Scribd
Upload
37 views10 pages

Fluidoss

This report summarizes a fluid flow simulation of water flow through a model. A fine mesh with over 155,000 cells was used. Two inlets with different velocities and temperatures were specified along with an outlet pressure boundary condition. The simulation was laminar, did not include heat transfer, gravity or radiation effects. Results included minimum fluid temperature and global min-max values to evaluate design goals. The simulation found that mixing occurred between the inlet flows.

Uploaded by

est.daniel.areyes
Copyright
© © All Rights Reserved
We take content rights seriously. If you suspect this is your content, claim it here.
Available Formats
Download as DOCX, PDF, TXT or read online on Scribd
37 views10 pages

Fluidoss

This report summarizes a fluid flow simulation of water flow through a model. A fine mesh with over 155,000 cells was used. Two inlets with different velocities and temperatures were specified along with an outlet pressure boundary condition. The simulation was laminar, did not include heat transfer, gravity or radiation effects. Results included minimum fluid temperature and global min-max values to evaluate design goals. The simulation found that mixing occurred between the inlet flows.

Uploaded by

est.daniel.areyes
Copyright
© © All Rights Reserved
We take content rights seriously. If you suspect this is your content, claim it here.
Available Formats
Download as DOCX, PDF, TXT or read online on Scribd
You are on page 1/ 10

[Company logo here]

Fluid Flow Simulation Project


[company name here] [city, state here] [company url here] Report

[name] ∙ [title] ∙ ∙ [email address] ∙ (###) ###-####

SOLIDWORKS Flow Simulation


Project Report

October 21, 2023

[Model Picture here]

Learn more about SOLIDWORKS Flow Simulation


Fluid Flow Simulation Report

Table of Contents
1 General Information...........................................................................................................................1
1.1 Analysis Environment.............................................................................................................1
1.2 Model Information..................................................................................................................1
1.3 Project Comments:..................................................................................................................1
1.4 Size of Computational Domain...............................................................................................1
1.5 Simulation Parameters.............................................................................................................1
1.5.1 Mesh Settings......................................................................................................................1
1.5.2 Material Settings..................................................................................................................2
1.5.3 Initial Conditions.................................................................................................................2
1.5.4 Boundary Conditions...........................................................................................................2
1.5.5 Volumetric Heat Sources.....................................................................................................2
1.5.6 Engineering Goals...............................................................................................................2
1.6 Analysis Time.........................................................................................................................2
2 Results.............................................................................................................................................2
2.1 Analysis Goals.........................................................................................................................2
2.2 Global Min-Max-Table..............................................................................................................2
2.3 Results.....................................................................................................................................2
2.4 Conclusion...............................................................................................................................2
3 Appendix..........................................................................................................................................2
3.1 Material Data...........................................................................................................................2

II
Fluid Flow Simulation Report

1 General Information
Objective of the simulation: Lorem ipsum dolor sit amet, consectetur adipiscing elit. Ut a pulvinar lacus. Vivamus
adipiscing adipiscing eleifend. Pellentesque eget ante in ante suscipit gravida in non lorem. Suspendisse hendrerit
sagittis lacus non aliquam. Proin pellentesque, lorem quis consequat porta, lectus nunc vestibulum lectus, nec rhoncus
libero dui ut felis. Vestibulum eu aliquet tellus. Curabitur suscipit ornare sem. Suspendisse pulvinar pharetra ultrices.
Suspendisse a quam massa

1.1 Analysis Environment


Software Product: Flow Simulation 2022 SP2.0. Build: 5593
CPU Type: Intel(R) Core(TM) i7-4770S CPU @ 3.10GHz
CPU Speed: 3101 MHz
RAM: 8100 MB / 3271 MB
Operating System: Windows 10 (or higher) (Version 10.0.19045)

1.2 Model Information


Model Name: ejercicio1.SLDPRT
Project Name: malla fina

1.3 Project Comments:


Unit System: SI (m-kg-s)
Analysis Type: Internal

1.4 Size of Computational Domain

Size
X min -0.038 m
X max 0.146 m
Y min 0.004 m
Y max 0.896 m
Z min 0m
Z max 0.038 m
X size 0.183 m
Y size 0.893 m
Z size 0.038 m

1.5 Simulation Parameters


1.5.1 Mesh Settings
1.5.1.1 Basic Mesh

Basic Mesh Dimensions


Number of cells in X 17
Number of cells in Y 70

1
Fluid Flow Simulation Report
Number of cells in Z 5

1.5.1.2 Analysis Mesh


Total Cell count: 155824
Fluid Cells: 155824
Solid Cells: 146604
Partial Cells: 83145
Trimmed Cells: 0

1.5.1.3 Additional Physical Calculation Options


Heat Transfer Analysis: Heat conduction in solids: Off
Flow Type: Laminar and turbulent
Time-Dependent Analysis: Off
Gravity: Off
Radiation:
Humidity:
Default Wall Roughness: 0 micrometer

1.5.2 Material Settings

Material Settings
Fluids
Water

1.5.3 Initial Conditions

Initial Conditions
Thermodynamic parameters Static Pressure: 101325.00 Pa
Temperature: 20.05 °C
Velocity parameters Velocity vector
Velocity in X direction: 0 m/s
Velocity in Y direction: 0 m/s
Velocity in Z direction: 0 m/s
Turbulence parameters Turbulence intensity and length
Intensity: 2.00 %
Length: 8.500e-04 m

1.5.4 Boundary Conditions

Boundary Conditions
Inlet Velocity 1
Type Inlet Velocity
Faces Cara<1>
Coordinate system Face Coordinate System
Reference axis X
Flow parameters Flow vectors direction: Normal to face
2
Fluid Flow Simulation Report
Velocity normal to face: 0.700 m/s
Fully developed flow: No
Thermodynamic parameters Temperature type: Temperature of initial
components
Temperature: 12.00 °C
Turbulence parameters Turbulence intensity and length
Intensity: 2.00 %
Length: 8.500e-04 m
Boundary layer parameters Boundary layer type: Turbulent

Inlet Velocity 2
Type Inlet Velocity
Faces Cara<1>
Coordinate system Face Coordinate System
Reference axis X
Flow parameters Flow vectors direction: Normal to face
Velocity normal to face: 1.000 m/s
Fully developed flow: No
Thermodynamic parameters Temperature type: Temperature of initial
components
Temperature: 80.00 °C
Turbulence parameters Turbulence intensity and length
Intensity: 2.00 %
Length: 8.500e-04 m
Boundary layer parameters Boundary layer type: Turbulent

Environment Pressure 3
Type Environment Pressure
Faces Cara<1>
Coordinate system Face Coordinate System
Reference axis X
Thermodynamic parameters Environment pressure: 101325.00 Pa
Temperature type: Temperature of initial
components
Temperature: 20.05 °C
Turbulence parameters Turbulence intensity and length
Intensity: 2.00 %
Length: 8.500e-04 m
Boundary layer parameters Boundary layer type: Turbulent

1.5.5 Volumetric Heat Sources

1.5.6 Engineering Goals

Goals
Global Goals
GG Minimum Temperature (Fluid) 1
3
Fluid Flow Simulation Report
Type Global Goal
Goal type Temperature (Fluid)
Calculate Minimum value
Coordinate system Global Coordinate System
Use in convergence On

GG Average Temperature (Fluid) 2


Type Global Goal
Goal type Temperature (Fluid)
Calculate Average value
Coordinate system Global Coordinate System
Use in convergence On

GG Maximum Temperature (Fluid) 3


Type Global Goal
Goal type Temperature (Fluid)
Calculate Maximum value
Coordinate system Global Coordinate System
Use in convergence On

GG Bulk Av Temperature (Fluid) 4


Type Global Goal
Goal type Temperature (Fluid)
Calculate Average value
Coordinate system Global Coordinate System
Use in convergence On

1.6 Analysis Time


Calculation Time: 536 s
Number of Iterations: 212
Warnings:

4
Fluid Flow Simulation Report

2 Results
2.1 Analysis Goals

Goals
Name Unit Value Progress Criteria Delta Use in
convergenc
e
GG °C 12.00 100 0.0071172984 0.0032932002 On
Minimum 7 2
Temperatur
e (Fluid) 1
GG °C 16.00 100 0.122223429 0.0051374715 On
Average
Temperatur
e (Fluid) 2
GG °C 80.01 100 0.0216942531 0.0216288441 On
Maximum
Temperatur
e (Fluid) 3
GG Bulk °C 15.98 100 0.123041276 0.0051240595 On
Av 1
Temperatur
e (Fluid) 4

2.2 Global Min-Max-Table

Min/Max Table
Name Minimum Maximum
Density (Fluid) [kg/m^3] 972.05 999.36
Pressure [Pa] 99780.23 102070.39
Temperature [°C] 12.00 80.01
Temperature (Fluid) [°C] 12.00 80.01
Velocity [m/s] 0 1.663
Velocity (X) [m/s] -1.573 0.419
Velocity (Y) [m/s] -1.552 0.381
Velocity (Z) [m/s] -0.208 0.559
Velocity RRF [m/s] 0 1.663
Velocity RRF (X) [m/s] -1.573 0.419
Velocity RRF (Y) [m/s] -1.552 0.381
Velocity RRF (Z) [m/s] -0.208 0.559
Vorticity [1/s] 0.02 965.43
Relative Pressure [Pa] -1544.77 745.39
Shear Stress [Pa] 0 19.53
Bottleneck Number [ ] 3.4335461e-14 1.0000000
Heat Transfer Coefficient 0 0

5
Fluid Flow Simulation Report
[W/m^2/K]
ShortCut Number [ ] 3.5628904e-13 1.0000000
Surface Heat Flux [W/m^2] 0 0
Surface Heat Flux 0 0
(Convective) [W/m^2]
Total Enthalpy Flux [W/m^2] -1.168e+09 1.446e+09
Acoustic Power [W/m^3] 0 8.472e-16
Acoustic Power Level [dB] 0 0

2.3 Results

2.4 Conclusion

Lorem ipsum dolor sit amet, consectetur adipiscing elit. Ut a pulvinar lacus. Vivamus adipiscing adipiscing eleifend.
Pellentesque eget ante in ante suscipit gravida in non lorem. Suspendisse hendrerit sagittis lacus non aliquam. Proin
pellentesque, lorem quis consequat porta, lectus nunc vestibulum lectus, nec rhoncus libero dui ut felis. Vestibulum eu
aliquet tellus. Curabitur suscipit ornare sem. Suspendisse pulvinar pharetra ultrices. Suspendisse a quam massa

6
Fluid Flow Simulation Report

3 Appendix
3.1 Material Data

Engineering Database
Liquids
Water
Path: Liquids Pre-Defined
Density
Density[kg/m^3]

Temperature[°C]

Dynamic viscosity
Dynamic viscosity[Pa*s]

Temperature[°C]

7
Fluid Flow Simulation Report
Specific heat (Cp)
Specific heat (Cp)[J/(kg*K)]

Temperature[°C]

Thermal conductivity
Thermal conductivity[W/(m*K)]

Temperature[°C]

Cavitation effect: Yes


Temperature: -273.15 °C
Saturation pressure: 0 Pa
Radiation properties: No

You might also like