Your search keyword '"Zbigniew Surma"' showing total 49 results

1. Selected Aspects of Heat Transfer Study in a Gun Barrel of an Anti-Aircraft Cannon

Author

Mateusz ZIELIŃSKI, Piotr KONIORCZYK, Zbigniew SURMA, Marek PREISKORN, and Judyta SIENKIEWICZ

Subjects

mechanical engineering, anti-aircraft cannon barrel, heat transfer, numerical simulation, temperature field, Electronics, TK7800-8360, Chemical engineering, TP155-156

Abstract

The paper presents the results of computer simulations of the transient heat flow in the barrel wall of a 35 mm caliber cannon for a single shot and a sequence of seven shots for a selected 30HN2MFA barrel steel. It was assumed that the inner surface of the barrel does not have a protective layer of chromium or nitride. When calculating heat transfer in a barrel, constant and temperature variable values of thermal conductivity, specific heat and density (in the range from RT (Room Temperature) up to 1000) in the 30HN2MFA steel were assumed. The test results were compared for both cases. A barrel with a total length of 3150 mm was divided into 6 zones (i = 1,, 6) and in each of them, the heat flux density was calculated as a function of the time q _i (t) on the inner surface of the barrel. In each zone, the heat transfer coefficient, as a function of the time hi(t) and bore gas temperature as a function of the time Tg(t) to the cannon barrel for given ammunition parameters, was developed. A calculating time equaling 100 ms per single shot was assumed. The results of the calculations were obtained using FEM implemented in COMSOL Multiphysics ver. 5.6 software.

Published

2023

2. Ballistic Model of Two-Stage Light Gas Gun

Author

Zbigniew SURMA

Subjects

light gas gun, propulsion system, hypervelocity, interior ballistics, Electronics, TK7800-8360, Chemical engineering, TP155-156

Abstract

A physical model and specificity of a two-stage light gas gun propulsion system are presented in this paper. For the considered system, a mathematical model of phenomena inside a combustion chamber, a light gas filled chamber, and a barrel was worked out. A numerical solution of the proposed model for the considered propulsion system gives pressures of powder gases, pressure of light gas, and motion parameters of a piston and a projectile. On the basis of the results of the accomplished calculations, influence of system structural parameters on the maximum pressure inside a compression chamber and a muzzle velocity of a projectile has been analysed. The final results of this work were used for development of the first in Poland a laboratory station with two-stage light gas gun intended for experimental investigation in the field of terminal ballistics of objects moving at hypersonic velocities.

Published

2023

3. Influence of the Shrinkage of the Inner Layer of Steel Tubes on Permissible Thermal Load

Author

Mateusz Zieliński, Piotr Koniorczyk, and Zbigniew Surma

Subjects

heat transfer, temperature field, protective coating, shrinkage of the steel, modeling, Technology

Abstract

This paper presents the results of numerical simulations of heat transfer in a tube with a protective chromium layer on the inner surface made of steel, with different shrinkage temperatures. Shrinkage in the steel is an unfavorable phenomenon because it causes cracks in the chrome coating. The cracks contribute to the peeling of the protective material on the inner surface of the tube. Wear and damage to the chrome layer significantly shortens the tube’s service life. The influence of the type of steel with medium carbon content on heat transfer for a sequence of ten, thirty, and sixty heat impulses was examined. Simulations were carried out for two selected steels with clearly different shrinkage temperatures, i.e., 30HN2MFA and X37CrMoV5-1 (1.2343). In 30HN2MFA steel, the shrinkage effect occurred at a temperature of approx. 750 °C, while in X37CrMoV5-1 steel it occurred at a temperature of approx. 870 °C. In the computational model, 30 cross-sections of the three-meter-long tube were analyzed. A time-dependent heat transfer coefficient was calculated in each zone. Heat transfer simulations were carried out using COMSOL version 6.1 software. This paper shows that for X37CrMoV5-1 steel, the shrinkage temperature on the inner surface of the tube was reached after approx. 60 heat impulses, while for 30HN2MFA steel, it was reached after approx. 30. The greatest differences in the number of impulses occurred for a pipe with a 200 µm thick chrome layer.

Published

2024

4. Influence of the Ignition Method on the Characteristics of Propellant Burning in the Context of the Geometric Burning Model

Author

Zbigniew Leciejewski, Zbigniew Surma, and Radosław Trębiński

Subjects

closed vessel test, propellant, burning rate, ignition, form function, Technology

Abstract

Mathematical models for the simulation of the operation of various projectile-throwing systems are continuously modified, simultaneously with the development of propellants. For these models, properly determined values of energetic ballistic characteristics of propellants are very important. This paper presents an original test and the results of closed vessel comparative investigations. The study analyses specific combustion characteristics of single-base propellants using conventional black powder ignition, plasma ignition, and gas ignition. The results of the study indicate the need to take into account—in the calculation of the burning rate—not only the dynamics of gas pressure changes but also the real (experimental) form function, which differs from the theoretical one resulting from the assumed geometric burning model. The obtained results allow for a critical analysis of the existing methods used for the determination of values of ballistic characteristics of propellants. Further, it will allow for creating pyrostatic test conditions that would reflect the condition of instantaneous ignition of propellant grains over their entire surface in the most realistic way.

Published

2023

5. Studies on Influence of Chromium Layer on Inner Surface of Steel Tube on Heat Transfer

Author

Mateusz Zieliński, Piotr Koniorczyk, and Zbigniew Surma

Subjects

heat transfer, temperature field, protective coating, modeling, Technology, Engineering (General). Civil engineering (General), TA1-2040, Biology (General), QH301-705.5, Physics, QC1-999, Chemistry, QD1-999

Abstract

This paper presents the results of numerical calculations of heat transfer in the steel wall of a tube with different chromium layer thicknesses on the inner surface for a single and a sequence of heat impulses. In modeling the thermal phenomenon, the tube material was assumed to be homogeneous, and the inner surface of the tube had a protective chromium layer. The calculations were performed for temperature-dependent parameters of the 30HN2MFA steel and chromium. The tube was divided into 30 zones. The time varying the heat transfer coefficient and the heat flux density on the inner surface of the tube in each zone were calculated. The numerical simulations of heat transfer in the tube wall were performed using the FEM implemented in COMSOL Multiphysics software. On account of the high thermal conductivity of chromium, after the first and subsequent heat impulses, as the thickness of the chrome layer increases, the highest peak temperature drops, while the temperature inside the steel wall of the tube increases. After the first heat impulse, the temperature of the wall at a depth 0.5 mm below the inner surface is twice as high for a tube with a 200 µm thick chrome coating compared to a tube without this coating. This paper showed that, after seven heat impulses, the temperature of the steel tube substrate does not exceed 750 °C, at which the shrinkage of the material occurs, causing cracks in the chrome coating.

Published

2023

6. Experimental Assessment of Primer Pressure in 9 mm Pistol Ammunition

Author

Bartosz FIKUS, Zbigniew SURMA, and Radosław TRĘBIŃSKI

Subjects

closed vessel test, ignition pressure, ignition charge mass, Electronics, TK7800-8360, Chemical engineering, TP155-156

Abstract

In theoretical simulations of internal ballistics phenomena, the value of pressure generated by the ignition system is required. Typically, the ignition pressure value is assumed to be 3 - 5 MPa. The work presents a measurement stand using a “micro closed vessel”, designed to determine the ignition pressure for 9 mm pistol ammunition. Pressure measurements were made for two types of ammunition, differing in the construction of the ignition system. The results of measurements indicate that the value of the ignition pressure is twice as high as usually assumed. In addition, the mass of the ignition charge was determined, which is used in selected models of internal ballistics. The mass value was at the level of 0.02 g.

