Alternatives to RS2

Utilizing PLAXIS 2D LE or PLAXIS 3D LE enables the modeling and evaluation of geoengineering initiatives through limit equilibrium techniques. These robust software tools focus on limit equilibrium slope stability analysis and finite element groundwater seepage analysis, delivering swift and thorough evaluations across a diverse range of scenarios. You can develop both 2D and 3D models for slope stability concerning soil and rock formations. Benefit from an extensive variety of search methods along with over 15 different analysis techniques at your disposal. Additionally, the multiplane analysis (MPA) feature enhances the spatial assessment of slope stability. This functionality allows for the analysis of various structures such as embankments, dams, reservoirs, and cover systems, while also considering broader hydrogeological contexts, thereby facilitating more informed engineering decisions. Such versatility makes these tools indispensable for professionals engaged in geoengineering projects.

Every project presents its own set of challenges, yet conducting geotechnical analysis can be straightforward with the right tools. PLAXIS 2D streamlines the process by offering rapid computational capabilities. It enables sophisticated finite element or limit equilibrium analysis concerning soil and rock deformation and stability, including aspects like soil-structure interaction, groundwater, and thermal dynamics. As an exceptionally powerful and intuitive finite-element (FE) software, PLAXIS 2D specializes in 2D analyses relevant to geotechnical engineering and rock mechanics. Used globally by leading engineering firms and academic institutions, PLAXIS is a staple in the civil and geotechnical sectors. The software proves to be versatile, accommodating various applications such as excavations, embankments, foundations, tunneling, mining, oil and gas projects, and reservoir geomechanics. Notably, PLAXIS 2D encompasses all necessary features for conducting deformation and safety assessments for soil and rock, without delving into complex factors like creep, steady-state groundwater, thermal flow, consolidation, or any time-dependent phenomena. This makes it an invaluable resource for engineers focused on efficiency and accuracy in their analyses.

GEMS, which stands for Geotechnical Engineering Modelling Software, creates sophisticated and user-friendly CAD applications specifically tailored for the evaluation and design of foundations. This suite utilizes finite element modeling methods to effectively analyze both shallow and deep foundation systems, featuring dedicated modules for assessing beam foundations, pile foundations, and a unique option for offshore pile foundations. You can experience the GEMS foundation analysis suite at no cost through a cloud-based platform. Additionally, it is accessible for trial downloads and available for purchase on both PC and Mac systems, ensuring a wide range of users can benefit from its advanced capabilities. Whether you are a student or a professional, GEMS provides an excellent opportunity to enhance your foundation design projects.

PLAXIS 3D encompasses crucial features necessary for conducting routine deformation and safety assessments related to soil and rock. This all-encompassing software facilitates the design and evaluation of soils, rocks, and their associated structures, enabling straightforward full 3D modeling. Users can efficiently create and adjust construction sequences for excavation projects. Additionally, it supports the calculation of steady-state groundwater flow, taking into account flow-related material parameters, boundary conditions, drainage systems, and wells. The software allows for the incorporation of interfaces and embedded pile elements to accurately simulate interactions between soil and foundation, addressing issues like slipping and gapping. With robust soil models and an extensive array of visualization tools, users can achieve reliable results. To tackle the specific geotechnical issues presented by soil-structure interactions, PLAXIS 3D provides various calculation methods, including plasticity, consolidation, and safety analysis, ensuring comprehensive coverage of user needs. Ultimately, this versatility makes it an indispensable tool for engineers in the field.

Ansys Mechanical stands out as an exceptional finite element solver, featuring capabilities in structural, thermal, acoustics, transient, and nonlinear analyses to enhance your modeling processes. This powerful tool allows you to tackle intricate structural engineering challenges, facilitating quicker and more informed design choices. The suite's finite element analysis (FEA) solvers permit the customization and automation of solutions for structural mechanics issues, enabling the examination of various design scenarios through parameterization. With its extensive array of analysis tools, Ansys Mechanical provides a versatile environment, guiding users from geometry preparation to integrating additional physics for enhanced accuracy. Its user-friendly and adaptable interface ensures that engineers at any experience level can swiftly obtain reliable results. Overall, Ansys Mechanical fosters an integrated platform that leverages finite element analysis (FEA) for comprehensive structural evaluations, proving invaluable for modern engineering projects.

MSC Nastran is a versatile application for multidisciplinary structural analysis, allowing engineers to conduct various assessments, including static, dynamic, and thermal analyses, in both linear and nonlinear contexts. This software integrates automated structural optimization and award-winning fatigue analysis technologies, all powered by advanced computing capabilities. Engineers leverage MSC Nastran to guarantee that structural systems possess the required strength, stiffness, and longevity to prevent failures such as excessive stresses, resonance, buckling, or harmful deformations that could jeopardize structural integrity and safety. Additionally, MSC Nastran serves to enhance the cost-effectiveness and comfort of passenger experiences in structural designs. By optimizing performance in existing frameworks or creating distinctive product features, this tool provides a competitive edge within the industry. Furthermore, it assists in addressing potential structural problems that might arise during a product's operational life, thereby minimizing downtime and reducing associated costs. Ultimately, MSC Nastran empowers engineers to innovate and refine their designs effectively.

