1. Steady State Heat Transfer (no mass transport) Chapter 3

2. Training Manual Inventory #001445 March 15, 2001 3-2 Steady-State Heat Transfer When the flow of heat does not vary with time, heat transfer is referred to as steady-state. Since the flow of heat does not vary with time, the temperature of the system and the thermal loads on the system also do not vary with time. From the First Law of Thermodynamics, the steady-state heat balance can be expressed simply as: energy in - energy out = 0

3. Training Manual Inventory #001445 March 15, 2001 3-3 Steady-State Heat Transfer Governing Equation For steady-state heat transfer, the differential equation expressing thermal equilibrium is: The corresponding finite element equation expressing nodal equilibrium is:

4. Training Manual Inventory #001445 March 15, 2001 3-4 Types of Thermal Loads and Boundary Conditions Temperature –is a DOF constraint on a specific region of a model used to impose a known, fixed temperature. Uniform Temperature –can be applied to all nodes that do not already have a temperature constraint. It may be used to set an initial temperature only, not a constraint, on all nodes in the first substep of a steady-state or transient analysis. It can also be used to evaluate initial values of temperature-dependent material properties in a non-linear analysis.

5. Training Manual Inventory #001445 March 15, 2001 3-5 Types of Thermal Loads and Boundary Conditions Heat Flow Rate –is a concentrated nodal load. A positive heat flow rate indicates energy is being supplied to the model. Heat flow rate may also be specified on keypoints. This type of load is typically applied when convection and heat flux cannot be used. Use care when applying this load to regions with large mismatches in thermal conductivity. Convection –is a surface load applied on exterior surfaces of a model to simulate heat transfer between a surface and surrounding fluid.

6. Training Manual Inventory #001445 March 15, 2001 3-6 Types of Thermal Loads and Boundary Conditions Heat Flux –is also a surface load. It is used when the heat flow rate across a surface is known. A positive value of heat flux indicates heat flux is being supplied to the model. Heat Generation Rate –is applied as a body load to represent heat generated within a body, and has units of heat flow rate per unit volume.

7. Training Manual Inventory #001445 March 15, 2001 3-7 Types of Thermal Loads and Boundary Conditions ANSYS Thermal Loads are grouped into four general categories: 1.DOF Constraint - specified DOF (temperature) value 2.Force Load - concentrated load (heat flow) applied at a point 3.Surface Load - distributed load (convection,heat flux) over a surface 4.Body Load - volumetric or field load (heat generation)

8. Training Manual Inventory #001445 March 15, 2001 3-8 Types of Thermal Loads and Boundary Conditions

9. Training Manual Inventory #001445 March 15, 2001 3-9 Types of Thermal Loads and Boundary Conditions General Notes on Thermal Loads and Boundary Conditions In ANSYS, boundaries that have no applied loads are treated as adiabatic (perfectly insulated) by default. Symmetry boundary conditions are imposed by letting the boundaries be adiabatic. If the temperature of a region of the model is known, then it can be fixed at that value. Reaction heat flow rates are only available at fixed temperature DOF’s.

10. Training Manual Inventory #001445 March 15, 2001 3-10 Thermal Analysis Template Building the Model –Specify title and jobname. –Record units, if desired. –Enter the Preprocessor Define element type(s), check keyoptions. Define real constants, if required. Define material properties. Create or Import geometry. Mesh.

11. Training Manual Inventory #001445 March 15, 2001 3-11 Thermal Analysis Template In the Solution Processor –Define analysis type, check analysis options. –Apply loads and boundary conditions. –Specify load step options. –Execute the solution.

12. Training Manual Inventory #001445 March 15, 2001 3-12 Thermal Analysis Template Review the Results –Start general postprocessor and/or time history postprocessor. –Review results by listing, plotting, etc. –Review appropriate error measures –Verify the solution.

13. Training Manual Inventory #001445 March 15, 2001 3-13 A listing of all commands executed can be found in the jobname.log file. GUI and ANSYS Commands ANSYS is a command driven program. ANSYS commands may be input manually, created using the GUI (Graphical User Interface) or both. The GUI provides an easy way for users to interact with the ANSYS program. The GUI generates ANSYS commands based on the user’s menu picks.

14. Training Manual Inventory #001445 March 15, 2001 3-14 GUI and ANSYS Commands Review the ANSYS output window to see the execution of the commands and text output.

15. Training Manual Inventory #001445 March 15, 2001 3-15 Follow the highlighted boxes for the steps specific to this example problem. Basic Description A long steel tube with rectangular fins receives heat by convection from a hot gas flowing inside the tube. The outer surface is exposed to ambient air, and heat flux is being extracted at the fin tips. An ANSYS input file for this example is provided in Appendix B Steady State Heat Transfer Example Problem Description Details of each step in the analysis process will be illustrated with the use of a simple example.

16. Training Manual Inventory #001445 March 15, 2001 3-16 Steady State Heat Transfer Example Problem Description Problem Description: The temperature of the hot gas is 600°F. The interior film coefficient is 0.40 BTU/hrin 2 °F. The ambient air temperature is 100 °F. The exterior film coefficient is 0.025 BTU/hrin 2 °F. Each fin is subject to a heat flux of -20 BTU/hrin 2 at the tip. Analysis Goals: Analyze the smallest repeatable section and determine the following: 1) Temperature distribution. 2) Convection heat loss from upper and lower fin surfaces.

17. Training Manual Inventory #001445 March 15, 2001 3-17 A cut cross-section is shown below. Steady State Heat Transfer Example Problem Description Modeling Guidelines: Use surface effect elements for the interior convection loads. Use “convection on lines” to apply convection to the exterior surfaces of the fins. Apply heat flux at the fin tip. Assume the finned tube is LONG, and neglect effects at the ends of the tube. Model the smallest repeatable section.