Published

2020

7. Specificity of Burning of Porous Combustible Material Used as Cartridge Case

Author

Zbigniew Surma, Zbigniew Leciejewski, and Radosław Trębiński

Subjects

combustible cartridge case, closed vessel test, dynamic vivacity, burning rate, Technology

Abstract

The combustible cartridge case has become an integral part of many modern weapons systems. The energetic and burning characteristics of the combustible case can have a significant impact on shot parameters. This paper describes Closed Vessel Tests (CVTs) performed on combustible cartridge case material and presents a method of determining the physical burning law and the linear burning rate of the tested material. The method was verified on the basis of the results of CVT of the felted combustible cartridge case material of a 120 mm tank round. It is shown that, in the case of porous combustible materials, the standard methods of determining the burning rate fail. The porosity of combustible materials greatly increases the burning surface and heat feedback from the burning zone to the unburned structure. These effects significantly increase the burning rate of porous materials. The results of analysis show the strong dependence of the burning rate on pressure. The results of this study can be applied in the modeling of gun propellant systems that contain combustible case elements.

Published

2022

8. Comparative analysis of the effects of gunpowder and plasma ignition in closed vessel tests

Author

Radoslaw Trebinski, Zbigniew Leciejewski, Zbigniew Surma, and Jakub Michalski

Subjects

Military Science

Abstract

This paper presents the results of a comparative investigation into the effects of the ignition method on the ballistic properties of a single-base gun propellant, as determined via closed vessel tests. Conventional gunpowder ignition and plasma jet ignition methods were used, and differences in the ignition time were analysed. The influence of the ignition method on the dynamic vivacity is discussed. It is shown that this influence is significant in the first phase of the combustion process, and with respect to the low values of the loading density. In the second phase of the combustion process, and for large values of the loading density, the dynamic vivacity plots for the two ignition methods converge. Regarding the burning law, close values of the exponent were obtained for the two ignition methods. The dynamic vivacity plots determined for plasma ignition reveal stronger dependence on the loading density than those determined for gunpowder ignition. The conclusion is that plasma ignition is not a solution to the problems inherent to the process of determining the ballistic properties of propellants, which results in deviation of the burning process from the geometric burning law. Keywords: Closed vessel test, Gun propellant, Gunpowder ignition, Plasma ignition

Published

2019

9. Investigations of the Influence of Ignition on the Dynamic Vivacity of Propellants

Author

Radosław TRĘBIŃSKI, Zbigniew LECIEJEWSKI, and Zbigniew SURMA

Subjects

internal ballistics, dynamic vivacity, ignition, Electronics, TK7800-8360, Chemical engineering, TP155-156

Abstract

The paper presents an attempt to determine the dynamic vivacity functions of propellants with taking into account a parallel burning of the black powder igniter and the tested propellant. The approach is based on presented results of closed vessel tests, proving that the burning of the tested propellant starts before complete burning of the black powder igniter. Basing on closed vessel tests results for black powder, its dynamic vivacity function was determined. It was used for a prediction of the partial pressure of black powder combustion products in the case when black powder was used as an igniter. Dynamic vivacity curves are compared with the dynamic vivacity curves calculated at the assumption that the combustion of the main charge starts after the complete burning of the igniter. Obtained results show that the considered approach fails due to a very complex interaction between the igniter and the tested propellant.

Published

2019

10. Recoilless Gun System as a Particular Form of General Interior Ballistics Model of Gun Propellant Systems

Author

Zbigniew SURMA

Subjects

mechanics, interior ballistics, recoilless propellant system, Electronics, TK7800-8360, Chemical engineering, TP155-156

Abstract

The development of the interior ballistics general model of gun propellant systems by taking into account the specificity of the recoilless propellant system is presented in this paper. The presented expanded physical and mathematical model makes possible the simulation of classical and nonclassical gun systems: two-chamber, mortar, and the considered recoilless one. To solve the system of equations associated with the mathematical model, a computer programme was developed. An analysis was made for two configurations of a recoilless system, differing in the way of arrangement of a propellant charge, i.e., with the propellant charge moving together with a projectile and with the propellant charge burning in a cartridge chamber. The obtained calculation results showed that the system, in which the propellant charge moves together with a projectile, has the maximum pressure and the muzzle velocity higher in comparison with the system with the propellant charge burning in a cartridge chamber. Influence of a way of placement of the propellant charge is the stronger, the higher is the ratio of its mass to the projectile mass. The results of the accomplished calculations, especially the pressure inside the barrel as well as motion parameters of the projectile make the grounds for projecting and construction optimization of the recoilless gun systems.

Published

2018

11. Determining the Burning Rate of Fine-Grained Propellants in Closed Vessel Tests

Author

Radosław Trębiński, Zbigniew Leciejewski, and Zbigniew Surma

Subjects

closed vessel test, burning rate, form–function, fine-grained propellants, Technology

Abstract

This paper presents the method of determining the burning rate of fine-grained propellants based on the results of closed vessel tests. It is shown that in the case of fine-grained propellants, the standard methods of determining the burning rate fail. There are two reasons for this: imperfections of the grain shapes and the prolonged process of ignition due to a more developed surface than that of coarse grains at the same mass of the propellant. The value of the exponent in the burning law is estimated by the use of the so-called experimental form–function. The upper and lower limits of the value of the coefficient in the burning law are estimated. The accuracy of the proposed method is analyzed. Its validity is assessed by comparing the results of closed vessel tests analysis with accessible literature data.

Published

2022

12. Numerical Study of Heat Transfer in a Gun Barrel Made of Selected Steels

Author

Mateusz Zieliński, Piotr Koniorczyk, Zbigniew Surma, Janusz Zmywaczyk, and Marek Preiskorn

Subjects

anti-aircraft cannon barrel, modeling, heat transfer, numerical simulation, temperature field, Technology

Abstract

The results of numerical simulations of transient heat transfer in the barrel wall of a 35 mm caliber cannon for a single shot and the sequences of seven shots and sixty shots for chosen barrel steels are presented. It was assumed that the cannon barrel was made of one of the three types of steel: 38HMJ (1.8509), 30HN2MFA and DUPLEX (1.4462). To model the thermal phenomena in the barrel, the barrel wall material was assumed to be homogeneous and the inner surface of the barrel had no protective chromium or nitride layer. The calculations were made for temperature-dependent thermophysical parameters, i.e., thermal conductivity, specific heat and thermal expansion (in the range from RT up to 1000 °C) of the selected barrel steels. A barrel with a total length of 3150 mm was divided into 6 zones (i = 1, …, 6) and in each of them, the heat flux density was calculated as a function of time q˙i(t) on the inner surface of the barrel. Using lumped parameter methods, an internal ballistic code was developed to compute in each zone the heat transfer coefficient as a function of time hi(t) and bore gas temperature as a function of time Tg(t) to the cannon barrel for given ammunition parameters. A calculation time equaling 100 ms per single shot was assumed. The results of the calculations were obtained using FEM implemented in COMSOL Multiphysics ver. 5.6 software.