Conduct a swift and straightforward stability assessment of both surface and underground crown pillars, as well as laminated roof beds, through the utilization of three distinct limit equilibrium analysis techniques: rigid plate, elastic plate, and Voussoir (no tension) plate analysis. Additionally, carry out a probabilistic evaluation to ascertain the likelihood of failure by incorporating statistical distributions to account for variability in factors such as geometry, location of force application, joint and bedding strength, water pressure, external loads, and more. By executing a sensitivity analysis with a variety of values, you can assess how modifications to model parameters impact the factor of safety. The methodology, initially tailored for steeply dipping ore body configurations, allows for the estimation of crown geometry and the classification of stope geometry as either steep or shallow, thus enabling the application of the most relevant empirical relationships to your analysis. This comprehensive approach ensures a robust evaluation of stability across diverse geological conditions.

A robust and adaptable preprocessor designed for generating high-quality finite element meshes at an appealing cost that is significantly lower than international alternatives. It offers strength assessments for both static and dynamic loads, as well as the ability to determine natural frequencies and vibration modes. Users can also analyze critical loads and buckling modes effectively. The software supports both 2D and 3D computations for various structures, including volumetric, thin-walled, and bar configurations. It incorporates elastoplastic deformation analysis based on the Mises and Drucker-Prager models, alongside strength evaluations for large displacements. Additionally, it calculates thermal conditions, heat loss, and temperature-induced deformations in parts and structures, while also providing strength assessments for materials with high elasticity. This comprehensive approach ensures that engineers can conduct thorough analyses across a wide range of applications.

By utilizing CONSELF, you can harness the power of Computational Fluid Dynamics (CFD) and Finite Element Analysis (FEA) to enhance your product designs: reduce drag and losses related to fluid dynamics, boost efficiency, optimize heat exchange capabilities, assess pressure loads, confirm material strength, analyze deformation in component shapes, compute natural frequencies and modes, among various other functions. The platform offers both static and dynamic simulations for Structural Mechanics, accommodating the behavior of materials under elastic and plastic conditions. Additionally, it enables modal and frequency analyses, starting from widely used CAD neutral file formats, ensuring a seamless integration into your design workflow. This comprehensive approach allows for innovative solutions to complex engineering challenges.

Cold forming tools experience significant mechanical and tribological stresses throughout their operational lifespan, which in some instances can result in premature damage to the tools. Given that these tools constitute a substantial portion of the manufacturing costs for components, it is crucial to proactively address potential issues during the design phase. The COLDFORM® software offers the ability to assess the mechanical strength of dies, thereby enhancing their longevity. It calculates stress distribution within the die, as well as monitoring deformations, wear, temperature variations, and any damage that may occur throughout the process. Furthermore, COLDFORM® can perform quick analyses by applying the stresses derived from the forming process to the tools. Additionally, the software supports coupled part/tool simulations, yielding highly accurate outcomes. With features focused on pre-stressed dies, it allows for precise assessment of the required pre-stressing for the interference fit of the tools. This capability ultimately aids manufacturers in optimizing tool performance and reducing costs associated with tool replacements.

Conduct a comprehensive soil settlement evaluation that encompasses immediate settlement, primary consolidation, and secondary settlement for various structures including embankments, foundations, and surface loads. Utilize RSLog for easy creation of soil profiles, integrating CPT boreholes with classified soil data, or leverage the section creator feature for efficient model generation. Gain greater adaptability in implementing ground improvement techniques such as soil replacement, vibro-compaction, or stone columns, which can be tailored to accommodate different staging at varying depths. Additionally, perform sensitivity analysis for settlement assessments that consider ground improvement characteristics like stiffness, top depth, bottom depth, and spacing. You can carry out CPT and Liquefaction analyses either independently or in tandem, with CPT analysis offering 29 distinct parameter outcomes. Furthermore, Liquefaction assessments can be derived using Standard Penetration Test (SPT), Cone Penetration Test (CPT), or Shear Wave Velocity (VST) data, providing a versatile approach to evaluating soil behavior under seismic conditions. This multifaceted analysis ensures a thorough understanding of soil dynamics, facilitating better engineering decisions.