18. Training Manual Inventory #001445 March 15, 2001 3-18 Adiabatic symmetry boundary Heat Flux at tip of fin Heat Flux at tip of fin Convection Surfaces Convection Surfaces Convection Surfaces Convection Surfaces Note simplification to the smallest repeatable 2D geometry. Note simplification to the smallest repeatable 2D geometry. Steady State Heat Transfer Example Problem Description

19. Training Manual Inventory #001445 March 15, 2001 3-19 Follow the highlighted boxes for the steps specific to this example problem. Steady State Heat Transfer Example Problem Description Guidelines for steady-state heat transfer example: Use smallest repeatable section to determine the following: –temperature distribution in the tube/fin –convection heat loss from the tube/fin –plot of temperature variation along the tube/fin surface. Mesh using axisymmetric PLANE55 elements. Use surface effect elements SURF151 with extra node option on the inner diameter of the tube. Assume constant, isotropic material properties. No temperature-dependent properties.

20. Training Manual Inventory #001445 March 15, 2001 3-20 Building the Model The first phase of thermal analysis includes building the model and meshing. In this section, we will: –Specify jobname and title. –Record units used. –Enter the Preprocessor Define element types and keyoptions. Review real constant definition. Define material properties. Create geometry. Mesh the model.

21. Training Manual Inventory #001445 March 15, 2001 3-21 Building the Model Setting Preferences for the GUI Use the Preferences option to activate GUI filtering; only menus related to thermal analysis will be visible and usable. If not set, menus for all disciplines will be active. Activate thermal filtering for this example, click “OK”. Activate thermal filtering for this example, click “OK”.

22. Training Manual Inventory #001445 March 15, 2001 3-22 Building the Model Specifying a Jobname Define a unique jobname to distinguish one set of analysis files from another. All files will have the name jobname.ext. Click on YES to begin writing new log and error files named jobname.log and jobname.err. Change jobname to “stltube”

23. Training Manual Inventory #001445 March 15, 2001 3-23 Building the Model Specifying a Title Define a descriptive title for your analysis. The title will be printed at the bottom of your plots, and is written to the load step files and the results file. Enter a Title: “Example - Steel Tube with Fins” and click “OK”.

24. Training Manual Inventory #001445 March 15, 2001 3-24 Building the Model Units Use the /UNITS command to record units used throughout the analysis. Record the units for this example as British/Inches, abbreviated “bin” Except for magnetic field analysis, you do not need to “tell” ANSYS which system of units you will be using. However, you may record the system of units used using the /UNITS command. Once you have decided which system of units to use, BE CONSISTENT. ANSYS does not perform any units conversion. The system of units selected will affect your solid model, material properties, real constants, and loads. No units conversion is done if a new /UNITS command is issued.

25. Training Manual Inventory #001445 March 15, 2001 3-25 Building the Model Units For more information on the /UNITS command, use the on-line documentation. To access help, type “help,xxxxx” in the input window; “xxxxx” can be an element number (77), command (/units), or element class (solid). Or, use the UtilityMenu>>Help pulldown. Enter “help, /UNITS” in the input window to access on-line documentation.

26. Training Manual Inventory #001445 March 15, 2001 3-26 Building the Model Units

27. Training Manual Inventory #001445 March 15, 2001 3-27 Now, we are ready to begin preprocessing… Remember, follow the highlighted boxes for steps specific to the example problem. Steady-state heat transfer example. Building the Model

28. Training Manual Inventory #001445 March 15, 2001 3-28 Preprocessing: Building the Model Defining an Element Type Define element type(s) to be used for the analysis. Begin element type definition for the example problem. Note there are currently no defined element types. Click “Add….” to begin.

29. Training Manual Inventory #001445 March 15, 2001 3-29 Preprocessing: Building the Model Defining an Element Type Use the HELP button to get more information on the element library. By default, the first element type defined is assigned Element Type Reference Number 1. Since GUI Preferences were set for thermal analysis, only thermal elements are shown. Then choose an element type within that category First choose a category Select Thermal Solid PLANE55 for element type 1, click “Apply”.

30. Training Manual Inventory #001445 March 15, 2001 3-30 Preprocessing: Building the Model Reviewing and Choosing Keyoptions Keyoptions Keyoptions or KEYOPTs are options associated with element types. Review or change the keyoptions for the element type defined by choosing “Options” as shown: Check default keyoptions for this element type, PLANE55.

31. Training Manual Inventory #001445 March 15, 2001 3-31 Preprocessing: Building the Model Reviewing and Choosing Keyoptions Use the menu pull-downs to reveal options available for a particular element, and pick the appropriate value. Change element behavior setting. This example requires axisymmetric element behavior. The default is planar.

32. Training Manual Inventory #001445 March 15, 2001 3-32 Preprocessing: Building the Model Surface Effect Elements Surface Effect Elements - An Introduction Surface effect elements act as a “skin” on the faces of solid elements and are frequently used to apply loads. Surface effect elements provide added flexibility when defining a surface load, particularly when both convection and heat flux occur on the same region. An optional discrete node, offset from the surface of the model, can be used to represent the bulk temperature of a surrounding fluid. This “extra” node is also convenient for results evaluation.

33. Training Manual Inventory #001445 March 15, 2001 3-33 Preprocessing: Building the Model Surface Effect Elements Surface Effect Elements - An Introduction Surface effect elements can be used to apply heat generation loads. Surface effect elements are convenient to use when the film coefficient varies with temperature; keyoption settings provide different options for their evaluation. NOTE: Surface effect elements will be discussed in greater detail in Chapter 7.