Published

2022

13. Heat Transfer Calculations in Barrel Cover of 35 mm Naval Armament System Gun

Author

Zbigniew LECIEJEWSKI, Piotr KONIORCZYK, Andrzej DĘBSKI, Marek PREISKORN, Zbigniew SURMA, and Janusz ZMYWACZYK

Subjects

mechanics, heat transfer, anti-aircraft gun barrel cover, Electronics, TK7800-8360, Chemical engineering, TP155-156

Abstract

This paper presents the results of numerical simulations of non-stationary heat transfer in a 35 mm anti-air gun barrel cover made of composite materials. The cover protects the gun against weather conditions, including sea water effects, and serves as a protection against mechanical damage. It was assumed that heat coercion in this problem will be the heat condition reached by the material of the barrel with the cover removed, after firing three bursts of 7 shells each, 120 s after opening fire. It was assumed, that in the second 120, the gun crew installs the gun cover and at this point, the heating process begins, followed by cooling of the cover material. The problem of initial and boundary value in the barrel with a cover installed system was solved as a three-dimensional initial and boundary problem. The initial and boundary value model adopted for the coverless barrel and the calculation results for the first burst of seven shells was presented in paper [7]. To obtain the heat condition of the barrel in the second 120, it was necessary to perform calculations for the second and third bursts, and for the barrel cooling processes starting in the second 120. The calculations were performed with a finite element method in the COSMOS/M software [9]. The cover material temperature values obtained during the numerical simulation are well below the temperature of 387K, which could form the upper limit of the composite applicability temperature range.

Published

2018

14. Ballistic Analysis of Polish Low-Vulnerability Gun Propellants

Author

Marta CZYŻEWSKA, Bartosz FIKUS, Zbigniew LECIEJEWSKI, Jakub MICHALSKI, Zbigniew SURMA, and Radosław TRĘBIŃSKI

Subjects

mechanics, internal ballistics, closed vessel tests, low-vulnerability propellant, Electronics, TK7800-8360, Chemical engineering, TP155-156

Abstract

One direction of modern artillery ammunition development is to reduce its vulnerability to the effects of mechanical and thermal factors during transport, storage and operation. For LOVA, the reduced vulnerability of propellant explosives intended for loading into this ammunition is usually connected with a higher thermal ignition impulse threshold and reduced burning rate under low propellant gas pressure. Since 2016, work has been under way at the Military University of Technology (Warsaw, Poland), intended to develop a Polish low-vulnerability gun propellant for 120 mm tank ammunition. It was established during the initial stage of research and analysis, that the JA-2 gun propellant (more specifically, its energy and ballistics characteristics and geometrical dimensions of grains) will be the reference propellant for the low-vulnerability propellant in development. To this end, the authors performed closed vessel tests with JA-2 propellant (with seven-perforated grains designated LO5460). This paper contains comparative (with the JA-2 propellant) results of closed vessel tests of several propellant blends developed by the MUT Faculty of New Technologies and Chemistry research team. Closed vessel tests of these propellant blends were performed in the Ballistics Laboratory of the MUT Institute of Armament Technology using a manometric chamber with a volume W0 = 200 cm3. Experimental tests and theoretical analyses were performed based on provisions of the standardisation agreement STANAG 4115 [6], American military standard MIL-STD 286C [7] and original test procedures developed based on [8, 9]. The tests focused mainly on the issue of correlation between the chemical composition of the given propellant blend with the expected values of energy and ballistics characteristics in connection with the required shape of propellant grains.

Published

2018

15. Investigations of Ballistic Characteristics of N340 Propellant

Author

Radosław TRĘBIŃSKI, Bartosz FIKUS, and Zbigniew SURMA

Subjects

ballistic characteristics, single-based propellant, dynamic vivacity, burning law, heat losses, Electronics, TK7800-8360, Chemical engineering, TP155-156

Abstract

Results of investigations of ballistic characteristics of the single-based N340 propellant are presented. A novel approach, proposed in an earlier authors’ work, was applied. Basing on pressure records, obtained in closed vessel tests the burning law and the dynamic vivacity function were determined. High value of the exponent in the burning law was obtained (1.25). This effect can be attributed to the process of infiltration of hot gases into propellant pores, enhanced by the increase in the pressure. The dynamic vivacity function was proved to be dependent on the value of the loading density. A simple analytical approximation of the averaged vivacity function was proposed. It describes the ballistic properties of the propellant much better than the geometric law of combustion. An effect of heat losses on the vivacity function was estimated, showing relatively small influence of the losses on the vivacity function. The obtained results confirmed applicability of the novel approach to the characterization of ballistic properties of fined-grained propellants.

Published

2017

16. Analysis of Application of Plasma Ignition in Closed Vessel Tests

Author

Radosław Trębiński, Zbigniew Leciejewski, Zbigniew Surma, and Jakub Michalski

Subjects

closed vessel test, gun propellant, gunpowder ignition, plasma ignition, Technology

Abstract

This paper presents the results of a comparative investigation into the effects of the ignition method on the ballistic properties of three types of propellants: a single-base propellant, a double-base propellant and a low vulnerability (LOVA) propellant, as determined via closed vessel tests (CVT). Conventional gunpowder ignition and plasma jet ignition methods were used. The influence of the ignition method on the values of the propellant characteristics obtained in CVT was analysed. It was found that the method of ignition has an influence on the values of propellant characteristics, determined in CVT. An analysis of the experimental form functions showed that plasma ignition is not a solution to the problems inherent to the process of determining the ballistic properties of propellants in which the burning process deviates from the geometric burning law.

Published

2021

17. Preliminary Studies of a Propellant System for the Counterprojectile of an Active Protection System

Author

Zbigniew SURMA, Mirosław ZAHOR, Przemysław KUPIDURA, and Zbigniew Leciejewski

Subjects

mechanics, active protection system, rocket engine, solid rocket propellant, Electronics, TK7800-8360, Chemical engineering, TP155-156

Abstract

This paper presents a selection of the deliverables for a research project intended to develop a technology demonstrator for a smart counterprojectile forming part of an active protection system. Given the required activation of the active protection system within a distance of ten or so metres from the protected facility, a solid-propellant rocket engine was used, which has the characteristics of a booster rocket. For the determined configuration of the rocket engine, the elements of the counterprojectile and missile launcher were designed, based on homogeneous rocket propellant of Polish origin. To confirm the validity of the adopted concept for the propulsion system solution, preliminary testing of the rocket engine was conducted using an engine test bed, and included the measurement of gas pressure and engine thrust for different masses of ignition charge. To ultimately verify the operation of the design, field testing of the counterprojectile propulsion system was carried out, based on which the parameters of projectile motion inside the missile launcher and along the initial flight path length were determined.