Inventor® Nastran® is a finite element analysis (FEA) tool integrated within CAD software, enabling engineers and analysts to perform a diverse range of studies using various materials. This software provides comprehensive simulation capabilities that encompass both linear and nonlinear stress analysis, dynamic simulations, and heat transfer assessments. It is exclusively accessible through the Product Design & Manufacturing Collection, which includes a suite of powerful tools designed to enhance workflows within Inventor. In addition to advanced simulation features, this collection also offers 5-axis CAM, nesting tools, and access to software like AutoCAD and Fusion 360, ensuring a holistic approach to product design and manufacturing processes. By utilizing Inventor Nastran, professionals can streamline their analysis and improve their design outcomes significantly.

With STAAD, you are empowered to design, assess, and document structural projects globally, utilizing any material you choose. This software provides a versatile solution tailored to meet all your structural engineering requirements from the ground up. STAAD serves as an all-encompassing application for structural finite element analysis and design, enabling users to conduct evaluations on any structure subjected to various loads including static, dynamic, wind, seismic, thermal, and moving forces. Available in multiple variations, STAAD allows you to select the version that best suits your specific needs. Renowned for its analytical capabilities, extensive applications, interoperability, and efficiency, STAAD is a favored choice among structural engineers. It facilitates 3D structural analysis and design for both steel and concrete frameworks. Furthermore, a physical model created within the software can easily be converted into an analytical model for in-depth structural analysis. STAAD incorporates numerous design code standards, ensuring compliance and accuracy in engineering practices. In addition, its user-friendly interface enhances productivity, making complex design processes simpler and more efficient.

You can effortlessly generate intricate concrete geometries, encompassing everything from single levels and ramps to multi-story concrete edifices, by utilizing powerful modeling tools that also support imports from CAD and BIM applications. Analyze slabs or full structures efficiently for the cumulative impacts of gravity, lateral forces, and vibrations through advanced 3D finite element analysis, simple load takedown techniques, and precise slab alignment. Whether you are examining an existing reinforced concrete slab or crafting a multi-story post-tensioned building, ADAPT-Builder gives you the ability to manage every design element, including cracking, long-term deflections, and punching shear, thus ensuring that your results are both accurate and comprehensive. No matter your specific concrete design requirements, ADAPT offers a software solution tailored to your needs. Take the time to compare the various packages available and embark on your project today. ADAPT-Builder serves as the comprehensive platform for 3D modeling, analysis, and design alongside ADAPT-Floor Pro, Edge, MAT, and SOG, while Modeler can be integrated with ADAPT-PT and RC for enhanced functionality and versatility. With these tools at your disposal, you can achieve remarkable precision and efficiency in your concrete design endeavors.

GT STRUDL® stands out as a comprehensive structural engineering software that integrates 3D CAD modeling and advanced 64-bit computation solvers in its various versions. This software provides a full suite of tools for analyzing a wide array of structural engineering and finite element analysis challenges, encompassing both linear and nonlinear static and dynamic analyses, achieving high accuracy in significantly less time compared to most other design software available. Designed to assist structural engineers in developing safe and efficient designs, GT STRUDL effectively addresses the complexities that arise across multiple industries such as power generation, civil engineering, marine applications, and infrastructure development. Moreover, quality software like GT STRUDL boasts a range of features, including interoperability, structural analysis capabilities, database-driven design, and quality assurance, all aimed at enhancing the engineering design process. This robust combination of functionality and efficiency makes GT STRUDL a valuable asset for engineers tackling intricate projects.

Ansys Sherlock stands out as the sole reliability physics-based tool for electronics design that delivers quick and precise life expectancy assessments for electronic components, boards, and systems during the initial design phases. By automating the design analysis process, Ansys Sherlock enables the rapid generation of life predictions, thus eliminating the "test-fail-fix-repeat" cycle that often hampers development. Designers can effectively model the interactions between silicon–metal layers, semiconductor packaging, printed circuit boards (PCBs), and assemblies, allowing for accurate predictions of potential failure risks stemming from thermal, mechanical, and manufacturing stresses, all prior to creating prototypes. Additionally, Sherlock's extensive libraries, which house over 500,000 components, facilitate the seamless transformation of electronic computer-aided design (ECAD) files into computational fluid dynamics (CFD) and finite element analysis (FEA) models. Each of these models is equipped with precise geometries and material properties, ensuring that stress information is accurately conveyed for reliable predictions. This capability not only enhances design efficiency but also significantly reduces the risk of costly errors in the later stages of product development.

Gain a comprehensive understanding of the properties of rock and soil materials by examining their strength characteristics and constitutive behaviors to establish strength envelopes and various material parameters. Employ constitutive models such as NorSand and Modified Cam Clay to thoroughly analyze the stress-strain relationships inherent in your soil materials. An added advantage of RSData is the inclusion of RocProp, an independent application that provides a database of intact rock properties. Explore the extensive array of technical features that RSData offers for your analyses. Adjust your rock’s strength criteria and the observed stress-strain behaviors using data obtained from field and laboratory tests, and make comparisons with numerical simulations of those same tests. RSData also allows for the importation of laboratory tests and stress-strain paths of soils for effective visualization. You can enhance your analysis by comparing and calibrating material parameters, visualizing predicted constitutive behavior alongside experimental data. Additionally, various constitutive models can be employed to predict outcomes in standard laboratory tests, making RSData a versatile tool for material analysis.

The Petrel E&P software suite features a user-friendly graphical interface known as Petrel Reservoir Geomechanics, which facilitates transparent data exchanges and supports the configuration and visualization of results from the VISAGE simulator. This integration allows users to leverage the robust capabilities of the VISAGE simulator alongside various interpretation, modeling, and engineering processes within the Petrel framework. By utilizing the workflows enabled by the Petrel platform, users can incorporate diverse data types to generate new 3D geomechanics property and stress models, or enhance existing subsurface reservoir models with geomechanics data. Such cohesive integration within the Petrel system guarantees that the geomechanics model remains aligned and harmonized with geophysics, geology, petrophysics, and reservoir information. Furthermore, this holistic approach promotes improved decision-making and more accurate predictions in reservoir management.

The optimization of material usage has emerged as a fundamental aspect of the ongoing transformation within the industry. Manufacturers are in a constant quest for components that are both lightweight and durable, aiming to enhance cost-effectiveness by reducing warranty claims, minimizing recall expenses, and speeding up production timelines. Advanced finite element analysis is essential for conducting design stress calculations effectively. However, many organizations still depend on the outdated method of manually selecting stress points for spreadsheet-based fatigue analysis, which proves to be both inefficient and prone to errors, raising the likelihood of missing critical failure points. In this context, fe-safe stands out as the leading expert in fatigue analysis software tailored for finite element models. Since the early 1990s, fe-safe has consistently set the standard for fatigue analysis solutions, working hand-in-hand with industry leaders. The fe-safe software suite represents a premier technology for durability analysis derived from finite element analysis, seamlessly integrating with all major FEA platforms, thereby enhancing efficiency and reliability in the analysis process. As industries continue to evolve, the need for such advanced tools will only grow more significant.

Fatigue Essentials is a desktop software designed to streamline the process of structural fatigue analysis. This application offers an intuitive interface for performing stress-life evaluations, utilizing either traditional stress calculations or integrating with FEMAP™ to leverage finite element analysis results. The program is designed with a user-friendly tree structure that guides users through various stages of analysis, starting with selections related to loads, materials, and spectrum branches. Each section allows for different variations of analysis or methods of input. Users can view analysis results directly on the screen, which can be easily copied into reports or visualized as damage contour plots in FEMAP. It encompasses a wide range of engineering needs, featuring a classic mode that allows for manual input of stresses and a professional mode linked with FEMAP, which can read nodal stresses and generate damage contour visualizations. Additionally, users have the flexibility to choose between interactive input or file uploads for entering stresses and cycles, enhancing the application's versatility. Ultimately, Fatigue Essentials stands out as an essential tool for engineers engaged in fatigue analysis.

nCode DesignLife serves as a proactive design tool that pinpoints essential areas and estimates realistic fatigue lifespans based on top finite element (FE) analysis results applicable to both metals and composites. This innovative tool empowers design engineers to enhance their approach beyond basic stress assessments, enabling them to simulate real-world loading scenarios and thereby mitigate the risks of both under-design and over-design in their products, which can lead to expensive modifications later on. Additionally, the software offers features like virtual shaker testing, fatigue analysis for welds, vibration fatigue assessments, crack growth monitoring, fatigue evaluation for composites, and thermo-mechanical fatigue studies. It leverages advanced technologies for analyzing multiaxial stress, weld integrity, short-fiber composites, vibrational impacts, crack propagation, and thermal stress fatigue. With a user-friendly graphical interface, it facilitates comprehensive fatigue analysis using data from leading FEA tools such as ANSYS, Nastran, Abaqus, Altair OptiStruct, LS-Dyna, among others. Moreover, it incorporates multi-threaded and distributed processing capabilities, enabling efficient handling of large finite element models and optimizing overall usage schedules. This powerful combination of features ultimately ensures that engineers can deliver more reliable and efficient designs.

SimScale, a web-based cloud application, plays an important role in simulation software for many industries. The platform supports Computational Fluid Dynamics, Finite Element Analysis (FEA), as well as Thermal Simulation. It also provides 3D simulation, continuous modeling, motion & dynamic modelling.