34. Training Manual Inventory #001445 March 15, 2001 3-34 Preprocessing: Building the Model Surface Effect Elements Surface Effect Elements and Convection A convection load may be applied directly to the surface effect elements, the solid elements, or the solid model entities. Using the “extra node” option with SURF151 allows specification of a nodal temperature at the “extra node”, which actually represents the bulk fluid temperature. NOTE: This example problem does not actually require the use of surface effect elements because there is only constant convection (with known Hf and Tb) on each surface. However, the use of the surface effect elements on the inner diameter of the pipe will allow us to more easily evaluate the heat loss/gain by convection during postprocessing.

35. Training Manual Inventory #001445 March 15, 2001 3-35 Preprocessing: Building the Model Defining an Element Type Note the second element type defined is assigned Element Type Reference Number 2 automatically. Define thermal surface effect element, SURF151. This is the second element type used in the example problem.

36. Training Manual Inventory #001445 March 15, 2001 3-36 Preprocessing: Building the Model Reviewing and Choosing Keyoptions Check the default settings for the SURF151element. Highlight Type 2, and click “Options”.

37. Training Manual Inventory #001445 March 15, 2001 3-37 Preprocessing: Building the Model Reviewing and Choosing Keyoptions Change element behavior from planar to axisymmetric. Note changes to K4, removal of midside nodes and K5, including an extra node for convection calculations. Click “Close” when finished.

38. Training Manual Inventory #001445 March 15, 2001 3-38 Preprocessing: Building the Model Defining and Checking Real Constants Real Constants Real constants are geometric properties specific to a given element type. Not all element types require real constants. Some element types may require real constants only if certain keyoptions are activated. Use ANSYS on-line help to get more information about real constants that may be required for your analysis. The first real constant set defined is assigned Reference Number 1 by default.

39. Training Manual Inventory #001445 March 15, 2001 3-39 Preprocessing: Building the Model Defining and Checking Real Constants Check required real constants. Note there are currently none defined. Click “Add….” to begin. Check required real constants. Note there are currently none defined. Click “Add….” to begin.

40. Training Manual Inventory #001445 March 15, 2001 3-40 Preprocessing: Building the Model Defining and Checking Real Constants To define real constants: –first highlight the element type with which the real constant set is associated –then, define the real constant set by filling in values in the dialog box provided. No real constants are required for either element type for the example problem. No real constants are required for either element type for the example problem. NOTE: Thickness must be specified if HGEN loads are applied to surface effect elements.

41. Training Manual Inventory #001445 March 15, 2001 3-41 Preprocessing: Building the Model Defining and Checking Material Properties General Notes on Material Properties for Steady-State Thermal Analysis –For a steady state analysis, thermal material property data must be input for thermal conductivity “k” as KXX, and optionally KYY, KZZ. –KYY and KZZ default to KXX if not defined by the user. –Density (DENS) and specific heat (C) or enthalpy (ENTH) are not required for a steady-state analysis without mass transport of heat. –Temperature-dependent material conductivity, k, makes a thermal analysis non-linear. –Temperature-dependent film coefficients are treated as material properties.

42. Training Manual Inventory #001445 March 15, 2001 3-42 Preprocessing: Building the Model Defining and Checking Material Properties Options for Definition of Material Properties in ANSYS: –Fill in values in the appropriate dialog boxes after selecting a material behavior option. –Read in material properties from the standard ANSYS material library, or a user-defined material library. After defining material properties, you may also write material data to a file for future use.

43. Training Manual Inventory #001445 March 15, 2001 3-43 Preprocessing: Building the Model Defining and Checking Material Properties To read material properties from a Material Library, simply indicate the directory and file containing the data.

44. Training Manual Inventory #001445 March 15, 2001 3-44 Preprocessing: Building the Model Defining and Checking Material Properties To input material data manually, first select Material Models and double-click the tree structure to get to the material behavior required for this analysis (Thermal, Conductivity, Isotropic) … The material type used for this example is constant isotropic. The first material defined is assigned reference number 1 by default.

45. Training Manual Inventory #001445 March 15, 2001 3-45 Preprocessing: Building the Model Defining and Checking Material Properties Then, fill in required value in the dialog box … For a steady-state thermal analysis with constant isotropic properties, only KXX is required. Thermal conductivity of steel used in this example is 0.75 BTU/hr-in-°F Thermal conductivity of steel used in this example is 0.75 BTU/hr-in-°F

46. Training Manual Inventory #001445 March 15, 2001 3-46 Preprocessing: Building the Model Temperature-Dependent Material Properties For temperature-dependent material properties, click Add Temperature to include additional temperature dependent values… Sample only. Do not use this data.

47. Training Manual Inventory #001445 March 15, 2001 3-47 Preprocessing: Building the Model Temperature-Dependent Material Properties Click the Graph button to plot a graph of Property v. Temperature… Sample only. Do not use this data.

48. Training Manual Inventory #001445 March 15, 2001 3-48 Preprocessing:Building the Model Using Temperature-Dependent Material Properties How does ANSYS use this data? Temperature-dependent material properties are evaluated once per element. The material properties are assumed to be constant over the volume of the element. The temperature used for a given element is:

49. Training Manual Inventory #001445 March 15, 2001 3-49 Preprocessing: Building the Model Listing Material Properties Material properties may be easily listed by making the following menu selections… Temperature dependent material properties can also be listed

50. Training Manual Inventory #001445 March 15, 2001 3-50 Preprocessing: Building the Model Deleting Material Properties Material properties may be deleted individually, or for multiple materials by using the Material Model GUI:

51. Training Manual Inventory #001445 March 15, 2001 3-51 Preprocessing: Building the Model Using Imported Geometry Geometry may be imported from CAD program part files or standard data exchange formatted files. To import geometry, use the File>>Import menu picks: NOTE: The sample dialog box shown here corresponds to one method of IGES file import.