Published

2017

18. Numerical Analysis of the Effects of the Geometric and Weight Parameters on the Exterior Ballistics of a Designed Counterprojectile

Author

Jakub MICHALSKI, Zbigniew SURMA, and Marta CZYŻEWSKA

Subjects

mechanics, exterior ballistics, numerical analysis, Electronics, TK7800-8360, Chemical engineering, TP155-156

Abstract

This paper presents a selection of deliverables of a research project intended to develop a technology demonstrator for an active protection system smart counterprojectile. Numerical simulations were completed to analyse the effects of geometry and weight of the counterprojectile warhead on the counterprojectile flight (motion) parameters. This paper investigates four variants of the counterprojectile warhead shape and three variants of the counterprojectile warhead weight. Given the investigated geometric and weight variants, the PRODAS software environment was used to develop geometric models of the counterprojectile warhead, followed by the determination of the model aerodynamic characteristics. The final deliverable of this work are the results of the numerical simulation of the counterprojectile motion along the initial flight path length. Given the required activation of the active protection system in direct proximity of the protected object, the analyses of counterprojectile motion parameters were restricted to a distance of ten-odd metres from the counterprojectile launching system.

Published

2017

19. Experimental Investigations of Motion of Slide of Selected Pistol Types

Author

Bartosz FIKUS, Wojciech KOPERSKI, Paweł PŁATEK, Zbigniew SURMA, and Radosław TRĘBIŃSKI

Subjects

mechanics, pistol slide motion, fast camera measurements, experimental investigations, Electronics, TK7800-8360, Chemical engineering, TP155-156

Abstract

In the presented paper, kinematic characteristics of movable parts of investigated pistols have been experimentally determined with application of high speed camera and appropriate software TEMA motion. Results of measurements can be useful in validation of various theoretical models and can reveal the influence of some technical solutions on parameters of motion of selected parts. Obtained curves presenting dependence of slide velocity versus time, allowed for rough estimation of average value of interaction force between slide and frame of the investigated construction. The results of study highlights advantage of HK USP pistol design. The achieved results are from reduction of the value of the mentioned interaction force (approximately 50%) due to elongation of the most intensive phase of slide motion damping process.

Published

2016

20. Analysis of Heat Transfer in a 35 mm Barrel of an Anti-Aircraft Cannon

Author

Andrzej DĘBSKI, Piotr KONIORCZYK, Zbigniew Leciejewski, Marek PREISKORN, Zbigniew SURMA, and Janusz ZMYWACZYK

Subjects

mechanics, heat transfer, anti-aircraft cannon barrel, Electronics, TK7800-8360, Chemical engineering, TP155-156

Abstract

The paper presents the results of computer simulations of unidentified transient heat transfer in the wall of a 35 mm cannon barrel for a single shot and for a sequence of seven shots with a subsequent firing break. The cannon barrel was made of 32CrMoV12-28 steel. For the phenomenon modelling, it was assumed that the material of the barrel wall is uniform and the barrel’s inner surface does not feature a protective coating of galvanic chrome or a nitrided casing. Calculations were performed for two input data variants: (i) for constant values of thermophysical parameters and (ii) for a temperature-dependent specific heat. The barrel with an overall length of 3150 mm was divided into 6 zones. On the inner surface of the barrel in each zone there were assumed various values of heat flux density expressed as rectangular functions in the range from 0 to 10 ms (with the start of ti of the function shifted in the subsequent zones). The calculation time for a single shot was assumed as equal to 100 ms. The calculations were performed with a finite element method in COSMOS/M software.

Published

2016

21. Laboratory Investigations on Perforation of 30PM Steel Plates

Author

Jacek JANISZEWSKI, Michał GRĄZKA, Djalel TRIA, Zbigniew SURMA, and Bartosz FIKUS

Subjects

mechanics, hard armor steel, perforation, laboratory experiments, Electronics, TK7800-8360, Chemical engineering, TP155-156

Abstract

In this study, high strength steel plates made of 30PM steel were subjected to 7.62 Armour Piercing projectiles at the ordnance velocity. Several experiments differing considerably in conditions of interaction between projectiles and plates were performed. Selected parameters were measured before, during, and after ballistic tests, and both projectile and plate were subjected to detailed examination. It is foreseen to use the obtained results in two ways. Protection performance of steel plates will be determined and experimental data will be used as a reference for analyzing various models and numerical techniques, accessible in commercially available hydrocodes. The authors present the methodology, the experimental set-up configuration, and the results of laboratory experiments.

Published

2016

22. On Influence of Mechanical Properties of Gun Propellants on Their Ballistic Characteristics Determined in Closed Vessel Tests

Author

Radosław Trębiński, Jacek Janiszewski, Zbigniew Leciejewski, Zbigniew Surma, and Kinga Kamińska

Subjects

gun propellants, mechanical material properties, high strain rate testing, shape function, Technology, Electrical engineering. Electronics. Nuclear engineering, TK1-9971, Engineering (General). Civil engineering (General), TA1-2040, Microscopy, QH201-278.5, Descriptive and experimental mechanics, QC120-168.85

Abstract

The geometric burning law of gun propellants is widely used in computer codes used for the simulations of the internal ballistics of guns. However, the results of closed vessel tests prove that the burning process of some propellants deviates from the geometric law. Validation of the hypothesis that observed deviations can be attributed to the cracking of propellant grains was the aim of this work. In order to verify the hypothesis, three types of gun propellants were chosen with considerably differing mechanical strengths: a single-base propellant, a double-base propellant, and a composite propellant. The mechanical properties of the gun propellants were tested using a quasi-static compression method with strain rate values of the order of 0.001 s−1 and the Split Hopkinson Pressure Bar technique with the strain rate in the range of 1000–6000 s−1. The mechanical responses of the propellants were assessed on the basis of the true stress–strain curves obtained and from the point of view of the occurrence of cracks in the propellant grains specimens. Moreover, closed vessel tests were performed to determine experimental shape functions for the considered gun propellants. Juxtaposition of the stress‒strain curves with the experimental shape functions proved that the observed deviations from the geometrical burning law can be attributed mainly to the cracking of propellant grains. The results obtained showed that the rheological properties of propellants are important not only from the point of view of logistical issues but also for the properly controlled burning process of propellants during the shot.

Published

2020

23. Specifying the Initial Conditions to Simulate the Flight of Artillery Shells

Author

Leszek BARANOWSKI and Zbigniew SURMA

Subjects

Mechanics, initial conditions, mortar grenade, flight simulation, Electronics, TK7800-8360, Chemical engineering, TP155-156

Abstract

The results of field tests of 120 mm mortar have been presented in this paper. Tests were conducted with using the mortar projectile type OF-483A. The main task of investigations was experimental determination of muzzle velocity and throwing angle, which are initial conditions for numerical simulation of the mortar projectile flight. Muzzle velocity and throwing angle were determined on the basis of accomplished results of motion the projectile as well as the mortar. The high-speed camera Phantom v12 was used during the field tests. The projectile velocity and the movement of the mortar barrel were calculated by means of TEMA Motion program.

