intelligentes", rendant possible le changement de cible en vol et l'optimisation de la portée. La méthode que nous proposons repose exclusivement sur un accéléromètre et un magnétomètre embarqués. En particulier, elle ne requiert pas de gyroscope, capteur coûteux et trop fragile pour survivre aux conditions de tir, quand il n'est pas soumis à des restrictions d'importation. Pour la détermination de l'attitude du projectile, nous contournons l'incapacité des accéléromètres à donner une mesure de direction de la gravité en vol ballistique, en les utilisant pour estimer la vitesse du projectile par rapport à l'air. Ceci est réalisé grâce à une méthode de détection de fréquence appliquée aux oscillations de précession et de nutation du projectile induites par les moments aérodynamiques qu'il subit. Par la suite, les variations de la vitesse du projectile nous donnent une information d'orientation partielle qui complète la direction donné par le magnétomètre 3-axes. Les deux informations sont traitées par un observateur d'attitude adapté du filtre complémentaire ; cette adaptation n'est pas triviale et on réalise une étude détaillée de la convergence de l'observateur proposé. L'efficacité de la méthode est illustrée par des résultats sur des données de simulation et des données de vol réel
The thesis addresses the estimation of the attitude of an artillery shell in free flight, during the flight phase called exterior ballistics. Attitude estimation is an essential step for the development of "smart-shells" a.k.a. "guided-ammunition" which are capable of achieving various guidance tasks such as in-flight re-targeting and optimization of range. The method developed here uses strapdown accelerometers and magnetometers only. In particular, it does not use any rate gyro, a pricey component that is too fragile to survive the stress of gunshot when it is not subjected to import restrictions. For attitude determination, we circumvent the intrinsic inability of accelerometers to provide direction information in free flight, by employing them not to measure the direction of gravity but to estimate the velocity wrt the air. This is achieved through a frequency detection method applied to the pitching and yawing rotational dynamics generated by aerodynamics moments. In turn, the variation of the velocity gives us an orientation information that complements the direction given by the 3-axis Magnetometer. The two information are treated by an attitude observer adapted from the well-known complementary filter. This adaptation requires special care and an analysis of the convergence of the resulting observer is provided. The applicability of the method is shown on simulations and real-flight experiments
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Smith, Matthew W. (Matthew Wayne) 1973. „In-flight estimation of environmental and aerodynamic modeling errors for a GPS-INS guided artillery shell in a GPS-jamming environment“. Thesis, Massachusetts Institute of Technology, 1998. http://hdl.handle.net/1721.1/50389.

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Moravec, Zdeněk. „Výroba těla granátu“. Master's thesis, Vysoké učení technické v Brně. Fakulta strojního inženýrství, 2021. http://www.nusl.cz/ntk/nusl-445161.

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The diploma thesis deals with the technology of production of the body of an artillery shell caliber 155 mm from C60 steel. The part is manufactured in series of 100,000 pieces. Based on a literature study and materials, a technological procedure of drop forging was designed, taking into account the specific shape of the forging. The volume of the starting blank and the forming force were determined. A suitable forming machine was selected based on the magnitude of the forming force. The design of tools for punching operations and reduction diameters of sets of rollers for forging stretching was also performed. In the technical and economic evaluation, the material costs for the production of the entire series were quantified.
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Vikström, Peter. „Den militära nyttan av kurskorrigerande tändrör“. Thesis, Försvarshögskolan, 2011. http://urn.kb.se/resolve?urn=urn:nbn:se:fhs:diva-1979.

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Sveriges ökade engagemang i internationella konflikter har förändrat under vilkaformer och i vilka miljöer som dagens militära operationer genomförs. Framföralltinnebär det att alla insatsförband inom Försvarsmakten ska kunna verka inom allakonfliktnivåer och i de flesta miljöer, även i urban terräng. Som en följd av dettauppkommer nya behov och krav på den indirekta bekämpningsförmågan i form avprecisionsbekämpning. Syftet med föreliggande arbete är att kartlägga om, och till vilken grad, ettkurskorrigerande tändrör bidrar till att öka den taktiska effektiviteten förstådd somverkanseffektivitet, kostnadseffektivitet, logistisk effektivitet samt minskad oönskadsidoverkan. Kartläggningen sker genom en komparativ litteraturstudie medkompletterande expertintervjuer. Med hjälp av kurskorrigerande tändrör som medger nära precisionsbekämpning kanen rad vinster erhållas. Exempel på sådana vinster är minskad spridning samt ökaddimensionering av verkan, minskad risk för oönskad sidoverkan, en lägre totalkostnad för ammunition samt minskat behov av transporter genom ökad effekt av detenskilda skottet.
Sweden’s increased international commitment has altered the forms andenvironments of today's battlefield and military operations for units within theSwedish Armed Forces. First and foremost it means that all units have to be able tohandle all levels of conflict in most types of environments, including urban terrain.As a consequence of this, new needs and requirements arise concerning indirect fireand Artillery precision strike capabilities. The purpose of this thesis is to investigate if and to what extent a course correctingfuse contributes to an increased tactical efficiency within the areas of effect, cost,logistics and reduced risk of collateral damage. The investigation is made through acomparative literature study with supplementary expert interviews.With the help of a course correcting fuse, which allows for close precision capability,a series of achievements can be acquired. Examples of such achievements are reduced dispersion and increased capability ofdimensioning of effects, reduced risk of collateral damage, lower total cost ofmunitions and reduced demand of logistics.
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Wang, Chun-Hao, und 王鈞豪. „Development of a Classification Recognition System for Exterior Features of the Artillery shells“. Thesis, 2013. http://ndltd.ncl.edu.tw/handle/12921059802420554080.