52. Training Manual Inventory #001445 March 15, 2001 3-52 Preprocessing: Building the Model Creating the Geometry Geometry may be created in ANSYS. Here primitives are used to generate geometry for our example problem. Create two independent areas using primitives, and input the dimensions as shown in the problem description.

53. Training Manual Inventory #001445 March 15, 2001 3-53 Preprocessing: Building the Model Creating Geometry Enter the coordinates of the corners of each rectangle. ANSYS will create the rectangle and its associated lines, and keypoints. Choosing “Apply” keeps the dialog box open. Choosing “OK”closes the dialog box.

54. Training Manual Inventory #001445 March 15, 2001 3-54 Area plot This plot is produced automatically by ANSYS after creating the two independent rectangles. The image is automatically sized to fit into the graphics window. Preprocessing: Building the Model Creating Geometry

55. Training Manual Inventory #001445 March 15, 2001 3-55 Preprocessing: Building the Model Creating Geometry Boolean operations such as intersect, add, subtract, divide, glue, overlap, and partition can also be used to manipulate geometry. Apply the Booleans>>Overlap>>Areas command to produce the desired geometry.

56. Training Manual Inventory #001445 March 15, 2001 3-56 Preprocessing: Building the Model Creating the Geometry “Pick All” selects both areas for overlapping and executes the command.

57. Training Manual Inventory #001445 March 15, 2001 3-57 Preprocessing: Building the Model Creating the Geometry Use the PlotControls>>Numbering commands, to turn on plotting of area numbers. Show with both colors and numbers (/NUM). To see individual entities clearly, turn on numbering using the Utility Menu.

58. Training Manual Inventory #001445 March 15, 2001 3-58 Preprocessing: Building the Model Creating the Geometry Plot of areas after overlap, with area numbering turned on, and shown with both colors and numbers.

59. Training Manual Inventory #001445 March 15, 2001 3-59 Preprocessing: Building the Model General Notes on Boolean Operations By default, input entities of a Boolean operation are deleted after the operation. Deleted entity numbers become “free”. That is, they will be reassigned to new entities created after the Boolean operation, starting with the lowest available number. When overlapping areas, a new area is created which is equal to the common area of the original entities. New areas are created by trimming the original areas to make room for the new area. All areas share common lines and keypoints. To review procedures for Boolean Operations, check the following documentation: –ANSYS On-line Help –ANSYS Modeling and Meshing Guide

60. Training Manual Inventory #001445 March 15, 2001 3-60 Preprocessing: Building the Model Defining Attributes Element Attributes Element attributes are model characteristics that must be assigned prior to meshing. They include: –Material properties –Element types –Real constants –Element coordinate systems Each specific type of attribute defined in a model will have a unique reference number.

61. Training Manual Inventory #001445 March 15, 2001 3-61 Preprocessing: Building the Model Defining Attributes Element Attributes (continued) Element attributes can be easily assigned under Attributes>>Define, or using the MeshTool. The MeshTool is often a more convenient approach since meshing controls, which are normally the next step in the processing sequence, are also set using the MeshTool. When using multiple element types, material or real constants, be sure to match attributes to the appropriate region of the model. Element attributes may be listed and plotted for model checking. Attributes can be set globally, or assigned to specific volumes, areas, lines, and keypoints prior to meshing.

62. Training Manual Inventory #001445 March 15, 2001 3-62 Preprocessing: Building the Model Defining Attributes To set Attributes using the MeshTool: Select an item then SET attributes.

63. Training Manual Inventory #001445 March 15, 2001 3-63 Preprocessing: Building the Model Defining Model Attributes When setting attributes, use the pull-down menus to reveal options, and pick the appropriate values. NOTE: You must already have defined element type, material and real constants prior to this operation. NOTE: ESYS is mainly used for orthotropic material definition.

64. Training Manual Inventory #001445 March 15, 2001 3-64 Meshing involves the following steps: 1) Assign element attributes. (element types, real constants, material properties) 2) Set mesh controls. Set the controls that govern the size (mesh density) and shape of the elements to be created during the meshing operation. 3) Save the database (optional). 4) Generate the Mesh. Preprocessing: Building the Model Setting Mesh Controls

65. Training Manual Inventory #001445 March 15, 2001 3-65 Preprocessing: Building the Model Setting Mesh Controls Meshing in ANSYS (continued): If a solid model is meshed without setting any controls, the mesh will have the following characteristics: –it will be free meshed, not mapped. –element sizes will be determined automatically by ANSYS (which may be OK for a first approximation ). –element type will be determined by the dimensionality of the geometry and element types defined (default=1) –element attributes will default to material 1 and real constant set 1. There are many ways to set mesh controls. Refer to the ANSYS Modeling and Meshing Guide for more information. By default meshing attributes are set to element type 1, material 1 and real set 1, therefore, they do not need to be redefined at this point in the sample problem.

66. Training Manual Inventory #001445 March 15, 2001 3-66 Preprocessing: Building the Model Setting Mesh Controls The next step is to set controls that govern the size (mesh density) of the elements that will be created during the meshing operation. Global size is used to create a mesh of uniform element size. Set a global element edge length value of 0.06 for the sample problem.

67. Training Manual Inventory #001445 March 15, 2001 3-67 Preprocessing: Building the Model Meshing the Model Using the MeshTool, specify: 1) Mesh: areas 2) Shape: quad 3) Mesher: mapped; 3 or 4 sided 4) Select “Pick All” in the picking menu 5) Close the MeshTool Using the MeshTool, specify: 1) Mesh: areas 2) Shape: quad 3) Mesher: mapped; 3 or 4 sided 4) Select “Pick All” in the picking menu 5) Close the MeshTool

68. Training Manual Inventory #001445 March 15, 2001 3-68 Preprocessing: Building the Model Meshing the Model The resulting element plot is shown below.