Published

2014

24. Ballistic Analysis of Missile Propulsion in a Perforated Barrel Launcher

Author

Zbigniew Leciejewski and Zbigniew Surma

Subjects

Physics, Missile, business.industry, Organic Chemistry, Materials Chemistry, Barrel (horology), Aerospace engineering, Propulsion, business

Published

2020

25. Preliminary analysis of ballistic requirements for LOVA propellants for new generation tank ammunition

Author

Radosław Trębiński, Zbigniew Surma, Bartosz Fikus, Zbigniew Leciejewski, and Jakub Michalski

Subjects

Propellant, Ammunition, 020303 mechanical engineering & transports, 0203 mechanical engineering, Nuclear engineering, Environmental science, 02 engineering and technology, Preliminary analysis

Abstract

At the end of 2016, the Scientific-Industrial Consortium (Mesko S.A., Polska Grupa Zbrojeniowa S.A., Warsaw University of Technology, Military University of Technology, Military Institute of Armament Technology) set up an R&D project to develop and manufacture a demonstrator of new generation critical components for a 120 mm Polish tank munition. The critical elements for the project included a combustible charge case, an insensitive propellant and tungsten rods for subcalibre projectiles. The task of the Military University of Technology was to develop the basic technology and fabricate insensitive LOVA propellants on a laboratory scale (research team of the Faculty of Advanced Technologies and Chemistry) and carry out the ballistic and simulation tests of a 120 mm tank gun using ammunition incorporating the developed LOVA propellant (research team of the Faculty of Mechatronics, Armamen and Aerospace). The article also includes an analysis of available literature on energy and ballistic properties of LOVA and JA-2 propellants. Closed-vessel tests of JA-2 propellant (manufactured by Nitrochemie AG, designation LO5460) were also carried out. The tests were carried out in a 200 cm3 closed vessel. Based on the propellant gas pressure/time records, the propellant force and co-volume, and dynamic vivacity curves were determined. A linear combustion rate coefficient was determined using the measured results of the propellant grain geometry. The authors’ own data enabled the carrying out of preliminary simulation tests of the 120 mm propellant system.

Published

2020

26. Theoretical and experimental investigations on a rocket propulsion system of projectiles intended for vehicle active protection system

Author

Zbigniew Leciejewski, Marek Białek, Zbigniew Surma, and Arkadiusz Dzik

Subjects

Engineering, 'Active' protection, Spacecraft propulsion, business.industry, Projectile, Aerospace engineering, business

Abstract

The paper presents the results of a research project carried out at the Military University of Technology aimed at designing a technology demonstrator of an active protection system – a smart counter-projectile for combating anti-tank missiles at a fixed distance from the protected object. Since the design of the counter-projectile head includes electronic components sensitive to high loads, a solid propellant rocket motor was used as the propulsion system. Based on the specification and requirements for the propulsion system, the propellant charge and nozzle dimensions were determined, and the performance properties of the designed system (chamber pressure, thrust with time and total thrust pulse), calculated. The tests and analyses were carried out using the known properties of homogenous solid rocket propellants manufactured in Poland. To verify the results of the theoretical analysis, experimental studies were carried out in collaboration with “GAMRAT” Sp. z o.o. Special Production Plant (Jasło, Poland) to validate the selected solid propellant and the initial assumptions made on the operation of the propulsion system of the designed counter-projectile.

Published

2020

27. IDENTIFICATION OF EXPERIMENTAL FORM FUNCTION USING LUMPED PARAMETERS INTERIOR BALLISTICS MODELS

Author

Bartosz Fikus, Zbigniew Leciejewski, Radoslaw Trebinski, Damian Szupieńko, and Zbigniew Surma

Abstract

A method for identifying experimental form functions based on the results of interior ballistics modelling using lumped parameters models is presented. The function is defined as the relation between the ratio of the actual burning surface of a whole propellant charge, to the initial global surface of all propellant grains in the charge and the relative burnt mass of the charge. It is approximated by a function depending on several parameters. Values of the parameters are identified by fitting the results of the interior ballistics modelling to the measured maximum pressure value and the projectile muzzle velocity value. The identified experimental form functions are compared to the functions determined in closed vessel tests. The examples analyzed suggest that the use of the experimental form function enables us to take into account the process of ignition in lumped parameters models.

Published

2022

28. INFLUENCE OF RELATIONS DEFINING PROPELLANT GASES—BARREL HEAT TRANSFER ON CRITICAL BURST LENGTH OF 35 MM ANTI-AIRCRAFT CANNON

Author

BARTOSZ FIKUS, ZBIGNIEW SURMA, ZBIGNIEW LECIEJEWSKI, and RADOSLAW TRĘBIŃSKI

Abstract

The paper presents a review of propellant gases – barrel heat transfer relations and their influence on results of interior ballistics simulations for an artillery system. During simulations the lumped-parameters model of interior ballistics was applied. The thermal processes were calculated using the distributed-parameters model and resulted in barrel temperature changes estimation. Taking into account the high fire rate of investigated system – i.e. anti-aircraft cannon – the influence of applied heat transfer definition on critical burst length was estimated. Various considered formulae provided wide interval of obtained critical burst length for investigated system.

Published

2022

29. Investigations of Middle-Caliber Anti-Aircraft Cannon Interior Ballistics including Heat Transfer Problem in Estimation of Critical Burst Length

Author

Bartosz Fikus, Alicja Dorochowicz, Zbigniew Surma, Jacek Kijewski, Zbigniew Leciejewski, Jakub Michalski, and Radosław Trębiński

Subjects

anti-aircraft cannon, interior ballistics modelling, barrel resistance, numerical simulations, heat transfer in barrel, Process Chemistry and Technology, Chemical Engineering (miscellaneous), Bioengineering

Abstract

Numerical and experimental investigations of armament systems are an important part of modern design processes. The presented paper reports problems that were encountered on the theoretical analysis of the performance of 35 mm anti-aircraft cannon and the way in which they were solved. The first problem concerns the application of results of closed vessel tests of used propellant in interior ballistics simulations. The use of a nonstandard form of the gas generation rate equation solved this problem. The second problem concerned the assessment of projectile–barrel interaction. The barrel resistance was estimated making use of finite element analysis. The third problem arose from the need to determine the heat transfer from propellant gases to the barrel. The employed formula for the heat exchange coefficient and 2D modelling of the heat conduction in the barrel provided the solution. Selected elements of the theoretical model were validated by shooting range experiments and data provided by the ammunition producer. Using the considered approach, crucial ballistic parameters (maximum propellant gas pressure and muzzle velocity) were estimated with an error of less than 6.0%, without application of additional fitting coefficients. The numerical estimation of the barrel external surface temperature provided a relative discrepancy with the experimental data lower than 6% and enabled the estimation of the critical burst length, equal to 14 shots.

Published

2022

30. Thermochemical Properties, Ballistic Parameters and Sensitivity of New RDX-based Propellants

Author

Mateusz Szala, Zbigniew Chyłek, Marcin Hara, Waldemar A. Trzciński, Stanisław Cudziło, and Zbigniew Surma

Subjects

Propellant, Materials science, Organic Chemistry, Materials Chemistry, Sensitivity (control systems), Composite material

Published

2020

31. Experimental Assessment of Primer Pressure in 9 mm Pistol Ammunition

Author

Radosław Trębiński, Zbigniew Surma, and Bartosz Fikus

Subjects

Primer (paint), Chromatography, Materials science, ignition charge mass, lcsh:Electronics, lcsh:TK7800-8360, lcsh:TP155-156, General Medicine, engineering.material, Ammunition, Physics::Plasma Physics, closed vessel test, ignition pressure, engineering, Physics::Chemical Physics, lcsh:Chemical engineering

Abstract

In theoretical simulations of internal ballistics phenomena, the value of pressure generated by the ignition system is required. Typically, the ignition pressure value is assumed to be 3 - 5 MPa. The work presents a measurement stand using a “micro closed vessel”, designed to determine the ignition pressure for 9 mm pistol ammunition. Pressure measurements were made for two types of ammunition, differing in the construction of the ignition system. The results of measurements indicate that the value of the ignition pressure is twice as high as usually assumed. In addition, the mass of the ignition charge was determined, which is used in selected models of internal ballistics. The mass value was at the level of 0.02 g.

