Your search keyword '"Peihao Song"' showing total 16 results

1. Spatial and Seasonal Variation and the Driving Mechanism of the Thermal Effects of Urban Park Green Spaces in Zhengzhou, China

Author

Yuan Feng, Kaihua Zhang, Ang Li, Yangyang Zhang, Kun Wang, Nan Guo, Ho Yi Wan, Xiaoyang Tan, Nalin Dong, Xin Xu, Ruizhen He, Bing Wang, Long Fan, Shidong Ge, and Peihao Song

Subjects

landscape metrics (LMs), land surface temperature (LST), urban ecology, urban parkland, vegetation characteristic index (VCI), urban heat island (UHI), Agriculture

Abstract

Greenscaping, a key sustainable practice, helps cities combat rising temperatures and climate change. Urban parks, a pivotal greenscaping element, mitigate the urban heat island (UHI) effect. In this study, we utilized high-resolution remote sensing imagery (GF-2 and Landsat 8, 9) and in situ measurements to analyze the seasonal thermal regulation of different park types in Zhengzhou, China. We calculated vegetation characteristic indices (VCIs) and landscape patterns (LMs) and employed boosted regression tree models to explore their relative contributions to land surface temperature (LST) across different seasons. Our findings revealed that urban parks lowered temperatures by 0.65 °C, 1.41 °C, and 2.84 °C in spring, summer, and autumn, respectively, but raised them by 1.92 °C in winter. Amusement parks, comprehensive parks, large parks, and water-themed parks had significantly lower LSTs. The VCI significantly influenced LST in autumn, with trees having a stronger cooling effect than shrubs. LMs showed a more prominent effect than VCIs on LST during spring, summer, and winter. Parks with longer perimeters, larger and more dispersed green patches, higher plant species richness, higher vegetation heights, and larger canopies were associated with more efficient thermal reduction in an urban setting. The novelty of this study lies in its detailed analysis of the seasonal thermal regulation effects of different types of urban parks, providing new insights for more effective urban greenspace planning and management. Our findings assist urban managers in mitigating the urban surface heat effect through more effective urban greenspace planning, vegetation community design, and maintenance, thereby enhancing cities’ potential resilience to climate change.

Published

2024

2. Coupled effects of land use and climate change on water supply in SSP–RCP scenarios: A case study of the Ganjiang River Basin, China

Author

Jia Tang, Peihao Song, Xijun Hu, Cunyou Chen, Baojing Wei, and Siwen Zhao

Subjects

CMIP6, Climate change, Ganjiang River Basin, Land use simulation, SSP–RCP scenario, Water supply changes, Ecology, QH540-549.5

Abstract

Coupling land use and climate change under shared socioeconomic pathway and representative concentration pathway (SSP–RCP) scenarios can provide more accurate predictions of water supply risks, thereby supporting decision-making for spatial planning with a focus on climate adaptation. Climate change exhibits spatial and temporal differences. To meet the requirements of spatial planning, further research is needed to assess water supply risks at different basin or regional scales. In this study, we selected four SSP–RCP scenarios for analysis, considering the temporal scale of spatial planning. The climate modeling capabilities of five global climate models (GCMs) and a multi-model ensemble (MME) were evaluated using a Taylor diagram, which assesses the performance of climate element simulations. The modeling framework that consisted of system dynamics (SD), patch-generating land-use simulations (PLUS), and Soil and Water Assessment Tool (SWAT) was employed to analyze synergistic changes in climate, land use, and water supply. The Ganjiang River Basin (GRB) serves as a case study for climate-adaptive planning at the basin scale, given its characteristics of high agricultural water demand and vulnerability to droughts and floods. The study aims to provide decision-making support for such planning. In our projections, precipitation in the GRB showed a slightly increasing trend from 2021 to 2050. Monthly precipitation increases during the flood season in August and decreases during the dry season from October to December. The maximum and minimum temperatures showed an increasing trend on both the yearly and monthly scales, with slightly higher increases during fall and winter. During the planning phase, the land use quantities of SSP126 and SSP245 showed similar variations. SSP370 experienced the most significant reduction in farmland, while SSP585 displayed a more scattered and punctuated layout of construction land. The annual water supply in the GRB showed a slightly decreasing trend from 2021 to 2035 and 2036–2050, and the largest reduction was found in SSP370. The trend of variation in the monthly water supply was complex. There was a consistent trend of decreasing water supply during the dry season, whereas the changes during the flood season were more complex. Seasonal variations in water supply are a major water security concern for the basin’s future. It is necessary to strengthen the agricultural water security planning in the northern region of the basin and enhance its ability to adapt to droughts and floods.