69. Training Manual Inventory #001445 March 15, 2001 3-69 Preprocessing: Building the Model Meshing the Model Continue meshing; generate surface effect elements Notes on generating the surface effect elements: Before generating the surface effect elements, we must do some additional preprocessing : –set attributes to use element type 2, SURF151. –create the “extra node” ( reference KEYOPT5). Surface effect elements will be created using the existing nodes on the surface, and reference the “extra node”. Continue meshing; generate surface effect elements Notes on generating the surface effect elements: Before generating the surface effect elements, we must do some additional preprocessing : –set attributes to use element type 2, SURF151. –create the “extra node” ( reference KEYOPT5). Surface effect elements will be created using the existing nodes on the surface, and reference the “extra node”.

70. Training Manual Inventory #001445 March 15, 2001 3-70 Preprocessing: Building the Model Meshing the Model Define attributes for meshing using the preprocessor menu picks Attributes>>Define as shown: Set element type number to : 2 SURF151 Set element type number to : 2 SURF151

71. Training Manual Inventory #001445 March 15, 2001 3-71 Preprocessing: Building the Model Meshing the Model Change the display to a node plot. NOTE: Since we will be using existing nodes for surface effect element definition, switching to a node plot will make it very easy to select nodes on the surface we are interested in. Change the display to a node plot. NOTE: Since we will be using existing nodes for surface effect element definition, switching to a node plot will make it very easy to select nodes on the surface we are interested in.

72. Training Manual Inventory #001445 March 15, 2001 3-72 Preprocessing: Building the Model Meshing the Model Create the “extra node” required for SURF151 definition. NOTE: Use direct generation to create the extra node. The active coordinate system is global cartesian. Create the “extra node” required for SURF151 definition. NOTE: Use direct generation to create the extra node. The active coordinate system is global cartesian.

73. Training Manual Inventory #001445 March 15, 2001 3-73 Preprocessing: Building the Model Meshing the Model NOTE: Here, randomly assigning a node number of 1000, which is greater than any existing node number, makes it easy to identify the “extra” node. If this field was left blank, the next available node number would be automatically assigned to the new node. NOTE: Location of the “extra” node is arbitrary. We selected x=1.0, y=0.25.

74. Training Manual Inventory #001445 March 15, 2001 3-74 Preprocessing: Building the Model Meshing the Model The node plot is automatically updated to include the new node. Use Box Zoom or any Zoom command to get a better view of the region of interest.

75. Training Manual Inventory #001445 March 15, 2001 3-75 Preprocessing: Building the Model Meshing the Model Now we are ready to create the surface effect elements. Create surface effect elements.

76. Training Manual Inventory #001445 March 15, 2001 3-76 Preprocessing: Building the Model Meshing the Model Use the Box picking option to select only the nodes on the inner tube surface for surface effect element definition.

77. Training Manual Inventory #001445 March 15, 2001 3-77 Preprocessing: Building the Model Meshing the Model Verify that all nine nodes are selected; click “Apply”

78. Training Manual Inventory #001445 March 15, 2001 3-78 Preprocessing: Building the Model Meshing the Model Use graphical picking to select the extra node, or enter 1000 in the input window. Then, click “OK”.

79. Training Manual Inventory #001445 March 15, 2001 3-79 Preprocessing: Building the Model Checking Attributes by Plotting Attributes may be checked by plotting using the Numbering Controls. Simply toggle the on/off buttons to specify which entities should be numbered and with what style. To verify the element types were properly specified, turn on numbering based on element type number.

80. Training Manual Inventory #001445 March 15, 2001 3-80 Preprocessing: Building the Model Checking Attributes by Plotting For the sample problem, check element attribute numbering by plotting to verify element types were correctly specified. NOTE: In this example, we could not have produced type 2, SURF151 elements without changing element attributes prior to meshing. For the sample problem, check element attribute numbering by plotting to verify element types were correctly specified. NOTE: In this example, we could not have produced type 2, SURF151 elements without changing element attributes prior to meshing.

81. Training Manual Inventory #001445 March 15, 2001 3-81 Here, switching to a vector plot will produce a wire-frame plot of elements. Preprocessing: Building the Model Checking Attributes by Plotting

82. Training Manual Inventory #001445 March 15, 2001 3-82 Preprocessing: Building the Model Checking Attributes by Plotting Example showing elements plotted in vector mode, with element types shown with both colors and numbers turned on. Issue the command /SHOW to reset plotting.

83. Training Manual Inventory #001445 March 15, 2001 3-83 Solution Processing Now we are ready to begin the next phase of the analysis process as described in the Thermal Analysis Template; Solution Processing In this phase, we will: –Define the analysis type, and check analysis options –Apply loads and boundary conditions. –Execute the solution. In the Solution Processor

84. Training Manual Inventory #001445 March 15, 2001 3-84 In the Solution Processor Defining the Analysis Type Specify that this is a new analysis, and a steady-state problem. (This is the default).

85. Training Manual Inventory #001445 March 15, 2001 3-85 In the Solution Processor Defining Analysis Options Analysis Options For a linear, steady-state, thermal analysis with a single load step, the only analysis option that may need to be set is the Equation Solver. NOTE: In ANSYS 5.5 and above, when Solution Control is On, the sparse solver is selected by default. Other analysis options such as Newton-Raphson options and Temperature Offset specifications, required for non-linear radiation problems will be discussed in the chapters that follow.

86. Training Manual Inventory #001445 March 15, 2001 3-86 In the Solution Processor Defining Analysis Options Change to Iterative solver for large, 3-D models. Check temperature offset; often required for radiation problems.