Published

2020

32. INFLUENCE OF HEAT LOSSES CORRECTION ON POWDER CHARACTERISTICS DETERMINED IN PYROSTATIC INVESTIGATIONS

Author

Radosław Trębiński, Zbigniew Surma, and Zbigniew Leciejewski

Subjects

Materials science, Heat losses, General Medicine, Composite material

Abstract

The paper studies the influence of heat losses in pyrostatic investigations on values of powder (propellant) measured characteristics. The influence of heat losses was assessed by a method developed by authors. Corrected pressure records were used to determine characteristics of JA-2 powder and SC-100 composite powder. Values of powder force and the covolume, the dynamic vivacity L, the burning rate, the exponent and the coefficient in the burning law, the dynamic vivacity G, and the experimental shape function were determined. The values of the force and the covolume were compared with results of thermochemical calculations. Basing on the results of the comparison the correctness of the method was confirmed. Other characteristics were compared with those determined without any correction. It was revealed that the correction for the heat losses diminishes the values of the dynamic vivacities L and G, as well as of the burning rate.

Published

2020

33. Investigations of the Influence of Ignition on the Dynamic Vivacity of Propellants

Author

Zbigniew Leciejewski, Zbigniew Surma, and Radosław Trębiński

Subjects

Propellant, internal ballistics, Materials science, dynamic vivacity, lcsh:Electronics, lcsh:TK7800-8360, lcsh:TP155-156, General Medicine, law.invention, Ignition system, law, Physics::Plasma Physics, ignition, Physics::Chemical Physics, lcsh:Chemical engineering

Abstract

The paper presents an attempt to determine the dynamic vivacity functions of propellants with taking into account a parallel burning of the black powder igniter and the tested propellant. The approach is based on presented results of closed vessel tests, proving that the burning of the tested propellant starts before complete burning of the black powder igniter. Basing on closed vessel tests results for black powder, its dynamic vivacity function was determined. It was used for a prediction of the partial pressure of black powder combustion products in the case when black powder was used as an igniter. Dynamic vivacity curves are compared with the dynamic vivacity curves calculated at the assumption that the combustion of the main charge starts after the complete burning of the igniter. Obtained results show that the considered approach fails due to a very complex interaction between the igniter and the tested propellant.

Published

2019

34. Determining the Burning Rate of Fine-Grained Propellants in Closed Vessel Tests

Author

Zbigniew Surma, Zbigniew Leciejewski, and Radoslaw Trebinski

Subjects

Control and Optimization, closed vessel test, burning rate, form–function, fine-grained propellants, Renewable Energy, Sustainability and the Environment, Energy Engineering and Power Technology, Building and Construction, Electrical and Electronic Engineering, Engineering (miscellaneous), Energy (miscellaneous)

Abstract

This paper presents the method of determining the burning rate of fine-grained propellants based on the results of closed vessel tests. It is shown that in the case of fine-grained propellants, the standard methods of determining the burning rate fail. There are two reasons for this: imperfections of the grain shapes and the prolonged process of ignition due to a more developed surface than that of coarse grains at the same mass of the propellant. The value of the exponent in the burning law is estimated by the use of the so-called experimental form–function. The upper and lower limits of the value of the coefficient in the burning law are estimated. The accuracy of the proposed method is analyzed. Its validity is assessed by comparing the results of closed vessel tests analysis with accessible literature data.

Published

2022

35. Synthesis of nitrogen-rich compounds and their use in novel composite propellants

Author

Leszek Szymańczyk, Marcin Hara, Mateusz Szala, and Zbigniew Surma

Subjects

Propellant, chemistry.chemical_compound, Thermogravimetric analysis, animal structures, Materials science, chemistry, Chemical engineering, Dibutyl phthalate, Differential thermal analysis, Composite number, Plasticizer, Volatility (chemistry), Nitrocellulose

Abstract

High-nitrogen azotetrazole salts were synthesized, characterized and used as nitrogen-rich compounds for the preparation of novel composite propellants. Triaminoguanidinium and guanidinium azotetrazolate (TAGAZ, GUAZ) were selected based on the results of thermic and sensitivity measurements. Nitrocellulose was used as a traditional ingredient of propellants, while dibutyl phthalate and 3-methyl-3-nitroxymethyloxetane (NIMMO) was used as a plasticizer. The ingredients and resulting propellants were tested using differential thermal analysis coupled with a thermogravimetric method. Standard pyrostatic tests in a closed chamber were also conducted and characteristic ballistic parameters were calculated. Both of the high-nitrogen compounds that were tested could be potential ingredients of future propellants. The pressure rise rate for the tested propellants is simply correlated with the amount of TAGAZ/GUAZ. NIMMO is an interesting new plasticizer for nitrocellulose, although it exhibits relatively high volatility during DTA-TG tests which limits its utility.

Published

2020

36. Heat Transfer Calculations in Barrel Cover of 35 mm Naval Armament System Gun

Author

Andrzej Dębski, Janusz Zmywaczyk, Zbigniew Surma, Zbigniew Leciejewski, Piotr Koniorczyk, and Marek Preiskorn

Subjects

Heat transfer, heat transfer, lcsh:Electronics, Barrel (horology), Mechanical engineering, lcsh:TK7800-8360, lcsh:TP155-156, Cover (algebra), General Medicine, lcsh:Chemical engineering, Geology, mechanics, anti-aircraft gun barrel cover

Abstract

This paper presents the results of numerical simulations of non-stationary heat transfer in a 35 mm anti-air gun barrel cover made of composite materials. The cover protects the gun against weather conditions, including sea water effects, and serves as a protection against mechanical damage. It was assumed that heat coercion in this problem will be the heat condition reached by the material of the barrel with the cover removed, after firing three bursts of 7 shells each, 120 s after opening fire. It was assumed, that in the second 120, the gun crew installs the gun cover and at this point, the heating process begins, followed by cooling of the cover material. The problem of initial and boundary value in the barrel with a cover installed system was solved as a three-dimensional initial and boundary problem. The initial and boundary value model adopted for the coverless barrel and the calculation results for the first burst of seven shells was presented in paper [7]. To obtain the heat condition of the barrel in the second 120, it was necessary to perform calculations for the second and third bursts, and for the barrel cooling processes starting in the second 120. The calculations were performed with a finite element method in the COSMOS/M software [9]. The cover material temperature values obtained during the numerical simulation are well below the temperature of 387K, which could form the upper limit of the composite applicability temperature range.