GENOA 3DP is a comprehensive software suite and design tool tailored for additive manufacturing across polymers, metals, and ceramics. Its simulate-to-print capabilities highlight strong performance and user-friendly interaction, making it an effective choice for diverse applications. With the ability to deliver precision at the micro-scale and significantly minimize material waste and engineering time, GENOA 3DP can be swiftly incorporated into any manufacturing process to ensure optimal additive manufacturing outcomes. Rooted in advanced failure analysis techniques and enhanced by multi-scale material modeling, this tool empowers engineers to reliably forecast issues like voids, net shapes, residual stress, and crack propagation in as-built additive manufacturing components. By offering a consistent approach to enhance part quality, decrease scrap rates, and adhere to specifications, GENOA 3DP effectively connects the fields of material science and finite element analysis, ultimately driving innovation in the manufacturing sector. This integration fosters a deeper understanding of material behaviors, paving the way for more efficient production methodologies.

Subjecting your designs to real-world scenarios can significantly enhance product quality while simultaneously minimizing the costs associated with prototyping and physical testing. The SOLIDWORKS® Simulation suite offers a user-friendly collection of structural analysis tools that employ Finite Element Analysis (FEA) to forecast how a product will behave in actual physical conditions by virtually evaluating CAD models. This comprehensive portfolio is equipped with capabilities for both linear and non-linear static and dynamic analyses. With SOLIDWORKS Simulation Professional, you can refine your designs by assessing mechanical resistance, durability, topology, natural frequencies, as well as examining heat transfer and potential buckling issues. Additionally, it facilitates sequential multi-physics simulations to enhance design accuracy. On the other hand, SOLIDWORKS Simulation Premium allows for an in-depth assessment of designs concerning nonlinear and dynamic responses, dynamic loading conditions, and composite materials. This advanced tier also features three specialized studies: Non-Linear Static, Non-Linear Dynamic, and Linear Dynamics, ensuring a thorough evaluation of your engineering projects. By leveraging these powerful tools, engineers can achieve greater design confidence and innovation.

Elevate your product design by incorporating simulation and analysis, which helps minimize expensive physical prototyping while enhancing the durability, reliability, and safety of your products. Employing digital prototypes to assess the performance of your designs in real-world scenarios is crucial for successful product development. Creo Simulation is specifically tailored for engineers, featuring a robust suite of structural, thermal, and vibration analysis tools along with an extensive range of finite element analysis (FEA) capabilities. With Creo Simulation, you can effectively evaluate and affirm the performance of your 3D virtual prototypes prior to producing the first physical component. We provide adaptable and innovative simulation solutions to meet the distinct needs of our customers. This section serves as a resource to explore our offerings tailored to your requirements, and should you have any inquiries about our toolset, please do not hesitate to reach out to a Creo representative for assistance. This proactive approach ensures that your products not only meet but exceed expectations in their respective markets.

FloCAD® serves as an add-on module for Thermal Desktop®, creating a comprehensive software solution for thermohydraulic analysis that encompasses fluid flow and heat transfer. The process of constructing fluid flow models in FloCAD closely resembles that of thermal models, allowing for the use of numerous shared commands across both model types. Users can create FloCAD models using a free-form approach, which allows for the simplification and abstraction of flow networks, or they can opt for geometry-based modeling that incorporates elements like pipe centerlines, cross-sections, and intricate vessels, as well as convection calculations linked to finite difference or finite element thermal structures. As an advanced tool for pipe flow analysis, FloCAD effectively accounts for pressure losses within piping networks arising from bends, valves, tees, and variations in flow area, among other factors. This versatility makes FloCAD a valuable asset for engineers looking to optimize system designs.

FEATool Multiphysics – "Physics Simulator Made Easy" – a fully integrated physics simulation, FEA and CFD toolbox. FEATool Multiphysics provides a fully integrated simulation platform that includes a unified user interface for several multi-physics solvers such as OpenFOAM and Computational fluid dynamics (CFD), including SU2 Code and FEniCS. This allows users to model coupled physics phenomena, such as those found in fluid flow and heat transfer, structural, electromagnetics acoustics and chemical engineering applications. FEATool multiphysics is a trusted tool for engineers and researchers in the energy, automotive and semi-conductor industries.

Simcenter Nastran stands out as a leading finite element method (FEM) solver known for its exceptional computational performance, precision, dependability, and scalability. This comprehensive tool provides robust solutions for various applications, including linear and nonlinear structural analysis, structural dynamics, acoustics, rotor dynamics, aeroelasticity, thermal analysis, and optimization. One of the key benefits of having such a diverse array of solutions within a single solver is that it standardizes input/output file formats across all types of analyses, significantly streamlining the modeling process. Whether utilized as an independent enterprise solver or integrated within Simcenter 3D, Simcenter Nastran is instrumental for manufacturers and engineering firms across several sectors, including aerospace, automotive, electronics, heavy machinery, and medical devices. By catering to their vital engineering computing requirements, it enables these industries to deliver safe, reliable, and optimized designs while adhering to increasingly tighter design timelines. This versatility and efficiency make Simcenter Nastran an invaluable asset in the modern engineering landscape.

Identify essential failure surfaces and determine the appropriate factor of safety by utilizing a blend of global metaheuristic search techniques alongside local surface-modifying technologies. By incorporating parallel processing for both failure detection and factor of safety calculations, outcomes can be produced in a matter of minutes. Enhance your workflow and gain more comprehensive insights by seamlessly integrating 3D wireframes that depict surveyed terrain, geological layers, modeled faults, and more into your 3D models. The process of constructing slope stability models has never been more efficient or expedient. You can either import surfaces from geological modeling or mine planning software or utilize integrated surface construction techniques based on coordinates or borehole information. Additionally, you have the option to create surfaces from point cloud data or import block models from various applications, including Leapfrog, Deswik, Datamine, and Vulcan, ensuring versatility and precision in your modeling efforts. This advancement not only accelerates the modeling process but also provides richer and more accurate representations of geological conditions.

Patran offers an extensive array of tools designed to facilitate the development of models ready for analysis across various domains, including linear and nonlinear problems, explicit dynamics, thermal analysis, and more within finite element solutions. Its geometry cleanup features assist engineers in efficiently addressing issues like gaps and slivers present in CAD designs, while solid modeling capabilities allow users to construct models from the ground up. The software simplifies the mesh generation process on both surfaces and solids through a combination of fully automated meshing routines and manual techniques that afford users greater precision. Additionally, Patran includes built-in options for setting up loads, boundary conditions, and analyses compatible with leading finite element solvers, significantly reducing the need for adjusting input files. With its robust and industry-validated functionalities, Patran ensures that virtual prototyping is not only swift but also effective, enabling users to assess product performance against specific requirements and refine their designs accordingly. As a result, engineers can spend less time on setup and more on innovation and optimization.

Comprehensive analysis of geological datasets allows for a detailed examination of the orebody, including variations in mid-bench hardness, forecasts for upcoming benches, and expectations for mill output. By consolidating data from across the site, a comprehensive operational overview is achieved that highlights the impact of decisions made by different departments on specific results. MinePortal serves as a cloud-based solution, ensuring that all team members have access to real-time insights from any device, regardless of their location. This integration of systems and operations promotes optimization across the entire site, enabling the maximization of throughput through enhanced blast performance. Consistent management of grade and hardness blends facilitates optimal throughput, leading to better planning and more effective blasting strategies, which subsequently improve mill performance. Increased understanding of how the orebody influences production processes fosters better communication among various operational stages. Moreover, integrated datasets pinpoint which geological characteristics and performance variables either contribute positively or pose challenges to overall operational efficiency. Such a comprehensive approach ultimately leads to improved decision-making and operational success.

S-FRAME empowers users to model, analyze, and design any type of structure, accommodating a wide range of geometric complexities, material specifications, loading scenarios, nonlinear behaviors, and design code stipulations. The platform features automated framework generators that facilitate rapid model creation and offers seamless integration with BIM and DXF formats, allowing users to enhance their efficiency with built-in design tools for concrete and steel, which support design, optimization, code adherence, and report generation. Through S-FRAME, users can swiftly define structures with advanced modeling automation, enabling the generation of regular framework structures and both standard and custom trusses, while clone tools allow for the easy replication of entire models or specific sections. Moreover, the ability to import existing BIM and DXF models significantly reduces modeling time, further improving productivity. The sophisticated meshing capabilities of S-FRAME create a detailed finite element mesh, equipping users to derive comprehensive analysis results tailored to their areas of interest. Lastly, users have the flexibility to delve deeper into their analysis by converting members into multi-shell models, enhancing their understanding and evaluation of structural performance.

Engineers and researchers can use WELSIM finite-element analysis software to create prototype virtual products and conduct simulation studies.

DEPRO is an all-encompassing program designed for torque, drag, and hydraulics analysis in drilling operations. This software aids users in mitigating various risks associated with drilling and completion tasks. By forecasting the limitations in horizontal well lengths based on friction factors, DEPRO offers recommendations for rig specifications and assesses the necessary weight for setting a packer. In terms of hydraulics, it addresses downhole circulating pressures, surge and swab effects, equivalent circulation densities (ECD), bit optimization, hole cleaning, and volumetric displacements. With DEPRO, users can thoroughly investigate downhole hydraulic conditions and pinpoint any potential issues before actual field implementation. Additionally, it provides calculations for torque, drag, and stress, while also supporting soft and stiff string models. The software caters to various operations including drilling, back reaming, rotation off the bottom, and tripping in and out. It also features predictions for sinusoidal and helical buckling, comparisons of field data on workload and surface torque, friction factor sensitivity analysis, and assessments for packer setting, ensuring a comprehensive toolkit for drilling engineers. The all-in-one nature of DEPRO enhances operational safety and efficiency.

SolidFEA is a groundbreaking solid finite element analysis tool that aims to make sophisticated structural engineering design both more accessible and cost-effective. Utilizing the Calculix engine, it provides in-depth sub-model analysis while requiring less financial investment and computing power compared to competitors such as Abaqus. This software is particularly well-suited for tackling intricate engineering challenges, such as those found in steel connections and bridge engineering, and it empowers users by making specialized software easier to access. With its ability to import IFC file formats, SolidFEA integrates smoothly into existing engineering workflows, enhancing the functionality of our GenFEA software for thorough structural analysis. By lowering entry barriers traditionally tied to solid finite element analysis (FEA), SolidFEA represents a significant advancement in structural engineering design and encourages innovation by allowing more engineers to participate in complex projects. Ultimately, its user-friendly design and compatibility features facilitate a new era of efficiency in engineering practices.

GeoProbe® software stands as the premier solution for 3D multi-volume interpretation and visualization within the industry. It is tailored to enhance interpretation workflows, spanning from broad basin analyses down to intricate prospect and reservoir evaluations. With GeoProbe, users experience remarkable speed, whether they are assessing reservoir-scale data on personal computers or collaborating with asset teams to analyze basin-scale volumes in expansive immersive visualization settings. The software incorporates GeoShell technologies, empowering geoscientists to swiftly interpret the geometries and boundaries of salt bodies with unmatched flexibility and accuracy. This capability to integrate all pertinent data into a dynamically adjustable multi-Z subsurface model ensures that even in regions with complex structures, the identification of reservoir compositions can be achieved with heightened precision. In doing so, GeoProbe not only streamlines the interpretation process but also enhances decision-making for resource exploration and development.

DesignCalc software offers users a comprehensive set of features, complemented by an integrated library of industry standards and effective practices that simplify compliance with ASME BPVC Section VIII for pressure vessel design like never before. It includes Finite Element Analysis (FEA) tools that facilitate rapid and straightforward assessments. NozzlePRO serves as a robust and efficient 3-D FEA application, adept at modeling nozzles, saddles, pipe shoes, and clips. Users can enhance their designs by performing calculations that determine either pressure or thickness. This allows for the use of the slimmest materials available while still adhering to necessary codes. Additionally, the software can produce industry-standard report formats that encompass the actual calculations utilized, making them ready for thorough review by inspectors. This ensures that all aspects of pressure vessel design are not only efficient but also compliant with industry regulations.

RadCAD employs an advanced, oct-tree accelerated Monte-Carlo ray tracing algorithm to calculate radiation exchange factors and view factors with remarkable speed. The enhancements introduced by C&R Technologies in the ray tracing methodology have led to the development of a highly efficient thermal radiation analysis tool. By utilizing finite difference "conics" or curved finite elements from TD Direct®, RadCAD is capable of precisely simulating diffuse and specular reflections as well as transmissive surfaces, independent of node density. The thermal solution's requirements govern the node quantity, rather than the precision needed for radiation calculations. Furthermore, RadCAD allows users to create custom databases that specify optical properties, with each surface coating detailing its absorptivity, transmissivity, reflectivity, and specularity in both solar and infrared wavelengths. These optical characteristics can be tailored to account for variations in incident angles or wavelength dependencies, enhancing the accuracy and relevance of thermal modeling. Ultimately, this level of customization ensures that RadCAD meets diverse analytical needs across various applications.

In times of tight schedules or limited resources, integrated solutions are crucial. RIBTEC provides many synergies in calculation design, construction, and design. In the context of Building Information Modeling (BIM), you can benefit from a faster data flow that streamlines the entire process of structural design. RIB's software solutions are available for structural engineers. They include building, ground, and finite element calculations as well as tunnel and bridge construction as well as the drawing of formwork or reinforcement plans. Since 1961, RIB has been a pioneer in structural design and FEM. Over 5,000 engineering offices, inspection and construction engineers, as well as planning departments from the public and private sectors use the RIBTEC programs. RIBTEC covers all aspects of structural design with more than 100 programs.

AxisVM is primarily utilized for designing buildings, along with industrial and geotechnical structures. Its robust finite element solver combined with practical modeling tools makes it suitable for bridge design, as well as for developing composite structures, machines, and vehicles. In addition to standard configurations, users have access to optional design modules tailored for structures constructed from reinforced concrete, steel, timber, and masonry members and connections. Furthermore, the software's unique elements and advanced analysis capabilities enable the successful design of innovative and custom structures. Additionally, users can generate comprehensive reports that include tables, drawings, and detailed design calculations, complete with tailored headings and text. These reports are dynamically updated, automatically reflecting the latest model data and results, ensuring accuracy and relevance in documentation. This feature enhances user efficiency by simplifying the reporting process.

SPACE GASS is a versatile 3D analysis and design software tailored for structural engineers. Its broad array of features accommodates everything from beams and trusses to complex structures like buildings, towers, tanks, cable systems, and bridges. Users can benefit from a powerful 64-bit multi-core solver, impressive 3D visualizations, and specialized elements including plate, frame, cable, and tension/compression-only types, as well as tools for moving loads and integrations with various CAD and building management systems. Choosing SPACE GASS means optimizing your resources with cost-effective, safe, and efficient designs. The user-friendly graphical interface allows for immediate visual feedback on changes, enhancing the design process. Additionally, a rapid sparse matrix solver takes full advantage of multi-core processing capabilities for increased efficiency. The software features a diverse suite of structural modeling tools, analysis methodologies, and design modules to meet various engineering needs. Moreover, an array of comprehensive video tutorials is available to guide users through complex tasks effectively. Finally, the software can be configured for either stand-alone use or floating network systems, adding flexibility for different working environments.

Simcenter Femap is a sophisticated simulation tool designed for the creation, modification, and analysis of finite element models pertaining to intricate products or systems. This software allows users to implement advanced workflows for modeling individual components, assemblies, or entire systems, enabling them to assess how these models react under realistic conditions. Moreover, Simcenter Femap offers robust data-driven capabilities and graphical visualizations for results interpretation, which, when paired with the top-tier Simcenter Nastran, provides a holistic CAE solution aimed at enhancing product performance. As manufacturers strive to develop lighter yet more robust products, there is a growing emphasis on the utilization of composite materials. Simcenter stands at the forefront of composite analysis, continually advancing its material models and element types to meet industry demands. Furthermore, Simcenter accelerates the simulation process for laminate composite materials by providing an integrated connection to composite design, streamlining workflows for engineers in the field. This integration ultimately fosters innovation and efficiency in product development, paving the way for more sustainable manufacturing practices.

CalculiX allows users to create, analyze, and process finite element models efficiently. It features an interactive 3D pre-and post-processor that utilizes the OpenGL API for enhanced visualization. The solver within CalculiX is capable of handling both linear and non-linear calculations, offering solutions for static, dynamic, and thermal problems. Since it employs the Abaqus input format, users can leverage commercial pre-processors seamlessly. Furthermore, the pre-processor can generate mesh-related data compatible with Nastran, Abaqus, Ansys, Code-Aster, as well as free computational fluid dynamics tools such as Dolfyn, Duns, ISAAC, and OpenFOAM. A straightforward step reader is also integrated into the system. Additionally, there are options for external CAD interfaces, broadening its usability. This versatile program is designed to operate on various Unix platforms like Linux and Irix, as well as on MS Windows, making it accessible to a wide range of users.

Numerous professionals utilize VisualAnalysis (VA) to efficiently meet their project deadlines. Users frequently commend it as "exceptional value" and "incredibly user-friendly." It provides essential tools that are budget-conscious. The software allows for the creation of 3D models for a variety of structures, including complete buildings, tanks, and towers, alongside offering both static and dynamic response analysis capabilities. It performs design code verifications for materials such as steel, wood, concrete, cold-formed steel, and aluminum. VisualAnalysis features comprehensive analysis and design functionalities, including automatic plate meshing, a command window, nonlinear elements, and dynamic time history analysis. Its 3D static and dynamic finite element analysis (FEA) is suitable for civil, mechanical, aerospace, and other types of structural evaluations. Additionally, it includes optional support for building code load combinations. Users can easily apply loads, distribute area loads to structural members, and manage gravity and lateral loads within the same project. The software enables the creation of frame, truss, or FEA models for nearly any type of structure, with the ability to sketch, generate, and import designs from CAD or BIM tools like Revit. With its rapid static analysis, P-delta calculations, AISC Direct methods, dynamic assessments, and nonlinear capabilities, it delivers proven and validated results for engineering professionals. Overall, VisualAnalysis stands out as a versatile solution for various engineering needs.

SwiftComp is an innovative composite simulation software that combines multiscale and multiphysics capabilities to provide the precision of 3D finite element analysis (FEA) with the simplicity of basic engineering models. This groundbreaking tool simplifies the modeling process for engineers, allowing them to treat composites with the same ease as metals while maintaining accuracy and capturing intricate microstructural details. It offers cohesive modeling for structures that are one-dimensional (like beams), two-dimensional (such as plates or shells), and three-dimensional, effectively calculating the material properties required. Users can utilize SwiftComp independently for virtual composite testing or as an enhancement to existing structural analysis tools, thereby integrating high-fidelity composite modeling into their workflows. Additionally, SwiftComp excels in determining the optimal structural model for macroscopic analysis and includes capabilities for dehomogenization, which enables the calculation of pointwise stresses within the microstructure. It seamlessly connects with established software such as ABAQUS and ANSYS, further broadening its applicability in engineering projects. As a result, SwiftComp significantly enhances the efficiency and effectiveness of composite material modeling in various engineering applications.