Published

2023

3. Mechanical response of four polycarbonates at a wide range of strain rates and temperatures

Author

Peihao Song, Akash R. Trivedi, and Clive R. Siviour

Subjects

Polycarbonates, Dynamic mechanical analysis, Tension, Compression, Rate- and temperature-dependence, Polymers and polymer manufacture, TP1080-1185

Abstract

Polycarbonate is widely used in engineering applications in which its mechanical properties need to be well understood over a wide range of strain rates and temperatures. These properties can be dependent on the molecular structure. In this research, the thermomechanical properties of three homo-polycarbonates with different melt flow rates, and a modified co-polycarbonate, were extensively characterized to produce a large dataset of mechanical properties based on consistent thermal histories. Dynamic Mechanical Analysis was performed to obtain modulus data from which time-temperature superposition master curves were constructed. Quasi-static tensile tests were conducted at two loading speeds, using a digital image correlation system to calculate strain fields. Compression properties were measured at strain rates from 0.001 to 3000 s−1 at 20 °C, and from −60 to 120 °C at a constant true strain rate of 0.01 s−1. The mechanical response of the polycarbonates is highly rate- and temperature-dependent, and the yield stresses at a wide range of rates and temperatures show time-temperature equivalence: the yield stress increases with an increase in strain rate or a decrease in temperature. Curves of yield stresses versus logarithm strain rate present an increasing gradient with increasing rate, which results from the secondary transition. Comparisons are drawn between time-temperature superposition parameters obtained from modulus data and from yield stress data, and between stress-strain curves obtained at different strain rates and at different temperatures. In the large strain region, apparent thermal softening can be observed during the medium rate tests, consistent with the transition from adiabatic to isothermal loading, whilst softening is less than expected at the higher rates.

Published

2023

4. Experimentally simulating adiabatic behaviour: Capturing the high strain rate compressive response of polymers using low strain rate experiments with programmed temperature profiles

Author

Akash R. Trivedi, Peihao Song, and Clive R. Siviour

Subjects

High strain rate, Experimental mechanics, Adiabatic self-heating, Time–temperature superposition, Polymers and polymer manufacture, TP1080-1185

Abstract

Polymers are widely used in applications where they may be subjected to impact loading leading to high strain rate deformation. Plastic work on deformation generates heat in the material. At high strain rates, there is insufficient time for this heat to diffuse out of the material, leading to adiabatic conditions. This leads to post-yield thermal softening in the mechanical response, which modifies the material response and must be considered in Engineering design. In this paper, a novel technique is presented in which this adiabatic self-heating can be simulated experimentally at low strain rates using programmed temperature profiles. We show that, in some cases, these simulations can very accurately capture the mechanical response at higher rates, but in others, the replication is less accurate. This may give further insights into the thermodynamics of high strain rate polymer mechanics. This technique therefore enables a number of avenues of research: the work to heat conversion can be investigated systematically; diagnostic tools that are limited to low strain rates can be applied; and we can better understand material behaviour and thereby improve predictive models.

Published

2022

5. Effect of Landscape Structure on Land Surface Temperature in Different Essential Urban Land Use Categories: A Case Study in Jiaozuo, China

Author

Xiaoli Jia, Peihao Song, Guoliang Yun, Ang Li, Kun Wang, Kaihua Zhang, Chenyu Du, Yuan Feng, Kexin Qu, Meng Wu, and Shidong Ge

Subjects

land surface temperature, land use categories, landscape structure, urban–rural gradients, Agriculture

Abstract

Understanding the relationship between different essential urban land use categories and the urban thermal environment is essential for urban planning, resource allocation and decision support. However, most of the spatiotemporal correlations between land use types and LST are focused on industrial land use and urban green space, and there are fewer discussions on the totality of urban land use types. Here, using multi-source remote sensing images, correlation analysis and the stepwise regression method, we elaborate the relationship between landscape structure and land surface temperature (LST) across the different seasons of 850 planning management units in Jiaozuo, China. Our results show that the degree of explanation of surface temperature by landscape structure increased with a fine division of land use. The imprint of urban–rural gradients on LST was largely masked by the land use categories at the regional scales. Moreover, the tridimensional structure of buildings significantly affected the LST of residential regions, and the large number of low-rise buildings in urban planning practice contributes to high LSTs. This study provides a comprehensive analysis of the effects of each land use type and landscape structure on surface temperature in urban space and also provides strategies and methods for urban planning in rapidly developing regions of the country.

Published

2022

6. Discover the Desirable Landscape Structure of Urban Parks for Mitigating Urban Heat: A High Spatial Resolution Study Using a Forest City, Luoyang, China as a Lens

Author

Kaihua Zhang, Guoliang Yun, Peihao Song, Kun Wang, Ang Li, Chenyu Du, Xiaoli Jia, Yuan Feng, Meng Wu, Kexin Qu, Xiaoxue Zhu, and Shidong Ge

Subjects

luoyang, Health, Toxicology and Mutagenesis, seasonal variations, Public Health, Environmental and Occupational Health, land surface temperature, stepwise regression, urban park green space, landscape structure

Abstract

Urban parks can mitigate the urban heat island (UHI) and effectively improve the urban microclimate. In addition, quantifying the park land surface temperature (LST) and its relationship with park characteristics is crucial for guiding park design in practical urban planning. The study’s primary purpose is to investigate the relationship between LST and landscape features in different park categories based on high-resolution data. In this study, we identified the land cover types of 123 parks in Luoyang using WorldView-2 data and selected 26 landscape pattern indicators to quantify the park landscape characteristics. The result shows that the parks can alleviate UHI in most seasons, but some can increase it in winter. While the percentage of bare land, PD, and PAFRAC have a positive impact on LST, AREA_MN has a significant negative impact. However, to deal with the current urban warming trend, a compact, clustered landscape configuration is required. This study provides an understanding of the major factors affecting the mitigation of thermal effects in urban parks (UP) and establishes a practical and feasible urban park renewal method under the idea of climate adaptive design, which provides valuable inspiration for urban park planning and design.

Published

2023

7. Investigating the Trends and Drivers between Urbanization and the Land Surface Temperature: A Case Study of Zhengzhou, China

Author

Chenyu Du, Peihao Song, Kun Wang, Ang Li, Yongge Hu, Kaihua Zhang, Xiaoli Jia, Yuan Feng, Meng Wu, Kexin Qu, Yangyang Zhang, and Shidong Ge

Subjects

urbanization intensity, land surface temperature, Landsat, GF-2, Zhengzhou, Renewable Energy, Sustainability and the Environment, Geography, Planning and Development, Building and Construction, Management, Monitoring, Policy and Law

Abstract

The effect of urbanization on the urban thermal environment (UTE) has attracted increasing research attention because its significant effects on local weather and climate, and serious consequences for people. However, systematic study of the relationship between urbanization and UTE has been undertaken only to a limited extent. Using quantitative thermal remote sensing and multi-buffer ring method and multiple spatial scales method, here we analyze Landsat TM/ETM+ images of Zhengzhou in Central China acquired on four different dates in 2017 to investigate the spatiotemporal variations, trends, and driving force in the land surface temperature (LST). Our results showed that LST generally increased with urbanization intensity. This trend was extremely obvious in spring and summer, weak in winter, and slightly downward in autumn. Moreover, PLAND (e.g., percentage of impervious surface in a landscape) has the most significant effect on urban LST, and generally increases as the spatial scale becomes larger. In conclusion, the study recommends that urban planning in Zhengzhou should prioritize PLAND, especially at large spatial scales. These results provide a scientific reference for urban planners who are committed to the sustainable development of Zhengzhou City.

Published

2022

8. Characterization and modelling of bisphenol-a type epoxy polymer over a wide range of rates and temperatures

Author

Huanming Chen, Peihao Song, Thomas Commins, Aaron Graham, Akash R. Trivedi, and Clive R. Siviour

Subjects

Polymers and Plastics, Organic Chemistry, Materials Chemistry

Abstract

Epoxy resins are employed in many engineering applications in which mechanical properties at different strain rates and temperatures must be quantified for effective use. It is known that these properties are related through the principle of time-temperature equivalence. In this paper, the application of this equivalence is explored in detail, at both small and large strains, and used as part of a strategy for calibrating a constitutive model that can reproduce the stress-strain behaviour in different mechanical conditions. In order to achieve this, quasi-static compression experiments were performed at temperatures from -40 to +40 °C in a screw-driven load frame; room temperature rate dependent experiments were performed from 0.0005 to 6300 s-1 using a screw-driven load frame, hydraulic compression system and Split Hopkinson Pressure Bar apparatus. Dynamic mechanical analysis and differential scanning calorimetry were also performed. A three-network (TN) polymer model was fit to the mechanical behaviour up to a strain of 0.5. This model, combined with time-temperature based mappings gave a good understanding of the thermomechanical behaviour of the material, and also demonstrates an approach that can be used for a wide range of polymers.

Published

2022

9. Tensile testing of polymers: Integration of digital image correlation, infrared thermography and finite element modelling

Author

Peihao Song, Akash Trivedi, and Clive R Siviour

Subjects

Mechanics of Materials, Mechanical Engineering, Condensed Matter Physics

Abstract

Tensile tests are often used as part of material characterisation strategies; however, the observed deformation is often complex, and it can be difficult to distinguish the underlying material behaviour from the structural response of the specimen. The objective of the research in this paper was to investigate whether a more accurate calibration of a material model could be obtained by considering not just the global behaviour of the specimen, but also the local strain-time response calculated from full-field displacement information obtained using digital image correlation. Tensile experiments were performed using ISO standard, flat, dog bone specimens. Optical and infra-red imaging were used to calculate full field displacement and temperature maps, and a finite element model of the experiment was produced. These were combined with compression test data from the same material to calibrate a constitutive model, which was shown to describe well the deformation and temperature rise in the specimen. The research demonstrates that it is insufficient to use force-displacement information from tensile experiments to calibrate, or validate, constitutive models of polymers. Further, it demonstrates a more applicable method, which could be further automated in the future.

Published

2023

10. Assessing the Ecosystem Services of Various Types of Urban Green Spaces Based on i-Tree Eco

Author

Guohang Tian, Peihao Song, Ruizhen He, Audrey L. Mayer, and Gunwoo Kim

Subjects

urban green space, 010504 meteorology & atmospheric sciences, Geography, Planning and Development, lcsh:TJ807-830, lcsh:Renewable energy sources, 010501 environmental sciences, Management, Monitoring, Policy and Law, luohe, 01 natural sciences, Ecosystem services, ComputerApplications_MISCELLANEOUS, i-tree eco, vegetation structure, Air quality index, lcsh:Environmental sciences, 0105 earth and related environmental sciences, lcsh:GE1-350, Renewable Energy, Sustainability and the Environment, business.industry, lcsh:Environmental effects of industries and plants, Environmental resource management, Urban design, Building and Construction, Vegetation, lcsh:TD194-195, Sustainability, Environmental science, Urban ecosystem, Surface runoff, business, ecosystem services, i-Tree

Abstract

Urban green spaces play a crucial role in maintaining urban ecosystem sustainability by providing numerous ecosystem services. How to quantify and evaluate the ecological benefits and services of urban green spaces remains a hot topic currently, while the evaluation is barely applied or implemented in urban design and planning. In this study, super-high-resolution aerial images were used to acquire the spatial distribution of urban green spaces, a modified pre-stratified random sampling method was applied to obtain the vegetation information of the four types of urban green spaces in Luohe, a common plain city in China, and i-Tree Eco model was further used to assess the vegetation structure and various ecosystem services including air quality improvement, rainfall interception, carbon storage, and sequestration provided by four types of urban green spaces. The modeling results reveal that there were about 1,006,251 trees in this area. In 2013, all the trees in these green spaces could store about 54,329 t of carbon, sequester about 4973 t of gross carbon, remove 92 t of air pollutants, and avoid 122,637 m&sup3, of runoff. The study illustrates an innovative method to reveal different types of urban green spaces with distinct ecosystem service productivity capacity to better understand their various roles in regulating the urban environment. The results could be used to assist urban planners and policymakers to optimize urban green space structure and composition to maximize ecosystem services provision.

Published

2020

11. Driving Mechanism of Habitat Quality at Different Grid-Scales in a Metropolitan City

Author

Yongge Hu, Enkai Xu, Nalin Dong, Guohang Tian, Gunwoo Kim, Peihao Song, Shidong Ge, and Shidong Liu

Subjects

urban habitat quality, biodiversity, grid-scales, driving mechanism, InVEST model, Geodetector, Zhengzhou, Forestry

Abstract

Urban ecosystem dysfunction, habitat fragmentation, and biodiversity loss caused by rapid urbanization have threatened sustainable urban development. Urban habitat quality is one of the important indicators for assessing the urban ecological environment. Therefore, it is of great practical significance to carry out a study on the driving mechanism of urban habitat quality and integrate the results into urban planning. In this study, taking Zhengzhou, China, as an example, the InVEST model was used to analyze the spatial differentiation characteristics of urban habitat quality and Geodetector software was adopted to explore the driving mechanism of habitat quality at different grid-scales. The results show the following: (1) LUCC, altitude, slope, surface roughness, relief amplitude, population, nighttime light, and NDVI are the dominant factors affecting the spatial differentiation of habitat quality. Among them, the impacts of slope, surface roughness, population, nighttime light, and NDVI on habitat quality are highly sensitive to varying grid-scales. At the grid-scale of 1000 to 1250 m, the impacts of the dominant factors on habitat quality is closer to the mean level of multiple scales. (2) The impact of each factor on the spatial distribution of habitat quality is different, and the difference between most factors has always been significant regardless of the variation of grid-scales. The superimposed impact of two factors on the spatial distribution of habitat quality is greater than the impact of the single factor. (3) Combined with the research results and the local conditions of Zhengzhou, we put forward some directions of habitat protection around adjusting urban land use structure, applying nature-based solutions and establishing a systematic thinking model for multi-level urban habitat sustainability.

Published

2022

12. Failure analysis of composite laminates under transverse shear load via XFEM

Author

Zhiyong Hu, Changhong Tang, Liyong Jia, Chen Zhang, Peihao Song, and Long Yu

Subjects

Materials science, business.industry, Fracture mechanics, Structural engineering, Composite laminates, Finite element method, Ultimate tensile strength, Ceramics and Composites, Fracture (geology), Direct shear test, business, Failure mode and effects analysis, Civil and Structural Engineering, Extended finite element method

Abstract

Extended finite element method (XFEM) is introduced in this study, and the normal direction of fracture surface under different failure modes is determined, which provides a new and efficient technology for failure prediction of composite laminates. According to the failure criterion, a user-defined FORTRAN subroutine (UDMGINI) has been written for Abaqus/Standard solver to model the damage initiation and crack propagation of G23 out-of-plane shear test. By comparing the load–displacement curve, strain field and failure mode of experiment, FEM and XFEM, XFEM can effectively predict the crack initiation and propagation. Meanwhile, the crack path of matrix failure simulated by XFEM is smooth without bifurcation, which is more consistent with experimental result. Moreover, by comparing damage factors of specimen before damage initiation in G23 test, it is found that the matrix tensile failure occurs more easily than matrix compressive failure at the root of V-notch, where cracks are the first to initiate.

Published

2021

13. Assessing city-scale green roof development potential using Unmanned Aerial Vehicle (UAV) imagery

Author

Qian Chen, Peihao Song, Ruizhen He, Bo Mu, Guohang Tian, Gunwoo Kim, and Huamei Shao

Subjects

0106 biological sciences, Flowchart, Ecology, Green roof, Soil Science, Forestry, 010501 environmental sciences, 010603 evolutionary biology, 01 natural sciences, Construction engineering, law.invention, Urban planning, law, Environmental science, City scale, Roof, 0105 earth and related environmental sciences

Abstract

While green roofs have been deemed promising in mitigating environmental issues caused by rapid urban development, city-scale green roof studies have faced various obstacles, especially difficulties in obtaining accurate data for analysis. This study developed a new, cost-effective approach to assessing green roof development potential by using ultra-high-resolution (UHR) (0.09 m) Unmanned Aerial Vehicle (UAV) imagery in a case study site (Central Luohe with an area of 158 km2) in China. Specifically, the data was processed, interpreted, and classified to create highly accurate land-use and building roof spatial resources databases. A decision-making flowchart was developed for preliminary determination of a building stock’s suitability for green roof implementation and the preferred type based on the five influencing factors and building roof classification. Subsequently, a two-stage strategy for large-scale green roof development was proposed. The approach demonstrated in this research greatly improves the accuracy of city-scale studies on roof spatial resources and enables better planning and development of urban green spaces at the local level.

Published

2021

14. Mechanical response of two different molecular weight polycarbonates at varying rates and temperatures

Author

Clive R. Siviour, Peihao Song, and Akash R. Trived

Subjects

Materials science, Physics, QC1-999

Abstract

Polymers are widely used for lightweight design in industrial applications, such as helmets and car bumpers, where the most common causes of failure or damage are dynamic impact events. It is well known that the mechanical response of most polymers is highly dependent on the loading rate and temperature, and that it is not sufficient to use properties measured under static loads in the analysis of dynamic events. However, the time-temperature equivalence phenomenon offers the chance to predict high-rate performance using low-rate data. In this study, information about the constitutive behaviour of two different molecular weight polycarbonates, is obtained in low-rate experiments and then compared with the high-rate response. A master curve of storage modulus constructed from Dynamic Mechanical Analysis data is employed to understand the viscoelastic response under small-strain loading at various frequencies and temperatures. For the large-strain constitutive response, experiments at strain rates from 0.001 s-1 to 3000 s-1 are performed using a conventional crosshead device, hydraulic device, and split-Hopkinson pressure bar. Moreover, experiments at strain rates of 0.01 s-1 and temperatures from -60 to 120 °C are also performed, and the results are compared. This approach can distinguish ’constitutive’ rate dependence from the effects of specimen self-heating due to adiabatic heating under high-rate deformation. Meanwhile, the molecular weight effects on the mechanical response at varying rates and temperatures are also noted.

Published

2021

15. Comparing Human Activity Density and Green Space Supply Using the Baidu Heat Map in Zhengzhou, China

Author

Ying Wang, Xiaoyu Zhao, Peihao Song, Audrey L. Mayer, Shumei Zhang, Guohang Tian, and Wenshi Zhang

Subjects

urban green space, Urban green space, Geography, Planning and Development, Big data, 0211 other engineering and technologies, TJ807-830, 02 engineering and technology, 010501 environmental sciences, Management, Monitoring, Policy and Law, Space (commercial competition), TD194-195, 01 natural sciences, Renewable energy sources, Transport engineering, big data, GE1-350, China, 0105 earth and related environmental sciences, human activity density (HAD), Baidu Heat Map, Environmental effects of industries and plants, Renewable Energy, Sustainability and the Environment, business.industry, Central city, Space use, central city of Zhengzhou, 021107 urban & regional planning, Geographically Weighted Regression, Environmental sciences, Geography, business

Abstract

Rapidly growing cities often struggle with insufficient green space, although information on when and where more green space is needed can be difficult to collect. Big data on the density of individuals in cities collected from mobile phones can estimate the usage intensity of urban green space. Taking Zhengzhou&rsquo, s central city as an example, we combine the real-time human movement data provided by the Baidu Heat Map, which indicates the density of mobile phones, with vector overlays of different kinds of green space. We used the geographically weighted regression (GWR) method to estimate differentials in green space usage between weekdays and weekends, utilizing the location and the density of the aggregation of people with powered-up mobile phones. Compared with weekends, the aggregation of people in urban green spaces on workdays tends to vary more in time and be more concentrated in space, while the highest usage is more stable on weekends. More importantly, the percentage of weekday green space utilization is higher in small parks and green strips in the city, with the density increasing in those small areas, while the green space at a greater distance to the city center is underutilized. This study validates the potential of applying Baidu Heat Map data to provide a dynamic perspective of green space use, and highlights the need for more green space in city centers.

Published

2020

16. Experimental and three-dimensional numerical investigation of matrix cracking and delamination interaction with edge effect of curved composite laminates

Author

Qingfeng Duan, Dongfeng Cao, Haixiao Hu, Shuxin Li, and Peihao Song

Subjects

Materials science, Delamination, Stacking, 02 engineering and technology, Bending, Composite laminates, Edge (geometry), 021001 nanoscience & nanotechnology, 020303 mechanical engineering & transports, Sequence dependent, 0203 mechanical engineering, Crack initiation, Ceramics and Composites, Composite material, 0210 nano-technology, Matrix cracking, Civil and Structural Engineering

Abstract

In this paper, the complex failure modes including intra-laminar matrix cracking , inter-laminar delamination and their interaction such as matrix cracking induced delamination and delamination kinking of curved composite laminates with free edge effect are investigated with both experimental testing and three-dimensional numerical modeling . Four-point bending testing of curved composite laminates with designed stacking sequences illustrated the different failure modes, and the experimental results are used to validate the proposed three-dimensional (3D) numerical model with zero-thickness cohesive elements and a mixed-mode traction-separation damage law. It is demonstrated that the proposed 3D modeling can successfully predict the stacking sequence dependent failure modes and locations, as well as crack initiation and propagation sequence, and the failure loads of the curved composite laminates. The advantage of the 3D modeling is further explored and attributed to the ability to predict the complex 3D stress distribution including the free edge effect and the progressive damage accumulation within the critical section of the curved composite laminates.

Published

2019