| 英文摘要 | New lightweight composite materials/structures
with excellent load bearing andimpact resistance energy absorption properties are essential for engineeringapplications in different fields. Natural biological materials in nature with theingenious macro/micro configuration collocation, the overall mate rial/structure shows
extraordinary bearing performance and the ability to resist the impact of foreign objects, providing inspiration for the design of new structures. U nderstanding and mastering the mechanism of interaction between macro/micro configurati ons of biomaterials can provide bionic examples for structural design, optimization, and performance improvement of key components in different industries. Based on the performance requirements of key components in actual service conditions, this paper
has innovatively designed and prepared a variety of bionic structures with outstanding bearing and impact resistance by referring to the macro and micro structural characteristics of biological materials and combining with 3D printing technology. By means of quasi static mechanical properties test, pendulum impact experiment and simulation, the improvement of mechanical properties and impact energy absorption
between the new bionic structure and the traditional structure was compared, and the mechanism of macr o and micro structure design to improve the overall mechanical properties of the structure was discussed, which could provide reference for the innovative design of new composite materials/structures. The main work and conclusion of this paper are summariz ed as follows: (1) Non pneumatic tires with traditional tires do not have the advantages of anti strapping, explosion proof, in civil, military and heavy industry fields show a broad application prospect. The vertical bearing capacity of the mature Tweel tire is weaker than that of the honeycomb tire, and the vertical bearing capacity of the
innovative Kuc, interconnected mesh tire and g rid type tire s designed by researchers is limited compared with that of the honeycomb tire. And the current situation whe reless attention has been paid to the high speed rolling characteristics of new structural tires during actual service. In Chapter 2, a Tweel 2 tire was designed by adding
circumferential element constraints to the plate spokes of Tweel tires Drawing on the
advantages of deformation and energy absorption of the flexible saddle structure in
the forelimb of the mantis shrimp, a new type of saddle structure tire was designed
using a hyperbolic paraboloid structure. The static load performance and dynamic
roll ing characteristics of honeycomb, Tweel, Tweel 2 and saddle tire were studied by
3D printing technology, quasi static compression experiment, quasi static and
dynamic simulation. Referring to the evaluation indicators for the bearing
performance of porous structures, as well as the parameters such as the maximum
Mises stress, maximum tread contact pressure, vertical load, and vertical deformation
新型仿生结构设计及静动态力学性能分析
IV
stability during dynamic rolling of tires, the differences in the vertical bearing
stability during dynamic rolling of tires, the differences in the vertical bearing performance, deformation enerperformance, deformation energy absorption performance, and dynamic rolling gy absorption performance, and dynamic rolling characteristics of four groups of structural tires were compared. The experimental and characteristics of four groups of structural tires were compared. The experimental and simulation results show that Tweelsimulation results show that Tweel--2 improves the yield strength, platform stress and 2 improves the yield strength, platform stress and absorbed energy by more than 40%, anabsorbed energy by more than 40%, and reduces the maximum contact pressure of the d reduces the maximum contact pressure of the outer tread by 50%. The yield strength, platform stress and absorbed energy of saddle outer tread by 50%. The yield strength, platform stress and absorbed energy of saddle tire are about 2.4 times that of honeycomb structure, and even more than 4 times that tire are about 2.4 times that of honeycomb structure, and even more than 4 times that of Tweel tire. In addition, the verticof Tweel tire. In addition, the vertical load and vertical deformation stability al load and vertical deformation stability performance of saddle tire are much higher than that of other nonperformance of saddle tire are much higher than that of other non--inflatable structure inflatable structure tires during rolling at different speeds.tires during rolling at different speeds.
(2) In order to solve the problems of simple structure, heavy material, high In order to solve the problems of simple structure, heavy material, high construconstruction cost and low energy absorption effect of traditional protective armor, the ction cost and low energy absorption effect of traditional protective armor, the Chapter Chapter 33 designs the gradient interlocking and bidirectional interlocking brickdesigns the gradient interlocking and bidirectional interlocking brick--mud mud structures by reference to the brickstructures by reference to the brick--mud microstructure of mother of pearl and conch mud microstructure of mother of pearl and conch shellshell, the gradient cellular microstructure of bamboo and deer horn, and the , the gradient cellular microstructure of bamboo and deer horn, and the mesomeso--interlocking structure of beetle shell interface. Enhance the overall ability of interlocking structure of beetle shell interface. Enhance the overall ability of material to resist external impact.material to resist external impact. Pendulum impact experiment results show that the Pendulum impact experiment results show that the larger the celarger the cell size gradient is, the higher the energy absorption of gradient ll size gradient is, the higher the energy absorption of gradient interlocking brickinterlocking brick--mud structure is. The smaller the number of elliptic cells in mud structure is. The smaller the number of elliptic cells in interlocking region, the higher the energy absorption of bidirectional interlocking interlocking region, the higher the energy absorption of bidirectional interlocking brickbrick--mud structure. The mud structure. The energy absorption of the two new interlocking brickenergy absorption of the two new interlocking brick--mud mud structures during the impact process can be up to 6.2 times and 2.5 times of the structures during the impact process can be up to 6.2 times and 2.5 times of the uniform motheruniform mother--pearl brickpearl brick--mud structure. The mechanism of energy absorption mud structure. The mechanism of energy absorption performance improvement of interlocking stperformance improvement of interlocking structures was studied by using finite ructures was studied by using finite element simulation method, that is, gradient interlocking design can significantly element simulation method, that is, gradient interlocking design can significantly improve the stress distribution and deformation coordination in the impact area, improve the stress distribution and deformation coordination in the impact area, effectively avoid the excessive stress level in the loceffectively avoid the excessive stress level in the local area, delay the process of al area, delay the process of structural failure. The bidirectional interlock design can increase the number of cracks structural failure. The bidirectional interlock design can increase the number of cracks and the degree of deflection in the fracture area, thus increasing the energy and the degree of deflection in the fracture area, thus increasing the energy dissipation.dissipation.