87. Training Manual Inventory #001445 March 15, 2001 3-87 * provided there are no mass transport of heat effects In the Solution Processor Defining Analysis Options Solvers: Any of the following solvers can be selected *: Frontal solver (default) Jacobi Conjugate Gradient Solver (JCG) JCG out-of-memory solver Incomplete Cholesky Conjugate Gradient Solver (ICCG) Preconditioned Conjugate Gradient Solver (PCG) PCG out-of-memory solver Iterative (Fast Solution; automatic solver selection option)

88. Training Manual Inventory #001445 March 15, 2001 3-88 In the Solution Processor Defining Analysis Options Iterative (Fast Solution) Option The Fast Solution option can be used for any linear, nonlinear, steady-state or transient thermal analysis with the following exceptions: –may not be used for radiation analysis –not recommended for heat transfer problems involving phase change. NOTE: This option saves time and disk space by eliminating the need to create the jobname.emat, jobname.erot files. Analysis restarts are not possible when using the Fast Solution Option.

89. Training Manual Inventory #001445 March 15, 2001 3-89 In the Solution Processor Defining Analysis Options When using the Fast Solution Option, you must specify an accuracy level.

90. Training Manual Inventory #001445 March 15, 2001 3-90 In the Solution Processor Defining Analysis Options Temperature Offset The temperature offset defines the difference between absolute zero and the zero of the temperature system used. Temperature offset can be specified in the Analysis Options menu, or by using the command TOFFST,value. Temperature offset is optional, but MUST be used when –radiation effects are present, and °F or °C are used. –temperature-dependent heat generation rate (MASS71) is used. The example problem uses BIN units, and degrees Fahrenheit. The Fahrenheit scale is offset 460 degrees from the Rankine scale.

91. Training Manual Inventory #001445 March 15, 2001 3-91 In the Solution Processor Applying Thermal Loads and Boundary Conditions Solid Model Loads and Finite Element Model Loads Thermal loads may be applied to either the solid model, or the FE model, or both. Solid model loads are independent of the mesh. The mesh can be changed but the loads will remain the same. Solid model loads are generally easier to apply than FE loads, especially when using graphical picking. Be careful when applying temperature values to keypoints. Use the expansion option to allow the temperature to be applied to all nodes on the line, rather than just the endpoints. Solid model loads take precedence over FE loads on the same region.

92. Training Manual Inventory #001445 March 15, 2001 3-92 In the Solution Processor Applying Thermal Loads and Boundary Conditions Constant Values and Tabular Input To apply loads using TABLE type array parameters, the same commands and menu paths shown for each type of load are still used. However, instead of specifying an actual value for a particular load, the name of a table array parameter is specified. A new table can be defined during interactive load application by specifying the “new table” option. A series of dialog boxes prompts the user for table definition. These features work with both solid model and finite element model loads. For more details on tabular input, see Chapter 6.

93. Training Manual Inventory #001445 March 15, 2001 3-93 In the Solution Processor Applying Thermal Loads and Boundary Conditions Nodal Temperature Specification Temperature constraints (DOF constraints) are specified in the model where the temperatures are known. Temperatures specified on solid model entities (keypoints, lines, and areas) will be applied to nodes for solution.

94. Training Manual Inventory #001445 March 15, 2001 3-94 NOTE: With GUI Preferences set to thermal only thermal loads appear in the “Apply” menu. In the Solution Processor Applying Thermal Loads and Boundary Conditions Nodal Temperature Specification Temperature constraints (DOF constraints) are specified in the model where the temperatures are known.

95. Training Manual Inventory #001445 March 15, 2001 3-95 In the Solution Processor Applying Thermal Loads and Boundary Conditions Initial Uniform Temperature General Notes: A uniform temperature can be applied to nodes that do not have temperature constraints. There are two primary reasons to set an initial temperature: –as a starting temperature in the first substep of a transient analysis. –to evaluate initial values for temperature dependent material properties in a nonlinear analysis. NOTE:Chapters 4 and 5 cover initial conditions and initial uniform temperature specification in greater detail. NOTE:Chapters 4 and 5 cover initial conditions and initial uniform temperature specification in greater detail.

96. Training Manual Inventory #001445 March 15, 2001 3-96 In the Solution Processor Applying Thermal Loads and Boundary Conditions Nodal Heat Flow Rates Heat flow rates are represented as heat flow per unit time through a node. A positive heat flow indicates heat is being supplied to the model. Heat flow rates are mainly used on line elements (conducting bars, convection links, etc.) in thermal network models where convection and heat fluxes cannot be specified. If both temperature and heat flow rate are defined on the same node, the temperature constraint will take precedence. Heat flow may also be specified on keypoints. Heat flow is considered a concentrated or “force” type of load.

97. Training Manual Inventory #001445 March 15, 2001 3-97 In the Solution Processor Applying Thermal Loads and Boundary Conditions Nodal Heat Flow Rates

98. Training Manual Inventory #001445 March 15, 2001 3-98 In the Solution Processor Applying Thermal Loads and Boundary Conditions Heat Flux Heat flux is a surface load representing heat flow distributed across a surface (heat per unit area). Positive heat flux indicates energy is being supplied to the model. Heat flux loading is only available for solid, shell, and surface effect elements. If a heat flux and a convection load are applied to the same entity, only the last load specified will be used. NOTE: To enable both convection and heat flux on the same region, surface effect elements may be used. (See notes on surface effect elements).

99. Training Manual Inventory #001445 March 15, 2001 3-99 Heat flux will be specified of the tip of the fin for the example problem; applied as a solid model load on lines. In the Solution Processor Applying Thermal Loads and Boundary Conditions Heat Flux

100. Training Manual Inventory #001445 March 15, 2001 3-100 In the Solution Processor Applying Thermal Loads and Boundary Conditions Heat flux specified of the tip of the fin.

101. Training Manual Inventory #001445 March 15, 2001 3-101 In the Solution Processor Applying Thermal Loads and Boundary Conditions A negative value indicates heat is being extracted from the model.