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碩士
國防大學理工學院
機械工程碩士班
101
Nowadays, the military ammunition identification work is still artificial manner. Therefore, this study attempted to establish recognition system through image processing technology combined with neural network to improve the recognition results of ammunition types. The results of recognition affects mainly by artillery shell features, shape and color characteristics identify the most effect. First, to extract the shape feature of ammunition images, modal analysis and some image intervals developed method are applied and the connected component is used to implement shape reconstruction. And to avoid identification being affected by the position, size and rotation angle, it is necessary for shape reconstruction graphics to be normalized. Finally, the geometric invariant moments of the normalized graphics are as the shape features. For color feature extraction, after constructiing back-propagation neural network color classifier by color samples, each pixel color of the artillery shell graphics is classified and the area ratio of each color is calculated. Shape features and area ratio of each color are used to construct two kinds of shells neural network recognition system, its network parameters are adjusted through the constructive algorithm to get the best recognition system. Considering the recognition results would be affected by environmental disturbances, i.e. camera angles, shooting distance and kinds of light, in this case, a large number of samples are generated by three degrees of these factors. Orthogonal array is used to diminish training samples and the results demonstrate that training time is reduced effectively at each iteration and keep excellent recognition capability. On the other hand, although the changes of light and color cause the incomplete developing shape, its geometric invariant moments can be still effectively identified. By contrast, the color characteristics except are affected by the incomplete shape, color distortion is more severe disruption. Hence, shape recognition system has better identification effect and the appropriate input values bring up a desired recognition system.
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Bücher zum Thema "Artillery shell"

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Tamid totḥan: Sipuro shel ḥayil loḥem. [Israel]: Avivim, 1994.

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Buchteile zum Thema "Artillery shell"

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Burton, M. G., und D. A. Allen. „Artillery Shells in Orion“. In Infrared Astronomy with Arrays, 61–64. Dordrecht: Springer Netherlands, 1994. http://dx.doi.org/10.1007/978-94-011-1070-9_13.

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Gerard, Philip. „Glory Bound“. In The Last Battleground, 29–33. University of North Carolina Press, 2019. http://dx.doi.org/10.5149/northcarolina/9781469649566.003.0006.

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Capt. William Henry Asbury Speer marches off to war from his beloved Yadkin River Valley a reluctant soldier who blames the Secessionists for the war. He is captured in battle, then exchanged, and rejoins the 28th regiment. Even as he fights bravely at Fredericksburg and is wounded at Chancellorsville, he campaigns hardest to keep his younger brother out of the war. He survives Pickett’s Charge at Gettysburg and ten more major engagements, rising to command the regiment. He pens a dark poem predicting his on death and near Petersburg is blasted by shrapnel from an artillery shell. Friends cart his body home in a wagon for burial among his Ulster Scots and Quaker ancestors.
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Hoddeson, Lillian, und Peter Garrett. „Smarter Machines (1944–1952)“. In The Man Who Saw Tomorrow, 45–64. The MIT Press, 2018. http://dx.doi.org/10.7551/mitpress/9780262037532.003.0004.

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This chapter traces Ovshinsky’s transition from machinist to inventor. It deals mainly with his first important invention, an innovative automatic lathe. After returning to Akron, he started his own company, Stanford Roberts, where he built the prototype of his Benjamin center drive lathe, followed by more advanced models. The lathe’s superior performance led to expansion of the company, but financial difficulties eventually led Ovshinsky to sell Stanford Roberts to the New Britain Machine Tool Company, where his lathe was spectacularly successful in machining artillery shell cases for use in the Korean War. Intent on further automating his lathe, he studied cybernetics and applied its principles of using sensors and feedback to the automation of other devices, like a self-guided tractor.
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„Artillery Shells in the Bay“. In Death of the Chesapeake, 29–37. Hoboken, NJ, USA: John Wiley & Sons, Inc., 2013. http://dx.doi.org/10.1002/9781118756584.ch4.

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Toal, Gerard. „Territorial Integrity“. In Near Abroad. Oxford University Press, 2017. http://dx.doi.org/10.1093/oso/9780190253301.003.0010.

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On the Evening of August 7, 2008, Inal Pliyev was working late at his office in the center of Tskhinval(i). A former journalist, Pliyev was head of communications for the self-declared South Ossetian Republic. Earlier in the evening, Georgian president Mikheil Saakashvili had declared a unilateral ceasefire after days of skirmishes between Georgian forces and South Ossetian militias. Pliyev, however, was still in the office because of information about increasing Georgian artillery and armor concentrations near the town. “First we heard what sounded like grenade launchers—after the years of conflict everyone here knows what sound is made by which weapon. I did not pay much attention to that.” But when he heard the first sounds of Grad missiles, Pliyev turned off his computer and ran for his life. “All parts of the city came under fire simultaneously. It was so intense, that you couldn’t even register a fraction of time between explosions, there were multiple explosions every second. The fire was non-stop. Electricity and gas supplies were cut off during the first minute of the shelling, and for the most part phone service was also cut off.” One shell fell next to the government building where Pliyev and his colleagues huddled. “The building shook so much that part of the ceiling bent down, and we ran into an underground bunker in a nearby non-government building. Explosions were becoming louder and even more frequent. We could not leave our hideout, and everyone was getting ready to die. Even more we feared being taken prisoner by Georgian soldiers. It was especially terrifying when we heard machine gun fire. Our only thought was to avoid being taken prisoner at any cost. Our only hope was for the Russian air force, we were waiting for it to come, so that Georgians would leave our city. But it wasn’t coming.” Pliyev had his mobile phone, and as its battery ran out he spoke to various Russian media outlets pleading for Russian military help.
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Grasso, Christopher. „I Am Kelso“. In Teacher, Preacher, Soldier, Spy, 167–89. Oxford University Press, 2021. http://dx.doi.org/10.1093/oso/9780197547328.003.0010.

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In January 1863, a large Confederate force swept up from Arkansas. Kelso and his men discovered the advance and were chased back to the fort at Beaver Station and then to the one at Ozark, both of which the Confederates destroyed as they marched north to their target, Springfield. The Battle of Springfield pitted about 2,300 Federals defending the town, including local men and boys in the militia and patients in the army hospital, against a like-sized Confederate force commanded by General John S. Marmaduke. The men fought all day with artillery shells flying overhead. Kelso went spying at night, creeping among the wounded and the dead. Unable to take the town, the Confederates withdrew the next morning. In the aftermath, Kelso’s conflict with his drunken commanding officer lead to court martial proceedings, but Kelso was acquitted.
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Konferenzberichte zum Thema "Artillery shell"

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Dupuis, Alain, und Claude Berner. „Wind Tunnel Tests of a Long Range Artillery Shell Concept“. In AIAA Atmospheric Flight Mechanics Conference and Exhibit. Reston, Virigina: American Institute of Aeronautics and Astronautics, 2002. http://dx.doi.org/10.2514/6.2002-4416.

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Ghosh, Ajoy, Ankur Singhal und Ayush Jha. „Flight Path Prediction of an Artillery Shell Using Feed Forward Neural Networks“. In AIAA Atmospheric Flight Mechanics Conference and Exhibit. Reston, Virigina: American Institute of Aeronautics and Astronautics, 2005. http://dx.doi.org/10.2514/6.2005-5820.

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Panda, Tapas Ranjan, und Arkadeb Banerjee. „Numerical Simulation of the In-bore Motion of a Typical Artillery Shell“. In 2019 International Conference on Range Technology (ICORT). IEEE, 2019. http://dx.doi.org/10.1109/icort46471.2019.9069663.

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Banerjee, Arkadeb, Nityananda Nayak, Dakshyaraj Giri und Karunakar Bandha. „Effect of Gun Barrel Wear on Muzzle Velocity of a typical Artillery Shell“. In 2019 International Conference on Range Technology (ICORT). IEEE, 2019. http://dx.doi.org/10.1109/icort46471.2019.9069641.

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Lutz, Y., und F. Christnacher. „Laser diode illuminator for night vision on-board a 155-mm artillery shell“. In AeroSense 2003, herausgegeben von William E. Thompson und Paul H. Merritt. SPIE, 2003. http://dx.doi.org/10.1117/12.513110.

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BORGSTROM, DAN, und LARS PAULSSON. „Aerodynamics of a rotating body descending from the separation position of an artillery munition shell“. In 11th Aerodynamic Decelerator Systems Technology Conference. Reston, Virigina: American Institute of Aeronautics and Astronautics, 1991. http://dx.doi.org/10.2514/6.1991-870.

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Junqi Gu, Mingquan Shi und Shuqian Fan. „An impact point of shipboard artillery shell calculating system based on DSP and matlab-simulink simulation“. In 2010 International Conference on Computer Design and Applications (ICCDA 2010). IEEE, 2010. http://dx.doi.org/10.1109/iccda.2010.5541364.

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Porshnev, S. V. „Investigation of artillery shell motion features at the initial stage of a shot using radar methods“. In 2000 10th International Crimean Microwave Conference. Microwave and Telecommunication Technology. Conference Proceedings. IEEE, 2000. http://dx.doi.org/10.1109/crmico.2000.1256210.

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PANDA, TAPAS RANJAN, und ARKADEB BANERJEE. „Numerical Simulation of the In-Bore Motion of a Typical Artillery Shell and Investigation of Balloting“. In 31st International Symposium on Ballistics. Lancaster, PA: DEStech Publications, Inc., 2019. http://dx.doi.org/10.12783/ballistics2019/33152.

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Hollis, Michael S. L., und Fred J. Brandon. „Design and Analysis of a Fuze-Configurable Trajectory Correction Device for an Artillery Projectile“. In ASME 2000 International Design Engineering Technical Conferences and Computers and Information in Engineering Conference. American Society of Mechanical Engineers, 2000. http://dx.doi.org/10.1115/detc2000/rsafp-14467.

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Abstract With the advances in microelectronics, sensor technology, and packaging design, the reality of an artillery projectile, range correction device is conceivable. A previous report entitled “Preliminary Design of a Range Correction Module for an Artillery Shell” (Hollis 1996) demonstrated a possible concept called the D-ring range correction device. One of the main objectives of the range correction device concept was to contain all the mechanical and electrical components within a fuze-like envelope, while maintaining certain constraints that would allow the fuze to fit into a variety of artillery shells used by North Atlantic Treaty Organization (NATO) countries. Another objective of the range correction device concept was to avoid any changes within the ogive of any of the projectiles in the existing stockpile. Range correction is achieved by a mechanism that symmetrically deploys four D-shaped blades, or drag blades, with the sole purpose of increasing drag. Estimates have been made of the percent change in drag as related to increases in frontal area. The deployed D-rings, with a spread of 80 mm, will increase the frontal area by 1.63 times. If the D-rings are extended a centimeter farther to a deployment diameter of 100 mm, the increase in frontal area is 2.39 times. An initial study by Brandon and Jara has indicated that reasonable maneuver authorities can be achieved for frontal areas of 7.3 in2 (47.1 cm2) and 10.7 in2 (69.0 cm2), which corresponds, respectively, to the 80-mm and 100-mm deployment diameters. This report is a culmination of many design iterations, numerical analyses, shock tests, and actual cannon launchings. Most of the design iterations and numerical analyses are not mentioned in this report simply because they were stepping stones that led to the final design. Structural analyses indicate that the overall prototype design is durable enough to withstand the most severe artillery cannon launching available today. The design should be capable of withstanding 15,000 g’s of inertial set-back loads with 150,000 rad/s2 of angular acceleration. In addition, the design is also capable of deploying at a velocity of 650 m/s, while spinning at 250 cycles per second. The next step would be to fabricate the design in order to truly verify the integrity of the structure and to determine the overall effect of the deployed drag blades on the range of flight.
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Berichte der Organisationen zum Thema "Artillery shell"

1

Erkman, J. O., und M. Lutzky. Computer Modeling of a Booster in An Artillery Shell. Fort Belvoir, VA: Defense Technical Information Center, Dezember 1986. http://dx.doi.org/10.21236/ada194758.

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2

Roberts, Neal P. Measurements of Range, Deflection, and Height of Burst for Fired Artillery Shell, Method II - A Least-Squares Methodology. Fort Belvoir, VA: Defense Technical Information Center, Februar 1991. http://dx.doi.org/10.21236/ada232521.

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3

Roberts, Neal P. Measurements of Range Deflection, Time of Flight, and Height of Burst for Fired Artillery Shell Method 1. Triangulation. Fort Belvoir, VA: Defense Technical Information Center, September 1990. http://dx.doi.org/10.21236/ada227169.

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