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Cradle Cfd 2025.1 (x64)
File Size: 4.6 MB[/center]
Cradle CFD is a series of practical, state-of-the-art CFD simulation and visualization software. Embracing remarkable processing speed, refined technology, and proven practicality verified by high user satisfaction, it has been in use for diverse applications, such as Automotive, Aerospace, Electronics, Building and Architecture, Civil Engineering, Fans, Machinery, and Marine developments, to solve thermal and fluid problems.
Cradle CFD includes modules
scFLOW
scSTREAM & Heat Designer
SC/Tetra
scPOST
CADthru
scFLOW
scFLOW - an application for mathematical modeling of fluid dynamics and heat transfer problems with an adaptive mesh and high computing speed.
Features and functions specific to scFLOW
Simplification of preprocessor operations
. Necessary operations with CAD data for mesh analysis have been significantly simplified compared to previous versions. Saving assembly information and adjusting part parameters create a sense of continuity in workflow between systems and reduce the user load.
Adaptive mesh.
The function of local coarsening/refining of elements during automatic mesh generation has been improved. The adaptive mesh is generated from elements with the most appropriate size for a specific geometry.
View mode.
Data from the preprocessor can be displayed in view mode when the license is occupied by the postprocessor or mesh generation.
Operation logging via the VB interface.
Operations from the preprocessor can be saved as a log file using the Visual Basic interface. This does not allow the creation of custom scripts, but allows the creation of an automated system in a short period of time based on the operations saved in the log.
Accelerated Steady-State Analysis
: Optimizations to the calculation algorithm have improved the performance of the convergence function and reduced the computational cycle time for steady-state calculations.
Calculation Stabilization
For a mesh of low-quality elements, calculations can be automatically stabilized to prevent divergence. Script
Development
Previously, complex settings (material properties or boundary conditions dependent on time or coordinates) required creating C code and then compiling. When using scripts, compilation is not required, and the functions themselves can be written in the JavaScript preprocessor. Moving Elements (Discrete Mesh) : Performing calculations for moving objects: rotating fans, cars moving close to each other. The accuracy of calculating element connections has been improved by revising the algorithm. Memory efficiency has been improved for the parallel solver, which should have a significant effect on multi-core calculations when working with large problems. Free Surface: The software calculates the shape of the contact surface between a gaseous and a liquid substance. This function can be used in conjunction with other functions such as boundary shifting, mesh overlapping, and particle tracking. If the phase surface is stabilized, a steady-state analysis can be performed, yielding results in a shorter time.
scSTREAM & Heat Designer
scSTREAM - an application for mathematical modeling of fluid dynamics and heat transfer problems with a structured mesh.
Calculation models in scSTREAM are based on a simple and easy-to-construct structured mesh. This type of mesh consists of many small cuboids, so it approximates curved surfaces only in a step structure.
This type of mesh is used in cases where curved surfaces or small details do not significantly affect the overall result. Examples of using a structured mesh are found in modeling electronics cooling, heating, ventilation and air conditioning, as well as in the design of architectural structures.
Features, functions, and tasks specific to scSTREAM
Various methods of representing geometry
The shape of the model to be analyzed can be represented using the following methods
- voxel method (inclined and curved surfaces are represented as cuboids);
- beveled cell method (refinement of a model created using a CAD system);
- finite element method (an arbitrary-shaped model with an unstructured mesh can be superimposed on a model with a structured mesh, allowing the CAD model to be used in its original form).
Modeling the Motion of Objects
The scSTREAM system allows one to calculate the flow generated by a perfectly rigid moving object. Parameters such as object motion (displacement, rotation, elastic deformations), heat generation/absorption, and air supply/exhaust can be set as conditions. A different mesh is created for the model of the moving object. With this approach, conditions such as the distance traveled by the object are virtually unlimited, allowing for the creation of models of arbitrary complexity.
Scaling Boundary Conditions
If the target phenomenon being studied is an order of magnitude smaller than the size of the environment that influences it, the results of the environmental analysis can be used as boundary conditions to reduce the time and number of calculations.
Free Surface
The software calculates the shape of the contact surface between a gaseous and a liquid substance. This feature is useful in a wide range of fields, from tsunami analysis in civil engineering and construction to soldering analysis in electronics.
Calculating highly complex models
With a structured mesh, a complex model requires virtually no adjustments, as the shape and size of model elements do not affect the complexity of mesh generation. Furthermore, parallel computing enables high-speed calculations, ensuring efficient data processing.
Local Mesh Refinement
Mesh refinement can be performed locally to more accurately represent the model shape and perform calculations efficiently.
Creation of User Variables and Scripts
Complex conditions containing trigonometric functions or branches with IF operators can be defined without compilation.
Electronic Component Library
The geometry and properties of frequently used parts can be saved in a library for future reuse, saving time when creating a calculation model.
Thermal Trajectory Display (HeatPathView)
Information about the temperature of each part and the total amount of heat released obtained during post-processing of CFD analysis results is not enough to understand the thermal trajectory. HeatPathView displays the thermal trajectory and the amount of heat transferred throughout the computational domain using diagrams, graphs, and tables, making it easy to identify bottlenecks.
Importing Data from Electronic CAD Systems
This function allows you to read and import data about the printed circuit board (PCB) wiring diagram from a CAD system. This allows for a more realistic simulation result, taking into account heat transfer caused by uneven wiring diagrams.
The HeatDesigner module (included in the scSTREAM distribution) is designed for thermal calculations of electronic components.
HeatDesigner is a specialized solution based on scSTREAM, developed for thermal calculations of electronics. HeatDesigner's performance is optimized for cases where precise reproduction of curved geometry is not required to predict the flow field. However, HeatDesigner supports meshes of over 100 million elements, allowing for a sufficiently accurate description of small geometric features. As with scSTREAM, HeatDesigner's main advantages are short calculation times and low consumption of computing resources.
Features, functions, and tasks specific to HeatDesigner
Calculation of highly complex models
. With a structured mesh, a complex model requires virtually no adjustment, since the shape and size of model elements do not affect the complexity of mesh generation. Furthermore, parallel calculations enable high-speed calculations, ensuring efficient data processing.
Local mesh refinement.
Mesh refinement can be performed locally to more accurately represent the model's shape and perform calculations efficiently.
Creating user variables and scripts.
Complex conditions containing trigonometric functions or branches with IF statements can be defined without compilation.
Electronic Component Library
The geometry and properties of frequently used parts can be saved in a library for future reuse, saving time when creating a simulation model.
Thermal Path Display (HeatPathView)
Information about the temperature of each part and the total amount of heat released obtained during post-processing of CFD analysis results is insufficient for understanding the thermal path. HeatPathView displays the thermal path and the amount of heat transferred throughout the entire computational domain using diagrams, graphs, and tables, making it easy to identify bottlenecks.
Importing Data from Electronic CAD Systems
This feature allows you to read and import printed circuit board (PCB) wiring diagram data from a CAD system. This allows for more realistic simulation results, accounting for heat transfer caused by uneven wiring.
Examples of the tasks solved
Modeling of boiling, condensation formation
Illumination analysis
Modeling of solar radiation
Air humidity analysis (condensation and evaporation processes)
Modeling of vegetation (wind, evaporative cooling)
Modeling of wind loads
Assessing the influence of the electrostatic field Modeling of
filling with foaming resin
Modeling of solidification/melting processes
Modeling of Joule heat
Tracking of elementary particles (behavior, reactions, interactions)
SC/Tetra
scTETRA is an application for mathematical modeling of fluid dynamics and heat transfer problems with an unstructured mesh.
scTETRA uses a hybrid mesh that allows for the representation of model geometry with high accuracy. A fast mesh generator, high-speed calculations, low memory consumption, and a user-friendly interface allow for efficient work and fast results.
The hybrid (or unstructured) mesh is generated using tetrahedral, pentahedral, hexahedral, and other polyhedral elements. This mesh is used in problems where accurate representation of geometry is critical. Examples of such problems include modeling vehicle aerodynamics, pipeline flows, and turbomachinery operation.
Features, functions, and applications specific to scTETRA
High-speed automatic mesh generation.
A high-quality mesh is automatically generated in minimal time using the Advancing Front exhaustion method. When creating a layer of prismatic elements, its width can be specified depending on the width of the flow channel. The software accelerates mesh generation by using parallel computing and supports the creation of large mesh sizes.
Adaptive Mesh
For steady-state analysis, this feature automatically reduces the mesh element size in regions where flow or pressure changes significantly. After the solver completes its calculations, the preprocessor runs automatically and rebuilds the mesh based on the calculation results. This feature is suitable for analyzing flows in complex pipe shapes.
CAD Model Modification
In scTETRA, models obtained from a CAD system can be edited as needed or if errors arise. Boundary conditions can be established based on part names and other parameters imported from the CAD system. If any regions required for analysis are missing from the imported model, they can be represented by shapes such as a cuboid or cylinder. Free
Surface
The software calculates the shape of the contact surface between a gaseous and a liquid substance. This feature can be used in conjunction with features such as boundary moving, mesh overlapping, and particle tracking. Application examples include analyzing the impact of waves on a ship, analyzing the impact of vibration on a gas tank, and more.
Dynamic function
Allows analysis of the forced displacement and rotation of a perfectly rigid object under the influence of hydrodynamic forces.
Discrete mesh
This mesh technology allows
- simulate flows generated by moving objects: rotating fans and turbines, moving cars or trains;
- analyze heating taking into account the shear between the rotor and hub in a disc brake system;
- analyze a combination of rotation and translation (e.g. a piston pump).
Mesh Overlap
Motion that is not reproduced by deformation or rotation is simulated using an overlapping mesh for the moving and stationary domains. In addition, object contact and overlap of multiple domains are supported. An example of an application for this function is the analysis of the opening and closing of an engine piston valve or a gear pump operating through gears.
Strength Analysis Module
Deformations and thermal stresses can be calculated based on the calculated values of pressure and temperature. An interface with Abaqus has been implemented for solving problems of fluid-structure interaction.
Compressible Fluid Simulation
scTETRA enables the analysis of supersonic flow phenomena and significant volume expansion/compression. For compressible fluids, both pressure-based and density-based solvers are used. The type of solver depends on the purpose of the analysis and the type of phenomenon.
Examples of the tasks solved
Boiling simulation
Cavitation simulation
Fan simulation (model creation, shape analysis)
Aerodynamic noise analysis
Solidification/melting process
simulation Dispersed multiphase flow simulation
Particle tracking (behavior, reactions, interactions)
Condensate amount calculation
Liquid film simulation (advanced particle tracking function)
Pressure loss simulation
Thermal control simulation
Turbulent flow simulation
Radiation simulation
Fan simulation without creating a geometric model
Joule heat simulation
Plain bearing designer
scPOST
scPOST is a postprocessor for visualizing calculation data performed by both Cradle-cfd and other solvers.
Available import formats: MSC Nastran, MSC Marc, images (BMP, PNG), 3D geometry (STL, Parasolid).
Available export formats: Generic format for fluid data (.cgns), images (BMP, JPG, PNG), animation (AVI, WMV), 3D geometry (STL, VRLM, FBX).
What's New
official site does not provide any info about changes in this version.
Cradle Cfd 2025.1 (x64)
File Size: 4.6 MB[/center]
Cradle CFD is a series of practical, state-of-the-art CFD simulation and visualization software. Embracing remarkable processing speed, refined technology, and proven practicality verified by high user satisfaction, it has been in use for diverse applications, such as Automotive, Aerospace, Electronics, Building and Architecture, Civil Engineering, Fans, Machinery, and Marine developments, to solve thermal and fluid problems.
Cradle CFD includes modules
scFLOW
scSTREAM & Heat Designer
SC/Tetra
scPOST
CADthru
scFLOW
scFLOW - an application for mathematical modeling of fluid dynamics and heat transfer problems with an adaptive mesh and high computing speed.
Features and functions specific to scFLOW
Simplification of preprocessor operations
. Necessary operations with CAD data for mesh analysis have been significantly simplified compared to previous versions. Saving assembly information and adjusting part parameters create a sense of continuity in workflow between systems and reduce the user load.
Adaptive mesh.
The function of local coarsening/refining of elements during automatic mesh generation has been improved. The adaptive mesh is generated from elements with the most appropriate size for a specific geometry.
View mode.
Data from the preprocessor can be displayed in view mode when the license is occupied by the postprocessor or mesh generation.
Operation logging via the VB interface.
Operations from the preprocessor can be saved as a log file using the Visual Basic interface. This does not allow the creation of custom scripts, but allows the creation of an automated system in a short period of time based on the operations saved in the log.
Accelerated Steady-State Analysis
: Optimizations to the calculation algorithm have improved the performance of the convergence function and reduced the computational cycle time for steady-state calculations.
Calculation Stabilization
For a mesh of low-quality elements, calculations can be automatically stabilized to prevent divergence. Script
Development
Previously, complex settings (material properties or boundary conditions dependent on time or coordinates) required creating C code and then compiling. When using scripts, compilation is not required, and the functions themselves can be written in the JavaScript preprocessor. Moving Elements (Discrete Mesh) : Performing calculations for moving objects: rotating fans, cars moving close to each other. The accuracy of calculating element connections has been improved by revising the algorithm. Memory efficiency has been improved for the parallel solver, which should have a significant effect on multi-core calculations when working with large problems. Free Surface: The software calculates the shape of the contact surface between a gaseous and a liquid substance. This function can be used in conjunction with other functions such as boundary shifting, mesh overlapping, and particle tracking. If the phase surface is stabilized, a steady-state analysis can be performed, yielding results in a shorter time.
scSTREAM & Heat Designer
scSTREAM - an application for mathematical modeling of fluid dynamics and heat transfer problems with a structured mesh.
Calculation models in scSTREAM are based on a simple and easy-to-construct structured mesh. This type of mesh consists of many small cuboids, so it approximates curved surfaces only in a step structure.
This type of mesh is used in cases where curved surfaces or small details do not significantly affect the overall result. Examples of using a structured mesh are found in modeling electronics cooling, heating, ventilation and air conditioning, as well as in the design of architectural structures.
Features, functions, and tasks specific to scSTREAM
Various methods of representing geometry
The shape of the model to be analyzed can be represented using the following methods
- voxel method (inclined and curved surfaces are represented as cuboids);
- beveled cell method (refinement of a model created using a CAD system);
- finite element method (an arbitrary-shaped model with an unstructured mesh can be superimposed on a model with a structured mesh, allowing the CAD model to be used in its original form).
Modeling the Motion of Objects
The scSTREAM system allows one to calculate the flow generated by a perfectly rigid moving object. Parameters such as object motion (displacement, rotation, elastic deformations), heat generation/absorption, and air supply/exhaust can be set as conditions. A different mesh is created for the model of the moving object. With this approach, conditions such as the distance traveled by the object are virtually unlimited, allowing for the creation of models of arbitrary complexity.
Scaling Boundary Conditions
If the target phenomenon being studied is an order of magnitude smaller than the size of the environment that influences it, the results of the environmental analysis can be used as boundary conditions to reduce the time and number of calculations.
Free Surface
The software calculates the shape of the contact surface between a gaseous and a liquid substance. This feature is useful in a wide range of fields, from tsunami analysis in civil engineering and construction to soldering analysis in electronics.
Calculating highly complex models
With a structured mesh, a complex model requires virtually no adjustments, as the shape and size of model elements do not affect the complexity of mesh generation. Furthermore, parallel computing enables high-speed calculations, ensuring efficient data processing.
Local Mesh Refinement
Mesh refinement can be performed locally to more accurately represent the model shape and perform calculations efficiently.
Creation of User Variables and Scripts
Complex conditions containing trigonometric functions or branches with IF operators can be defined without compilation.
Electronic Component Library
The geometry and properties of frequently used parts can be saved in a library for future reuse, saving time when creating a calculation model.
Thermal Trajectory Display (HeatPathView)
Information about the temperature of each part and the total amount of heat released obtained during post-processing of CFD analysis results is not enough to understand the thermal trajectory. HeatPathView displays the thermal trajectory and the amount of heat transferred throughout the computational domain using diagrams, graphs, and tables, making it easy to identify bottlenecks.
Importing Data from Electronic CAD Systems
This function allows you to read and import data about the printed circuit board (PCB) wiring diagram from a CAD system. This allows for a more realistic simulation result, taking into account heat transfer caused by uneven wiring diagrams.
The HeatDesigner module (included in the scSTREAM distribution) is designed for thermal calculations of electronic components.
HeatDesigner is a specialized solution based on scSTREAM, developed for thermal calculations of electronics. HeatDesigner's performance is optimized for cases where precise reproduction of curved geometry is not required to predict the flow field. However, HeatDesigner supports meshes of over 100 million elements, allowing for a sufficiently accurate description of small geometric features. As with scSTREAM, HeatDesigner's main advantages are short calculation times and low consumption of computing resources.
Features, functions, and tasks specific to HeatDesigner
Calculation of highly complex models
. With a structured mesh, a complex model requires virtually no adjustment, since the shape and size of model elements do not affect the complexity of mesh generation. Furthermore, parallel calculations enable high-speed calculations, ensuring efficient data processing.
Local mesh refinement.
Mesh refinement can be performed locally to more accurately represent the model's shape and perform calculations efficiently.
Creating user variables and scripts.
Complex conditions containing trigonometric functions or branches with IF statements can be defined without compilation.
Electronic Component Library
The geometry and properties of frequently used parts can be saved in a library for future reuse, saving time when creating a simulation model.
Thermal Path Display (HeatPathView)
Information about the temperature of each part and the total amount of heat released obtained during post-processing of CFD analysis results is insufficient for understanding the thermal path. HeatPathView displays the thermal path and the amount of heat transferred throughout the entire computational domain using diagrams, graphs, and tables, making it easy to identify bottlenecks.
Importing Data from Electronic CAD Systems
This feature allows you to read and import printed circuit board (PCB) wiring diagram data from a CAD system. This allows for more realistic simulation results, accounting for heat transfer caused by uneven wiring.
Examples of the tasks solved
Modeling of boiling, condensation formation
Illumination analysis
Modeling of solar radiation
Air humidity analysis (condensation and evaporation processes)
Modeling of vegetation (wind, evaporative cooling)
Modeling of wind loads
Assessing the influence of the electrostatic field Modeling of
filling with foaming resin
Modeling of solidification/melting processes
Modeling of Joule heat
Tracking of elementary particles (behavior, reactions, interactions)
SC/Tetra
scTETRA is an application for mathematical modeling of fluid dynamics and heat transfer problems with an unstructured mesh.
scTETRA uses a hybrid mesh that allows for the representation of model geometry with high accuracy. A fast mesh generator, high-speed calculations, low memory consumption, and a user-friendly interface allow for efficient work and fast results.
The hybrid (or unstructured) mesh is generated using tetrahedral, pentahedral, hexahedral, and other polyhedral elements. This mesh is used in problems where accurate representation of geometry is critical. Examples of such problems include modeling vehicle aerodynamics, pipeline flows, and turbomachinery operation.
Features, functions, and applications specific to scTETRA
High-speed automatic mesh generation.
A high-quality mesh is automatically generated in minimal time using the Advancing Front exhaustion method. When creating a layer of prismatic elements, its width can be specified depending on the width of the flow channel. The software accelerates mesh generation by using parallel computing and supports the creation of large mesh sizes.
Adaptive Mesh
For steady-state analysis, this feature automatically reduces the mesh element size in regions where flow or pressure changes significantly. After the solver completes its calculations, the preprocessor runs automatically and rebuilds the mesh based on the calculation results. This feature is suitable for analyzing flows in complex pipe shapes.
CAD Model Modification
In scTETRA, models obtained from a CAD system can be edited as needed or if errors arise. Boundary conditions can be established based on part names and other parameters imported from the CAD system. If any regions required for analysis are missing from the imported model, they can be represented by shapes such as a cuboid or cylinder. Free
Surface
The software calculates the shape of the contact surface between a gaseous and a liquid substance. This feature can be used in conjunction with features such as boundary moving, mesh overlapping, and particle tracking. Application examples include analyzing the impact of waves on a ship, analyzing the impact of vibration on a gas tank, and more.
Dynamic function
Allows analysis of the forced displacement and rotation of a perfectly rigid object under the influence of hydrodynamic forces.
Discrete mesh
This mesh technology allows
- simulate flows generated by moving objects: rotating fans and turbines, moving cars or trains;
- analyze heating taking into account the shear between the rotor and hub in a disc brake system;
- analyze a combination of rotation and translation (e.g. a piston pump).
Mesh Overlap
Motion that is not reproduced by deformation or rotation is simulated using an overlapping mesh for the moving and stationary domains. In addition, object contact and overlap of multiple domains are supported. An example of an application for this function is the analysis of the opening and closing of an engine piston valve or a gear pump operating through gears.
Strength Analysis Module
Deformations and thermal stresses can be calculated based on the calculated values of pressure and temperature. An interface with Abaqus has been implemented for solving problems of fluid-structure interaction.
Compressible Fluid Simulation
scTETRA enables the analysis of supersonic flow phenomena and significant volume expansion/compression. For compressible fluids, both pressure-based and density-based solvers are used. The type of solver depends on the purpose of the analysis and the type of phenomenon.
Examples of the tasks solved
Boiling simulation
Cavitation simulation
Fan simulation (model creation, shape analysis)
Aerodynamic noise analysis
Solidification/melting process
simulation Dispersed multiphase flow simulation
Particle tracking (behavior, reactions, interactions)
Condensate amount calculation
Liquid film simulation (advanced particle tracking function)
Pressure loss simulation
Thermal control simulation
Turbulent flow simulation
Radiation simulation
Fan simulation without creating a geometric model
Joule heat simulation
Plain bearing designer
scPOST
scPOST is a postprocessor for visualizing calculation data performed by both Cradle-cfd and other solvers.
Available import formats: MSC Nastran, MSC Marc, images (BMP, PNG), 3D geometry (STL, Parasolid).
Available export formats: Generic format for fluid data (.cgns), images (BMP, JPG, PNG), animation (AVI, WMV), 3D geometry (STL, VRLM, FBX).
What's New
official site does not provide any info about changes in this version.
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