102. Training Manual Inventory #001445 March 15, 2001 3-102 In the Solution Processor Applying Thermal Loads and Boundary Conditions General Notes on Plotting Loads and Boundary Conditions: In the Utility Menu>>Plot Controls>>Symbols, graphical symbols can be turned on/off for applied boundary conditions, reactions, and many other items. This is useful for checking the model both before and/or after solution. In particular: –nodal load symbols can be displayed –various surface loads may be displayed using arrows or face outlines. –body loads can be displayed graphically.

103. Training Manual Inventory #001445 March 15, 2001 3-103 In the Solution Processor Applying Thermal Loads and Boundary Conditions Turn on surface load symbols. Choose heat flux, represented as arrows on the region to which it is applied. Controls plotting of point boundary conditions Controls plotting of point boundary conditions Controls plotting of surface boundary conditions Controls plotting of surface boundary conditions Controls plotting of body loads. Controls plotting of body loads.

104. Training Manual Inventory #001445 March 15, 2001 3-104 In the Solution Processor Applying Thermal Loads and Boundary Conditions The resulting plot shows the label, value, and location of load.

105. Training Manual Inventory #001445 March 15, 2001 3-105 In the Solution Processor Applying Thermal Loads and Boundary Conditions Convection Convection is a surface load which accounts for heat transfer to or from a surrounding fluid medium. Both a film coefficient and a bulk temperature must be specified when defining convection. Convection loading is only available for solid, shell, and surface effect elements. If convection is applied to the same solid model entity (or element) as heat flux, only the last load specified will be used. –NOTE: To enable both convection and heat flux on the same region, surface effect elements may be used. (Refer to Chapters 2 & 7 for discussion of surface effect elements) Convection loads may be applied using tables.

106. Training Manual Inventory #001445 March 15, 2001 3-106 In the Solution Processor Applying Thermal Loads and Boundary Conditions Temperature-Dependent Film Coefficients Film coefficients (HF) may be temperature-dependent. They are treated as temperature-dependent material properties in ANSYS. To use, assign a material number n, and define a temperature table. Then define a film coefficient corresponding to each temperature. When applying the convection load, use a value of -n in the HF value field of the loading command, where n is the assigned material number of the temperature-dependent convection curve. A temperature-dependent film coefficient makes a thermal analysis non-linear.

107. Training Manual Inventory #001445 March 15, 2001 3-107 In the Solution Processor Applying Thermal Loads and Boundary Conditions The example problem requires convection be applied at the external surfaces of the tube and fin. Here, the convection load is applied to the solid model entities.

108. Training Manual Inventory #001445 March 15, 2001 3-108 In the Solution Processor Applying Thermal Loads and Boundary Conditions Pick the two lines for convection loading, and then “Apply”.

109. Training Manual Inventory #001445 March 15, 2001 3-109 In the Solution Processor Applying Thermal Loads and Boundary Conditions Film coefficient and bulk temperature are constant for this example. Input values as shown, then “OK” to close the dialog box. If using a temperature- dependent convection load, enter the -n here

110. Training Manual Inventory #001445 March 15, 2001 3-110 In the Solution Processor Applying Thermal Loads and Boundary Conditions With the legend on, we can clearly see the load label, value and location. Note, convection or flux (but not both) can be shown on a given plot since ANSYS uses the same graphical representation for both surface loads.

111. Training Manual Inventory #001445 March 15, 2001 3-111 In the Solution Processor Applying Thermal Loads and Boundary Conditions Apply the convection load to the surface effect elements on the inner diameter. NOTE: Since these elements lie on top of the PLANE55 elements, load application will be easier if we isolate surface effect elements from the rest of the model. Use Select Logic to select all Type 2 elements, and click “OK”. Apply the convection load to the surface effect elements on the inner diameter. NOTE: Since these elements lie on top of the PLANE55 elements, load application will be easier if we isolate surface effect elements from the rest of the model. Use Select Logic to select all Type 2 elements, and click “OK”.

112. Training Manual Inventory #001445 March 15, 2001 3-112 In the Solution Processor Applying Thermal Loads and Boundary Conditions Listing the elements verifies that all eight surface effect elements (type 2) are currently selected.

113. Training Manual Inventory #001445 March 15, 2001 3-113 Select the SURF151 elements that you want to load. Apply - convection - uniform - on elements (see next slide). Do NOT apply convection on lines –SURF151 elements are not related to the solid model (lines) –you will put the load on the underlying solid elements (I.e. PLANE55) Do NOT apply convection on nodes –both the SURF151 and underlying solid are associated with the nodes on the surface –you will produce double convection loading!! In the Solution Processor Special Considerations for Surface Effect Elements

114. Training Manual Inventory #001445 March 15, 2001 3-114 Convection may be applied on lines, areas, nodes, and elements. In the Solution Processor Applying Thermal Loads and Boundary Conditions Now we will apply the uniform convection load directly to the surface effect elements.

115. Training Manual Inventory #001445 March 15, 2001 3-115 In the Solution Processor Applying Thermal Loads and Boundary Conditions “Pick All” applies the load to all currently selected elements.

116. Training Manual Inventory #001445 March 15, 2001 3-116 In the Solution Processor Applying Thermal Loads and Boundary Conditions Enter the film coefficient for the inside of the tube, and click “OK”to finish. NOTE: The bulk temperature field should be left blank. The bulk fluid temperature will be specified as a temperature constraint on the extra node. Enter the film coefficient for the inside of the tube, and click “OK”to finish. NOTE: The bulk temperature field should be left blank. The bulk fluid temperature will be specified as a temperature constraint on the extra node.

117. Training Manual Inventory #001445 March 15, 2001 3-117 In the Solution Processor Applying Thermal Loads and Boundary Conditions Now apply temperature constraint to the extra node to be 600 F, the bulk fluid temperature.