(3) The traditional thinThe traditional thin--wall energy absorptiowall energy absorption device has a single section n device has a single section configuration, so it is difficult to meet the requirements of high efficiency of energy configuration, so it is difficult to meet the requirements of high efficiency of energy absorption and controllable mode of crushing deformation in the actual service absorption and controllable mode of crushing deformation in the actual service process, and the direction of external impact load is oftenprocess, and the direction of external impact load is often uncertain. Therefore, the uncertain. Therefore, the traditional thintraditional thin--wall energy absorber has higher requirements for crashworthiness at wall energy absorber has higher requirements for crashworthiness at different angles.different angles. In Chapter 4, based on the configuration characteristics of transverse In Chapter 4, based on the configuration characteristics of transverse and longitudinal sections of natural hedgehog spines, tand longitudinal sections of natural hedgehog spines, the thinhe thin--wall structure of the wall structure of the bulkheadbulkhead hedgehog spines was designed. Combined with 3D metal printing, hedgehog spines was designed. Combined with 3D metal printing, quasiquasi--static compression test and finite element impact simulation, the dynamic static compression test and finite element impact simulation, the dynamic behavior of the thinbehavior of the thin--wall structure during axial and oblique impact comprewall structure during axial and oblique impact compression was ssion was studied. The results show that under axial impact, the energy absorption ratio of the
studied. The results show that under axial impact, the energy absorption ratio of the thinthin--wall structurewall structure of the bulkhead hedgehog spineof the bulkhead hedgehog spine is 4.0, 2.2 and 1.3 times that of the is 4.0, 2.2 and 1.3 times that of the singlesingle--wall cylinder, spider wewall cylinder, spider web and simplified hedgehog spineb and simplified hedgehog spine, respect, respectively. Under ively. Under oblique impact, the oblique impact, the energy absorption ratio ofenergy absorption ratio of bulkhead hedgehog spinebulkhead hedgehog spine is is 4.1, 1.9 and 4.1, 1.9 and 1.5 times1.5 times at most thatat most that of of the other three structures, respectively. In addition, under the other three structures, respectively. In addition, under axial and oblique impact, the average crushing load of the thinaxial and oblique impact, the average crushing load of the thin--wall wall structure of the structure of the bulkheadbulkhead hedgehog spine is greatly increased, and thus a high and stable crushing hedgehog spine is greatly increased, and thus a high and stable crushing load efficiency is obtained. The finite element simulation results show that, different load efficiency is obtained. The finite element simulation results show that, different from the deformation failure modes of the other three structures, thefrom the deformation failure modes of the other three structures, the lateral expansion lateral expansion of the thinof the thin--wall structure under axial impact is more uniform, and the overall buckling wall structure under axial impact is more uniform, and the overall buckling deformation occurs under oblique impact, showing better deformation coordination. deformation occurs under oblique impact, showing better deformation coordination. More materials participate in the bearing deformation and store morMore materials participate in the bearing deformation and store more energy during e energy during the impact process, thus significantly improving the axial and oblique the impact process, thus significantly improving the axial and oblique crashcrash--resistance.resistance.
(4) With the rapid development of vehicle motorization, the incidence of head With the rapid development of vehicle motorization, the incidence of head injury caused by impact accidents is increasing, which puts forward higheinjury caused by impact accidents is increasing, which puts forward higher r requirements for the development of head protection devices with light weight, high requirements for the development of head protection devices with light weight, high strength and high impact resistance and energy absorption performance.strength and high impact resistance and energy absorption performance. The The Chapter Chapter 55 uses the durian shell coneuses the durian shell cone--spine structure and mantis shrimp's skimpspine structure and mantis shrimp's skimp--foot foot bibi--directiodirectional corrugated structure for reference to design the bionic structure of the nal corrugated structure for reference to design the bionic structure of the helmet's liner component which plays the main role of energy absorption. Through helmet's liner component which plays the main role of energy absorption. Through geometric parameter optimization, the bidirectional staggered pyramid structure geometric parameter optimization, the bidirectional staggered pyramid structure gasket was designegasket was designed step by step, and the impact resistance of the gasket was d step by step, and the impact resistance of the gasket was compared with the classical honeycomb structure and the gradient lattice bionic compared with the classical honeycomb structure and the gradient lattice bionic structure gasket in the existing literature. Based on the simulation results of structure gasket in the existing literature. Based on the simulation results of configuration evolution and energy dconfiguration evolution and energy distribution in the impact process, it can be seen istribution in the impact process, it can be seen that the bidirectional staggethat the bidirectional staggered tetrapyramidal cell designred tetrapyramidal cell design effectively improves the effectively improves the deformation coordination of the structure, and makes the deformation area of the liner deformation coordination of the structure, and makes the deformation area of the liner structure in the impact process lastructure in the impact process larger, the distribution range of high strain energy rger, the distribution range of high strain energy wider, and more materials involved in bearing and deformation energy storage. Thus, wider, and more materials involved in bearing and deformation energy storage. Thus, the energy absorption performance of the new bionic structure gasket is greatly the energy absorption performance of the new bionic structure gasket is greatly improved, and the energy absorption ratioimproved, and the energy absorption ratio of the bidirectional staggered quadpyramid of the bidirectional staggered quadpyramid structure helmet is 1.3 times and 2.7 times of that of the honeycomb structure and the structure helmet is 1.3 times and 2.7 times of that of the honeycomb structure and the gradient lattice structure, respectively.gradient |
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