Published

2018

37. Comparative Analysis of the Effects of Gunpowder and Plasma Ignition in Closed Vessel Tests

Author

Zbigniew Leciejewski, Jakub Michalski, Radosław Trębiński, and Zbigniew Surma

Subjects

Propellant, Materials science, Gunpowder, Mechanical Engineering, Plasma ignition, Metals and Alloys, Computational Mechanics, Plasma jet, Mechanics, law.invention, Ignition system, Military Science, Physics::Plasma Physics, law, Combustion process, Phase (matter), Ceramics and Composites, Physics::Chemical Physics

Abstract

This paper presents the results of a comparative investigation into the effects of the ignition method on the ballistic properties of a single-base gun propellant, as determined via closed vessel tests. Conventional gunpowder ignition and plasma jet ignition methods were used, and differences in the ignition time were analysed. The influence of the ignition method on the dynamic vivacity is discussed. It is shown that this influence is significant in the first phase of the combustion process, and with respect to the low values of the loading density. In the second phase of the combustion process, and for large values of the loading density, the dynamic vivacity plots for the two ignition methods converge. Regarding the burning law, close values of the exponent were obtained for the two ignition methods. The dynamic vivacity plots determined for plasma ignition reveal stronger dependence on the loading density than those determined for gunpowder ignition. The conclusion is that plasma ignition is not a solution to the problems inherent to the process of determining the ballistic properties of propellants, which results in deviation of the burning process from the geometric burning law. Keywords: Closed vessel test, Gun propellant, Gunpowder ignition, Plasma ignition

Published

2019

38. CONCEPT OF MAGNETO-HYDRODYNAMIC PLASMA IGNITER FOR IGNITION OF LOW VULNERABILITY GUN PROPELLANTS

Author

Cezary Pochrybniak, Zbigniew Leciejewski, Andrzej Horodenski, Zbigniew Surma, Kamil Namyślak, and Jakub Michalski

Subjects

Propellant, Ignition system, Materials science, Physics::Plasma Physics, law, Physics::Space Physics, General Medicine, Plasma, Mechanics, Magneto hydrodynamic, Vulnerability (computing), law.invention

Abstract

A concept of plasma coaxial magneto-hydrodynamic igniter for low sensitivity propelling materials is presented with initial experimental results. The concept is an interesting alternative for igniters generating the plasma by a blasting wire such as CPG (Capillary Plasma Generator) systems which have been recently investigated in many worldwide laboratories.

Published

2017

39. PYROSTATIC TESTS OF JA-2 TYPE POWDER

Author

Radosław Trębiński, Zbigniew Surma, Zbigniew Leciejewski, and Bartosz Fikus

Subjects

Materials science, General Medicine

Abstract

Literature data concerning ballistic properties of JA-2 powders was studied. The data was compared with results of own tests received for powder LO5460 manufactured by Nitrochemie AG. Pyrostatic tests were carried out in the manometric chamber having the volume of 200 cm3. The force of the powder and the co-volume of powder gases were measured. The influence of thermal losses into these parameters was evaluated by using a methodology proposed by the authors. Exponent value in the powder burning law and curves of dynamical liveliness of the powder were established. The curves actually overlap what shows the adequacy of the physical law of burning. It was proved that the ignition of tested powder takes place prior the complete burning of an igniting charge. It was taken into account at modification of the method for establishing the dynamic liveliness. Exploiting results of measurements for powder grains geometry and the curves of dynamical liveliness a coefficient of linear burning velocity was established. A good compliance with literature data was achieved for the dependence of linear burning rate on the pressure. It was proved that the geometrical burning law is adequate with the description of tested powder burning for changes of relative volume of burned powder above 0.2.

Published

2017

40. Preliminary Study of New Propellants Containing Guanidinium or Triaminoguanidinium Azotetrazolate

Author

Leszek Szymańczyk, Mateusz Szala, Marcin Hara, and Zbigniew Surma

Subjects

Propellant, animal structures, Materials science, 010304 chemical physics, Dibutyl phthalate, musculoskeletal, neural, and ocular physiology, General Chemical Engineering, technology, industry, and agriculture, Plasticizer, macromolecular substances, 02 engineering and technology, General Chemistry, 021001 nanoscience & nanotechnology, 01 natural sciences, body regions, chemistry.chemical_compound, chemistry, Friction sensitivity, 0103 physical sciences, Polymer chemistry, 0210 nano-technology, Nitrocellulose, Maximum pressure, Nuclear chemistry

Abstract

Guanidinium and triaminoguanidinium azotetrazolate (GUAZ, TAGAZ) were used as high-nitrogen compounds for the preparation of new propellants bound with nitrocellulose and plasticized with dibutyl phthalate and 3-methyl-3-nitroxymethyloxetane. The new propellant compositions were tested by using a differential thermal analysis-thermogravimetric technique, friction sensitivity and impact were ascertained and pyrostatic tests were conducted. Regardless of the amount of TAGAZ and plasticizer type, the propellants exhibit similar maximum pressure of the gases which allow for the replacement of NC in propellants by TAGAZ.

Published

2017

41. Numerical Analysis of the Effects of the Geometric and Weight Parameters on the Exterior Ballistics of a Designed Counterprojectile

Author

Zbigniew Surma, Marta Czyżewska, and Jakub Michalski

Subjects

Classical mechanics, numerical analysis, Numerical analysis, exterior ballistics, lcsh:Electronics, Ballistics, lcsh:TK7800-8360, lcsh:TP155-156, General Medicine, lcsh:Chemical engineering, mechanics, Mathematics

Abstract

This paper presents a selection of deliverables of a research project intended to develop a technology demonstrator for an active protection system smart counterprojectile. Numerical simulations were completed to analyse the effects of geometry and weight of the counterprojectile warhead on the counterprojectile flight (motion) parameters. This paper investigates four variants of the counterprojectile warhead shape and three variants of the counterprojectile warhead weight. Given the investigated geometric and weight variants, the PRODAS software environment was used to develop geometric models of the counterprojectile warhead, followed by the determination of the model aerodynamic characteristics. The final deliverable of this work are the results of the numerical simulation of the counterprojectile motion along the initial flight path length. Given the required activation of the active protection system in direct proximity of the protected object, the analyses of counterprojectile motion parameters were restricted to a distance of ten-odd metres from the counterprojectile launching system.

Published

2017

42. Experimental Investigations of Motion of Slide of Selected Pistol Types

Author

Radosław Trębiński, Bartosz Fikus, Wojciech Koperski, Paweł Płatek, and Zbigniew Surma

Subjects

experimental investigations, Classical mechanics, pistol slide motion, lcsh:Electronics, lcsh:TK7800-8360, lcsh:TP155-156, fast camera measurements, General Medicine, lcsh:Chemical engineering, mechanics, Motion (physics), Geology

Abstract

In the presented paper, kinematic characteristics of movable parts of investigated pistols have been experimentally determined with application of high speed camera and appropriate software TEMA motion. Results of measurements can be useful in validation of various theoretical models and can reveal the influence of some technical solutions on parameters of motion of selected parts. Obtained curves presenting dependence of slide velocity versus time, allowed for rough estimation of average value of interaction force between slide and frame of the investigated construction. The results of study highlights advantage of HK USP pistol design. The achieved results are from reduction of the value of the mentioned interaction force (approximately 50%) due to elongation of the most intensive phase of slide motion damping process.

Published

2016

43. Modelling and Verification of Solid Propellant Rocket Motor Operation

Author

Zbigniew Leciejewski, Krzysztof Motyl, Zbigniew Surma, Tomasz Rasztabiga, and Bogdan Zygmunt

Subjects

Propellant, 020301 aerospace & aeronautics, Materials science, business.industry, Organic Chemistry, 02 engineering and technology, Rocket motor, 01 natural sciences, 010305 fluids & plasmas, 0203 mechanical engineering, 0103 physical sciences, Materials Chemistry, Aerospace engineering, business

Published

2016

44. Experimental study of hybrid soft ballistic structures

Author

Tadeusz Niezgoda, Zbigniew Surma, Roman Gieleta, Andrzej Morka, and Piotr Kędzierski

Subjects

Materials science, business.industry, Projectile, 02 engineering and technology, Structural engineering, Impulse (physics), 021001 nanoscience & nanotechnology, Body armor, 020303 mechanical engineering & transports, 0203 mechanical engineering, Woven fabric, Ceramics and Composites, Composite material, 0210 nano-technology, business, Civil and Structural Engineering

Abstract

This paper presents studies on perforation and trauma resistance of hybrid soft structures. A selection of hybrid configurations were tested experimentally with a 7.62 × 25 mm Tokarev projectile. Hybrid packages included a wide range of textiles used for personal protection from laminates through plain-woven and multiaxial fabrics to felt. Their effectiveness was evaluated by reference to homogenous packages. The conducted examination demonstrated that hybrid packages employing stiff anti-trauma liners can reduce backface deformation by about 10% compared to homogenous packages. However, too many stiff layers deteriorates perforation resistance by shortening the distance in which a projectile is arrested. Utilization of felt material has a positive effect on trauma and perforation resistance. Soft layers with substantial thickness decrease impulse force and allow projectiles to be stopped over a longer distance. Hybrid packages with felt material have one major drawback in that they are a few times thicker than the other structures tested. An optimal compromise between ballistic performance and thickness is provided by panels based on unidirectional laminates combined with felt and stiff anti-trauma layers. Coupling of plain woven fabric and unidirectional laminate was found to be less efficient than packages entirely made of unidirectional laminate.

Published

2016

45. Laboratory Investigations on Perforation of 30PM Steel Plates

Author

Bartosz Fikus, Jacek Janiszewski, Zbigniew Surma, Djalel Eddine Tria, and Michał Grązka

Subjects

Materials science, laboratory experiments, Metallurgy, Perforation (oil well), lcsh:Electronics, lcsh:TK7800-8360, lcsh:TP155-156, General Medicine, hard armor steel, Steel plates, perforation, Composite material, lcsh:Chemical engineering, mechanics

Abstract

In this study, high strength steel plates made of 30PM steel were subjected to 7.62 Armour Piercing projectiles at the ordnance velocity. Several experiments differing considerably in conditions of interaction between projectiles and plates were performed. Selected parameters were measured before, during, and after ballistic tests, and both projectile and plate were subjected to detailed examination. It is foreseen to use the obtained results in two ways. Protection performance of steel plates will be determined and experimental data will be used as a reference for analyzing various models and numerical techniques, accessible in commercially available hydrocodes. The authors present the methodology, the experimental set-up configuration, and the results of laboratory experiments.

Published

2016

46. Numerical modeling of the large strain problem in the case of mushrooming projectiles

Author

Piotr Kędzierski, Sebastian Stanisławek, Zbigniew Surma, and Andrzej Morka

Subjects

Projectile, Computer science, Mechanical Engineering, Aerospace Engineering, Numerical modeling, Experimental data, CPU time, Ocean Engineering, Finite element method, Mechanics of Materials, Automotive Engineering, Large strain, Range (statistics), Predictability, Safety, Risk, Reliability and Quality, Simulation, Civil and Structural Engineering

Abstract

The paper investigates the capabilities and limitations of five different numerical approaches to the modeling of large strains of mushrooming projectiles on the example of a 9 mm Parabellum. The studies included the following methods: FEM, FEM-Remeshing, ALE-Smoothing, ALE-Euler and SPH. The results of computer simulations are summarized and confronted with experimental data for reduced and nominal impact velocity. The selected methods are compared in terms of predictability, credibility of results, range of application and computational effectiveness. Additionally, practical guidelines for simulation of the soft-core projectile impact problem are given. The most realistic results were registered for the ALE–Euler model, but this incurred the considerable computational cost. FEM is suggested for simulation of projectile impact with reduced velocity as it takes the least CPU time. Selection of other methods should be based on maximum impact velocity and the available computer resources.

Published

2020

47. Factors Determining Nature of Dynamic Vivacity Curve During Closed Vessel Investigations

Author

Zbigniew Leciejewski, Zbigniew Surma, and Pawel Zuk

Subjects

Propellant, Physics::Biological Physics, animal structures, Materials science, musculoskeletal, neural, and ocular physiology, technology, industry, and agriculture, macromolecular substances, Mechanics, Quantitative Biology::Cell Behavior, law.invention, body regions, Ignition system, law, Physics::Chemical Physics, Combustion chamber

Abstract

It is assumed that the mechanism of gun propellant gases production is dependent on the knowledge of propellant grains geometry and adoption of a geometric model of propellant grains burning. In the paper, the authors analyse the influence of arrangement of propellant grains in a combustion chamber on the changes of dynamic vivacity. The grains of the propellant charge have been piled up spontaneously at the bottom of a combustion chamber or have been spaced separately, systematically on the whole circuit of a combustion chamber. The investigations were carried out with application of black powder ignition and gas ignition for the same loading density. The results of closed vessel investigations showed that the character of dynamic vivacity is determined not only by geometry of propellant grains but also by the conditions of heat transport between hot ignition gases and available burning surface of propellant grains.

Published

2017

48. Ballistic resistance tests of multi-layer protective panels

Author

Jan Godzimirski, Marek Rośkowicz, Jacek Janiszewski, and Zbigniew Surma

Subjects

Engineering, business.industry, Structural engineering, Safety, Risk, Reliability and Quality, business, Ballistic resistance, Multi layer, Industrial and Manufacturing Engineering

Published

2015

49. Effect of application of various ignition conditions in closed-vessel tests on burning rate calculation of a fine-grained propellant

Author

Zbigniew Surma and Zbigniew Leciejewski

Subjects

Propellant, Work (thermodynamics), animal structures, Materials science, General Chemical Engineering, technology, industry, and agriculture, General Physics and Astronomy, Energy Engineering and Power Technology, General Chemistry, Mechanics, Closed chamber, Combustion, law.invention, Ignition system, Burn rate (chemistry), Fuel Technology, law, Time profile

Abstract

The most widely used experimental method for determination of dynamic characteristics of gun propellant combustion is burning a specific amount of a propellant in a closed chamber (vessel) and measuring the resulting pressure versus time profile. The aim of this work is to conduct experimental investigations at different conditions of propellant ignition, which permit to verify the view on legitimacy of standard conditions of closed-vessel tests. This paper considers first of all the influence of conditions of propellant ignition during closed-vessel tests on possible deviations in determination of the burning rate. For this purpose, experimental tests of a fine-grained, single-base propellant are carried out in a conventional closed vessel and a micro-closed vessel, applying different ignition methods for the same loading density. The results of experimental tests and calculations show significant influence of the ignition system type used on determined values of the burning rate and other dynamic characteristics of propellant combustion, such as dynamic vivacity, absolute quickness, and relative quickness.

Published

2011