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NFX|迫击炮Mortar 底板分析

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Abstract

   Due to the high costs associated with the purchase of ammunition and firing in certified training ground cen-ters, tests of retaining plate deformations are increasingly replaced by computer simulations using numerical models. Computer programs usually use a single-parameter subsoil model (Winkler-Zimmermann) for calcu-lations, which requires providing the subgrade susceptibility coefficient. The subgrade compliance coefficient is intended to determine the mutual reaction of the subgrade and the structure due to the pressure exerted on the soil by the retaining slab, which settles. When designing slabs in computer programs, it is assumed that the substrate compliance coefficient is constant. Determining the impact of the soil on the retaining slab is important when analyzing its deformations. The subject of the work was the analysis of the influence of ground support on the results obtained during modeling of the retaining slab. In order to obtain data for FEM analysis and validation, the actual strains occurring on the thrust plate were measured using strain gauge ro-settes. The plate deformations were measured during field shooting tests. In order to vary the influence of supporting the slab on the ground and obtain reliable stress values on the slab surface, a method of successive iterations was proposed. Calculations are performed using this method until the error is smaller than the as-sumed one.

Keywords: 

mortar base plate, strain measurement, finite element method

1. Introduction

   When measuring the value of strains (stresses) during field shooting tests, the high costs associat-ed with purchasing ammunition and carrying out such tests in a certified research center should be taken into account. The data obtained from real measurements are the most reliable, but the develop-ment of technology and economic considerations are increasingly reduced to performing computer simulations on computational models.

    The issues of interaction between the mortar base plate and the ground are not widely described in world literature. The first and at the same time the most frequently used measurement method is the measurement of deformation using strain gauges (Szwajka et al., 2022). The main emphasis in re-search is on the analysis of the stress and strength of the mortar itself (Bartnik et al., 2021, Zhang et al., 2016). The quality requirements for mortars stipulate the possibility of firing from them after plac-ing on grounds with a wide range of properties. Any proper interaction of the mortar and the terrain is largely dependent on the latter’s deformation modulus (Gomez & Spencer, 2019; Lee & Park, 2015).

    The main assumption of Finite Element Method (FEM) is the discretization of a continuous geo-metric model by dividing it into a finite number of elements connecting at nodes. The effect of this division is also the transformation of a system with an infinite number of degrees of freedom into a form with a specific number of degrees of freedom (Kleiber, 1989). In the case of calculations using FEM, all other physical quantities operating in the system in the form of continuous functions, such as loads, restraints, displacements and stresses, are also discretized. The result of discretization of a spe-cific physical quantity is the pursuit of a maximum approximation of its discrete and continuous form through the use of approximation methods (Dacko et al., 1994). The complexity of the finite element method and its approximate nature place significant demands on the software user. A necessary condi-tion for obtaining correct results is to define the appropriate computational model based on the speci-ficity and fundamentals of finite elements (Kacprzyk et al., 2011). The basic advantages of using FEM software include undertaking increasingly complex designs and analyzes of structures for which ana-lytical solutions are not available, and easy consideration of many variants of loads, boundary condi-tions, types of materials, and shapes of individual parts. Moreover, FEM programs enable automatic data conversion, preventing possible errors or time-consuming calculations, and creating reports on the analyzes performed (Anitescu et al., 2019; Bielski, 2010). The thematic reference to the characterized finite element method are publications by Wang (2019) and Wang et al. (2020), in which the computa-tional models are mortar retaining slabs. The final effect of design optimization is the ability to make boards from light composite layers.

    Another example of the use of FEM on a computational model in the form of a mortar thrust plate is the work (Ristić et al., 2009), in which the Pro/Engineer Wildfire software was used. Based on the simulations performed, the stresses occurring on the retaining plate of a 120 mm mortar were analyzed for soft, medium and hard ground. In this work, an attempt was made to compare the simulation with real measurements, however, the insufficiently well-prepared strain gauge installation and its location provided rudimentary results from shooting tests.