118. Training Manual Inventory #001445 March 15, 2001 3-118 In the Solution Processor Applying Thermal Loads and Boundary Conditions Use node 1000. after typing keyboard entry

119. Training Manual Inventory #001445 March 15, 2001 3-119 In the Solution Processor Applying Thermal Loads and Boundary Conditions Input 600 degrees.

120. Training Manual Inventory #001445 March 15, 2001 3-120 In the Solution Processor Applying Thermal Loads and Boundary Conditions Remember to select all entities before executing the solution. Select everything to include all elements and loads in the solution.

121. Training Manual Inventory #001445 March 15, 2001 3-121 In the Solution Processor Applying Thermal Loads and Boundary Conditions Change surface load symbol plotting to show the convective film coefficient. Verify the loading graphically.

122. Training Manual Inventory #001445 March 15, 2001 3-122 In the Solution Processor Applying Thermal Loads and Boundary Conditions Create an element plot. An element plot provides a quick check of the applied convection load. It shows all active elements, applied temperature at the extra node, and convection load on surface effect elements on the inner diameter of the tube.

123. Training Manual Inventory #001445 March 15, 2001 3-123 In the Solution Processor Applying Thermal Loads and Boundary Conditions Heat Generation Heat generation rates are body loads which represent heat generated within an element (heat flow rate per unit volume). Heat generation rates may be applied on solid model entities, and finite element entities. Loads are converted to elemental loads. A uniform heat generation rate can be applied to all nodes in a model with one command (BFUNIF). Heat generation can also be applied with tables. NOTE: Loading using the BFA and BFK commands distribute the loads to elements differently. Review these commands before using.

124. Training Manual Inventory #001445 March 15, 2001 3-124 In the Solution Processor Applying Thermal Loads and Boundary Conditions Apply heat generation using the appropriate menu picks. This shows application of heat generation to areas.

125. Training Manual Inventory #001445 March 15, 2001 3-125 In the Solution Processor Transferring Solid Model Loads to FE model Transfer of solid model thermal loads and boundary conditions to the finite element model occurs automatically when a solution is requested (SOLVE command ). Solid model thermal loads and boundary conditions may also be transferred manually, either by load category, or all at the same time. For example, you may manually transfer: –only DOF constraints (temperatures) –only Force loads (heat flow) –only Surface loads (convection/heat flux) –only Body loads ( heat generation) –all Solid Model loads Manual transfer, when used, is typically for model checking.

126. Training Manual Inventory #001445 March 15, 2001 3-126 In the Solution Processor Transferring Solid Model Loads and BC’s Note options for transferring loads to FE model from solid model. The highlighted option transfers all solid model loads. Loads may also be transferred based on load category.

127. Training Manual Inventory #001445 March 15, 2001 3-127 In the Solution Processor Deleting Thermal Loads and Boundary Conditions Loads may be deleted in various ways using the following menu picks: Used to delete loads by category from the entire model. Used to delete loads from specific entities. Delete loads in the same manner as they were applied ( e.g. flux on lines).

128. Training Manual Inventory #001445 March 15, 2001 3-128 In the Solution Processor Listing Thermal Loads and Boundary Conditions Loads may be listed using the Utility Menu picks. Here, a listing of surface loads on all lines shows the heat flux load and convection load on the exterior surface of the tube and fin example problem. NOTE: Recall that the second convection load, on the inside of the tube, was applied to the surface effect elements directly and therefore is not included in this list of surface loads on lines.

129. Training Manual Inventory #001445 March 15, 2001 3-129 After defining all of the loads and load options, the final step in the Solution phase is to initiate the solution. Save the database just before solving. To review ANSYS solution processing and program messages, bring the ANSYS output window forward before executing the solution. In the Solution Processor Getting Ready to Solve

130. Training Manual Inventory #001445 March 15, 2001 3-130 In the Solution Processor Solving a Single Load Step To solve a single load step: Enter the command Solve>>Current LS Review the status window for proper solution option and load step option settings. If ready to solve, click “OK” to execute the solution. Use Solve>>Current LS to begin solution execution.

131. Training Manual Inventory #001445 March 15, 2001 3-131 In the Solution Processor Solving a Single Load Step Review the status window, and click “OK” to solve.

132. Training Manual Inventory #001445 March 15, 2001 3-132 In the Solution Processor Load Step A load step is a set of boundary conditions and load options for which at least one solution is computed. A given ANSYS analysis can consist of either: –A single load step or –Multiple load steps. We will discuss two ways to define and solve multiple load steps: –The multiple solve method –The load step file method

133. Training Manual Inventory #001445 March 15, 2001 3-133 Easiest of the three methods to understand. Disadvantage -- GUI users must wait for each solution to be completed before defining the next. In the Solution Processor The Multiple Solve Method To use the multiple solve method: 1. Specify analysis controls, loads and options for the first load step. 2.Solve (see previous slide) and postprocess if desired. 3.Change the title and loading as required for the next solution. 4.If you have left the solution processor (to do postprocessing for example) since the last solve (e.g., postprocessing), then specify a RESTART to avoid the new analysis overwriting the results file. 5.Solve, and postprocess as desired. 6.Repeat steps 3, 4, and 5 until all load steps are completed.

134. Training Manual Inventory #001445 March 15, 2001 3-134 In the Solution Processor The Load Step File Method Convenient for GUI users solving multiple load steps. Writes loads and options to load step files and, with one command, reads in each file and solves. To use the load step method: 1. Specify analysis controls and specify loads and options for the first load step, change the title. 2.Write load step file. 3.Change loads and options as required for the next load step, change the title. 4.Write next load step file. 5.Repeat steps 3 and 4 for remaining load steps. 6. Solve from load step files. 7. Postprocess NOTE: LSWRITE files may require editing if Solution Control is On

135. