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TwinMesh

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== TwinMesh ==
== TwinMesh ==
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TwinMesh is a [[Meshing|meshing]] software developed by CFX Berlin Software GmbH, Germany. It automatically generates hexahedral meshes for the computational [[Fluid dynamics|fluid dynamics]] ([[Introduction to CFD|CFD]]) simulation of the continuously changing [[Fluid|fluid]] volumes of the working chambers of rotary positive displacement machines. The product was released in 2014.
+
TwinMesh is a [[Meshing|meshing]] software developed by CFX Berlin Software GmbH, Germany. It automatically generates hexahedral meshes for the computational [[Fluid dynamics|fluid dynamics]] ([[Introduction to CFD|CFD]]) simulation of the continuously changing [[Fluid|fluid]] volumes of the working chambers of rotary positive displacement (PD) machines. The product was released in 2014.
TwinMesh supports floating licenses via LM-X license manager for 64-bit Windows and Linux systems.
TwinMesh supports floating licenses via LM-X license manager for 64-bit Windows and Linux systems.
-
The current product release is Version 2019, released in January 2019.
+
The current product release is Version 2024, released in November 2023.
=== Mesh Types ===
=== Mesh Types ===
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* Node mapping at general grid interfaces.
* Node mapping at general grid interfaces.
* Various smoothing algorithms to control mesh orthogonality and node equidistance in all three dimensions.
* Various smoothing algorithms to control mesh orthogonality and node equidistance in all three dimensions.
-
* Mesh quality check such as: determinant, min. angle, volume change, aspect ratio.
+
* Mesh quality check such as: determinant, min. angle, volume change, and aspect ratio.
-
* CHT-GGI interface allows to create a fluid-fluid-solid interface.
+
 
* TwinMesh supports [[Parallel computing|parallel computing]] with the usage of up to 16 local cores for the meshing process.
* TwinMesh supports [[Parallel computing|parallel computing]] with the usage of up to 16 local cores for the meshing process.
 +
 +
=== Additional Features ===
 +
 +
* CHT-GGI interface that allows to create a fluid-fluid-solid interface.
 +
* Non-reflecting boundary condition in CFX-Pre.
 +
* Mesh interpolation feature that allows to vary the solver timestep and the rotational speed of the PD machine.
 +
* Consideration of shaft deflection and thermal deformation.
 +
* Support for variable pitch profiles
 +
* Support for bending line and rotor deformation due to mechanical and thermal loads
 +
* Mesh deformation approach for reed valves is included into User Fortran routines (CFX) and User Defined Functions (Fluent) to get a simple but stable and efficient simulation setup, allowing several reed valves with different properties in one simulation
 +
=== Geometry Support ===
=== Geometry Support ===
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=== Rotary Positive Displacement Machines ===
=== Rotary Positive Displacement Machines ===
-
TwinMesh allows meshing of the following rotary positive displacement machines:
+
TwinMesh allows meshing of the following rotary PD machines:
* Internal/external gear pump
* Internal/external gear pump
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* Eccentric screw pump/progressive cavity pump
* Eccentric screw pump/progressive cavity pump
* Wankel engine
* Wankel engine
 +
* Single stage and multi stage vacuum pumps
=== CFD Solver Interfaces ===
=== CFD Solver Interfaces ===
-
TwinMesh has built-in support for [[Ansys FAQ#CFX|ANSYS CFX]] and automatically generates ready-to-run templates for ANSYS CFX (including non-reflecting boundary conditions) and ANSYS CFD PrepPost.
+
TwinMesh has built-in support for [[Ansys FAQ#CFX|ANSYS CFX]] and [[Ansys Fluent]] and automatically generates ready-to-run templates for ANSYS CFX, Ansys Fluent and ANSYS CFD PrepPost.
=== Supported Platforms ===
=== Supported Platforms ===
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* Hesse, J., Spille-Kohoff, A., Hauser, J., & Schulze-Beckinghausen, P. (2014). Structured meshes and reliable CFD simulations: TwinMesh for positive displacement machines. In International screw compressor conference, TU Dortmund.
* Hesse, J., Spille-Kohoff, A., Hauser, J., & Schulze-Beckinghausen, P. (2014). Structured meshes and reliable CFD simulations: TwinMesh for positive displacement machines. In International screw compressor conference, TU Dortmund.
* Spille-Kohoff, A., Hesse, J., & El Shorbagy, A. (2015, August). CFD simulation of a screw compressor including leakage flows and rotor heating. In IOP Conference Series: Materials Science and Engineering (Vol. 90, No. 1, p. 012009). IOP Publishing. ([https://iopscience.iop.org/article/10.1088/1757-899X/90/1/012009/pdf])
* Spille-Kohoff, A., Hesse, J., & El Shorbagy, A. (2015, August). CFD simulation of a screw compressor including leakage flows and rotor heating. In IOP Conference Series: Materials Science and Engineering (Vol. 90, No. 1, p. 012009). IOP Publishing. ([https://iopscience.iop.org/article/10.1088/1757-899X/90/1/012009/pdf])
-
* Andres, R., Nikolov, A., & Brümmer, A. (2016). CFD Simulation of a Twin Screw Expander including Leakage Flows. In 23rd International Compressor Engineering Conference at Purdue, July 11-14, 2016. ([https://www.conftool.com/2016Purdue/index.php/Andres-2016-CFD_Simulation_of_a_Twin_Screw_Expander_including_Leakage_Flows-1512.pdf?page=downloadPaper&filename=Andres-2016-CFD_Simulation_of_a_Twin_Screw_Expander_including_Leakage_Flows-1512.pdf&form_id=1512&form_version=final])
+
* Andres, R., Nikolov, A., & Brümmer, A. (2016). CFD Simulation of a Twin Screw Expander including Leakage Flows. In 23rd International Compressor Engineering Conference at Purdue, July 11-14, 2016. ([https://docs.lib.purdue.edu/cgi/viewcontent.cgi?article=3496&context=icec])
* Willie, J. (2017, September). Use of CFD to predict trapped gas excitation as source of vibration and noise in screw compressors. In IOP Conference Series: Materials Science and Engineering (Vol. 232, p. 012021). IOP Publishing. ([http://iopscience.iop.org/article/10.1088/1757-899X/232/1/012021/pdf])
* Willie, J. (2017, September). Use of CFD to predict trapped gas excitation as source of vibration and noise in screw compressors. In IOP Conference Series: Materials Science and Engineering (Vol. 232, p. 012021). IOP Publishing. ([http://iopscience.iop.org/article/10.1088/1757-899X/232/1/012021/pdf])
* Pietrzyk, P., Roth, D., Schmitz, K. & Jacobs, G. (2018). Design study of a high speed power unit for electro hydraulic actuators (EHA) in mobile applications. In 11th International Fluid Power Conference Aachen, March 19-21, 2018. ([http://publications.rwth-aachen.de/record/726047/files/726047.pdf])
* Pietrzyk, P., Roth, D., Schmitz, K. & Jacobs, G. (2018). Design study of a high speed power unit for electro hydraulic actuators (EHA) in mobile applications. In 11th International Fluid Power Conference Aachen, March 19-21, 2018. ([http://publications.rwth-aachen.de/record/726047/files/726047.pdf])

Latest revision as of 09:51, 29 November 2023

Contents

TwinMesh

TwinMesh is a meshing software developed by CFX Berlin Software GmbH, Germany. It automatically generates hexahedral meshes for the computational fluid dynamics (CFD) simulation of the continuously changing fluid volumes of the working chambers of rotary positive displacement (PD) machines. The product was released in 2014.

TwinMesh supports floating licenses via LM-X license manager for 64-bit Windows and Linux systems.

The current product release is Version 2024, released in November 2023.

Mesh Types

TwinMesh can generate structured hexahedral meshes for the axial gaps and working chambers of rotary positive displacement machines.
Additionally, TwinMesh can generate unstructured tetrahedral meshes for the axial gaps of rotary positive displacement machines.

Meshing Techniques

TwinMesh's mesh generation employs the following meshing techniques and smoothing algorithms.

  • Option to fix the nodes along the rotors, which results in a general interface between the rotor meshes.
  • Option to fix the nodes along the housing geometry to get an 1:1 interface between the rotor meshes.
  • Option to fix the nodes on one of the rotors so that the nodes on the other rotor are able to move. This method also results in an 1:1 rotor interface.
  • Option to mesh rotors with variable pitch.
  • Manual adjustment of individual nodes.
  • Node mapping at general grid interfaces.
  • Various smoothing algorithms to control mesh orthogonality and node equidistance in all three dimensions.
  • Mesh quality check such as: determinant, min. angle, volume change, and aspect ratio.
  • TwinMesh supports parallel computing with the usage of up to 16 local cores for the meshing process.

Additional Features

  • CHT-GGI interface that allows to create a fluid-fluid-solid interface.
  • Non-reflecting boundary condition in CFX-Pre.
  • Mesh interpolation feature that allows to vary the solver timestep and the rotational speed of the PD machine.
  • Consideration of shaft deflection and thermal deformation.
  • Support for variable pitch profiles
  • Support for bending line and rotor deformation due to mechanical and thermal loads
  • Mesh deformation approach for reed valves is included into User Fortran routines (CFX) and User Defined Functions (Fluent) to get a simple but stable and efficient simulation setup, allowing several reed valves with different properties in one simulation


Geometry Support

TwinMesh supports IGES (.iges) and point data (.csv).

The following geometry modifications are available in TwinMesh:

  • Rotor scaling
  • Rotor translation
  • Rotation angle offset

Rotary Positive Displacement Machines

TwinMesh allows meshing of the following rotary PD machines:

  • Internal/external gear pump
  • Gerotor pump
  • Orbital motor
  • Vane pump
  • Lobe pump
  • Roots blower
  • Rotary piston pump
  • Scroll compressor/expander
  • Conical rotor pump
  • Screw compressor/expander
  • Eccentric screw pump/progressive cavity pump
  • Wankel engine
  • Single stage and multi stage vacuum pumps

CFD Solver Interfaces

TwinMesh has built-in support for ANSYS CFX and Ansys Fluent and automatically generates ready-to-run templates for ANSYS CFX, Ansys Fluent and ANSYS CFD PrepPost.

Supported Platforms

TwinMesh supports 64-bit Windows versions.

Literature

  • Hesse, J., Spille-Kohoff, A., Hauser, J., & Schulze-Beckinghausen, P. (2014). Structured meshes and reliable CFD simulations: TwinMesh for positive displacement machines. In International screw compressor conference, TU Dortmund.
  • Spille-Kohoff, A., Hesse, J., & El Shorbagy, A. (2015, August). CFD simulation of a screw compressor including leakage flows and rotor heating. In IOP Conference Series: Materials Science and Engineering (Vol. 90, No. 1, p. 012009). IOP Publishing. ([1])
  • Andres, R., Nikolov, A., & Brümmer, A. (2016). CFD Simulation of a Twin Screw Expander including Leakage Flows. In 23rd International Compressor Engineering Conference at Purdue, July 11-14, 2016. ([2])
  • Willie, J. (2017, September). Use of CFD to predict trapped gas excitation as source of vibration and noise in screw compressors. In IOP Conference Series: Materials Science and Engineering (Vol. 232, p. 012021). IOP Publishing. ([3])
  • Pietrzyk, P., Roth, D., Schmitz, K. & Jacobs, G. (2018). Design study of a high speed power unit for electro hydraulic actuators (EHA) in mobile applications. In 11th International Fluid Power Conference Aachen, March 19-21, 2018. ([4])

External Links

* TwinMesh's homepage
* CFX Berlin's homepage
My wiki