    The work (Wang & Yang, 2021) presents a topographic design of the retaining plate of a 120 mm mortar based on the finite element method. The model of a trapezoidal-pyramidal plate was subjected to optimization of the dynamic topology of its continuous structure based on the results obtained from laboratory tests. For this purpose, a station was created enabling the impact load on the thrust plate to be applied and this force to be measured. The results obtained from the analyzes provided the basis for optimizing the original model.

    The issue of the interaction of the mortar retaining plate with the ground is not widely described in world literature. The main emphasis in the research is placed on the analysis of stresses and strength of the mortar itself. Therefore, the study presents a comparison of the stresses on the mortar retaining plate obtained during the tests carried out using strain gauge measurements with the stress results ob-tained using FEM. A function was assumed that determines the influence of the elastic substrate on the deformations of the retaining plate. The research is complemented by the results of calculations of the plate model using the finite element method in the MIDAS program. Problems related to the coopera-tion of the ground and the structures resting on it are an important aspect of strength analysis. There is no detailed research in the literature regarding, among others, deformations of retaining plates on an elastic base. As previously mentioned, a very important issue in the FEM analysis of plates is their interaction with the substrate on which they rest, which are loaded not only with static, but above all dynamic forces.

    Due to the specific nature of military products with closely guarded design solutions, the litera-ture review in the area of stress measurement methods and computer simulations in relation to testing mortar thrust plates is significantly limited. Based on the literature, the concept of the work undertaken was to find effective methods to replace the firing of a retaining plate in laboratory conditions and to reduce the costs associated with shooting tests. Due to the lack of correlation between the actual de-formations occurring on the retaining plate during the shot and numerical simulations on the computa-tional model of the plate, this work was undertaken to analyze the state of stress and compare the val-ues obtained from strain measurements and as a result of strength analyzes carried out using the finite elements.

2. Material and methods

2.1. Mortar base plate

     The subject of the research was the retaining plate of a 98 mm mortar used to support the mortar barrel and to slow down the recoil during firing by transferring energy to the ground. It was made of heat-treated 30HGSA steel. 30HGSA steel is characterized by high hardenability, strength and wear resistance. Due to the decrease in strength properties after exceeding a certain thickness, it is used to produce elements up to 60 mm. It is steel intended for heat treatment consisting of hardening and tem-pering. After thermal improvement, it obtains excellent strength parameters, while maintaining opti-mal other properties. Steel is used primarily for highly loaded machine parts and heavy structures sub-ject to heavy loads. Table 1 lists its mechanical properties. The resistance plate used in the research is part of the equipment of soldiers. We had no influence on its shape.

   The technology for making the retaining plate was cold-formed sheet metal, 5 mm thick, in the shape of a circle with stiffening embossments. The sheet is then connected to the ball socket, reinforc-ing ribs and plates as well as stiffening and transport elements by welding with 3.5 mm thick fillet welds. After welding, the plate was heat treated. Figure 1 shows the retaining plate of a 98 mm mortar from both sides.

2.2. Experiment procedure

     During the firing range tests, the deformations occurring on the thrust plate and the pressure of the gunpowder gases in the mortar barrel were measured. The firing was conducted from the ground at a barrel elevation angle of 45⁰ with smoke projectiles on reinforced propellant charges (Fig. 2).

   Ten strain gauge rosettes were used to measure deformations on the thrust plate during firing from a 98 mm mortar, allowing measurement in three directions: 0°, 45° and 90°. Strain gauge rosettes were placed on the supporting plate in such a way as to enable obtaining as much data as possible re-garding the loads acting on various areas of the supporting plate during the shot. Preliminary shooting tests (in the form of pilot tests) showed that the greatest loads on the plate occur in its lower area, and the smallest in the upper area. A symmetrical stress distribution in the vertical system was also ob-served, on the basis of which the arrangement of strain gauge rosettes on the retaining plate was de-termined, graphically shown in Fig. 3.

   The strain gauge installation was made on the outside of the thrust plate, due to the direction of the shot force, but also due to the impossibility of securing the strain gauges if they were mounted on the side in contact with the ground. The installation consisted of 10 KYOWA rosettes, type KFGS-10-120-D17-11 L3M3S, glued using CC-33A glue from KYOWA. The frequency response of the strain gauge rosettes was 1200 Hz. The signals were recorded at a frequency of 19,200 Hz using an HBM amplifier – QuantumX MX1615B model and dedicated HBM computer software. Then, the signals were filtered to remove interference. The strain gauge rosettes used for the measurement worked in a Wheatstone quarter-bridge. Along with recording the deformations, a measurement of the pressure of the gunpowder gases was carried out in parallel, synchronized in an identical time interval using the Piezotronics 482C PCB signal conditioner. Figure 4 shows a diagram of the measurement track used during the firing range tests.

3. Results and discussion

   During firing, the maximum deformation values were measured on the retaining plate of the 98 mm mortar using ten strain gauge rosettes, and the pressure of the powder gases in the mortar barrel was measured using a piezoelectric sensor. Examples of the recorded maximum signals for the R1 rosette are shown in Fig. 5a, while the pressure course over time is shown in Fig. 5b.

    When conducting strength analyses, the measurement results were reduced to reduced stresses in accordance with the Huber-Mises-Hencky (H-M-H) hypothesis. In the calculation program, the stress-es for individual directions were converted into reduced stresses using the Von Mises module. Below is an iterative summary of the results obtained in three subsequent analyses, which allowed to obtain the correct final result of the analyses. The elements used to represent the stiffness of the soil were Bush elements. These are elements that are characterized by elasticity and damping. In the calcula-tions, they were used as elements whose dominant component is stiffness. There is a node at each end of the bush element (this is a 1D element). One of the nodes is adjacent to the surface of the elements from which the numerical model of the plate is built. The second node is automatically supported.

    The next stage was to determine the estimated values of soil stiffness, which will be expressed in N/mm. Converting the stiffness into these units is necessary because it is in them that the stiffness is defined in the midas NFX calculation program. An axisymmetric model was prepared for this task. By assigning material parameters (Young's modulus, Poisson's ratio) determined from standard PN-81 B-03020 that describe various types of soil, a model was created into which a triangular indenter was pressed, which was supposed to approximately reproduce the shape of the plate (test this, to a large extent, looked like a microhardness test). Then, after applying the assumed force to the indenter, the indentation value was read. In this way, the stiffness parameter (N/mm) was obtained from the materi-al parameters. This allowed us to determine the approximate order of magnitude of the individual stiffnesses that the Bush-type elements that support the model should have.

     The initial assumption for modeling the structure of the mortar support plate in the numerical model in iteration 1 included the full support of the plate on the ground, both surface and edge parts, with constant soil stiffness conditions. Below is a summary of the stiffness of spring elements repre-senting elastic support conditions:

stiffness on surfaces 200N/mm,

stiffness at the edges 1400N/mm.

   envelopes of stress values in individual views for 2D shell elements for top and bottom sur-faces are shown in Figure 6.

    A comparison of the results of numerical analyzes and the results obtained during measurements at reference measurement points is shown in Fig. 7.

    The initial assumption for modeling the structure of the mortar support plate in the numerical model in iteration 2 included half of the support of the surface parts of the plate on the ground and full support of the edge parts of the plate on the ground, with constant soil stiffness conditions. Figure 8 presents a summary of the stiffness of spring elements representing elastic support conditions:

stiffness on surfaces 200N/mm

stiffness at the edges 1400N/mm

    A comparison of the results of numerical analyzes and the results obtained during measurements at reference measurement points is shown in Fig. 9.

     The initial assumption for modeling the structure of the mortar support plate in the numerical model in iteration 3 took into account only the medial area of the support of the surface parts of the plate on the ground and the full support of the edge parts of the plate on the ground, with constant soil stiffness conditions. Figure 10 presents a summary of the stiffness of spring elements representing elastic support conditions:

stiffness on surfaces 200 N/mm

stiffness at the edges 1400 N/mm

    A comparison of the results of numerical analyzes and the results obtained during measurements at reference measurement points is shown in Fig. 11.

4. Conclusions

   This study proposes a continuum base plate topology optimization problem under quality and en-gineering constraints. The modeling method used for the mortar base plate was proven to be accurate and feasible through test verifications. In this case, topology optimization was performed on the mor-tar base plate structure using a force transmission path based on base plate stress analysis. The base plate optimization model could meet the requirements of structural stiffness and strength, shooting stability and lightweight structure. Thus, this study provides a benchmark for performance improve-ment and structural optimization design of the base plate.

     The highest stress values were observed on the outer circumference of the mortar plate. This is due to the shape of the outer ring of the plate. It sinks into the ground and acts as a block to the move-ment of the mortar plate.

    The case of obtaining the results of individual analyzes was limited to the ground, which was fill sand and shot at an angle of 45°. The iterative comparison of the results obtained in three subsequent analyzes allowed to obtain the final effect of the analyses, allowing obtaining satisfactory results, con-sistent with the results obtained from strain gauge measurements. The process of obtaining the final results was an iterative process, which included many computational approaches with each change of the calculation assumptions, in particular the slab support conditions.

References

Anitescu, C., Atroshchenko, E., Alajlan, N., & Rabczuk, T. (2019). Artificial neural network methods for the solution of second order boundary value problems. Computers, Materials & Continua, 59(1), 345–359.

Bartnik, G., Józefiak, K., Superczyńska, M., Czerwińska, M., Krajewski, W., Legieć, J., Kuśnierz, T., Magier, M. (2021). The use of geotechnical methods to determine the deformation parameters of the ground in terms of operation and safety of mortar use. Materials, 14(23), Article 7237. https://doi.org/10.3390/ma14237237

Bielski, J. (2010). Introduction to engineering applications of the finite element method. The publishing house of the Krakow University of Technology.

Dacko, M, Borkowski, W, Dobrociński, S, Niezgoda, T., & Wieczorek, M. (1994). Finite element method in structural mechanics. Arkady.

Gomez, F., & Spencer, B. F. (2019). Topology optimization framework for structures subjected to stationary stochastic dynamic loads. Structural and Multidisciplinary Optimization, 59, 813–833. https://doi.org/10.1007/s00158-018-2103-3

Kacprzyk, Z., Maj, M., Pawłowska, B., & Sokół, T. (2011). Finite element method manual (2nd ed.). Warsaw University of Technology Publishing House.

Kleiber, M. (1989). Introduction to the finite element method. State Sci. Pub. House.

Lee, H. -A., & Park, G. -J. (2015). Nonlinear dynamic response topology optimization using the equivalent static loads method. Computer Methods in Applied Mechanics and Engineering, 283, 956–970. https://doi.org/10.1016/j.cma.2014.10.015

Ristić, Z., Kari, A., & Bajević, M. (2009). Dynamic analysis of the mortar base model using the Pro/engineer software package. Vojnotehnički Glasnik, 57(1), 81–89. http://dx.doi.org/10.5937/vojtehg0901081R

Szwajka, K., Szewczyk, M., & Trzepieciński, T. (2022). Experimental Compaction of a High-Silica Sand in Quasi-Static Conditions. Materials, 16(1), Article 28. https://doi.org/10.3390/ma16010028

Wang, X. (2019). Optimal design of a large caliber mortar base plate structure. Nanjing University of Technol-ogy.

Wang, F., Yang, G., Wang, D., Ge, J., Yu, Q., & Li, Z. (2020). Research on the test and lightweight design of a mortar base plate. Vibration and Shock, 39(17), 76–81. https://doi.org/10.13465/j.cnki.jvs.2020.17.011

Wang, F., & Yang, G. (2021). Topological design of a mortar base plate under impact loads. Shock and Vibra-tion, 2021(1), 1-13. https://doi.org/10.1155/2021/8845019

Zhang, X., Liu, S., Peng, K. et al. (2016). Topological optimization design for mortar’s base plate. Journal of Ordnance Equipment Engineering, 4, 33–35.

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来源:midas机械事业部
ACTACPMechanicalSystemDeform
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首次发布时间:2024-08-14
最近编辑:3月前
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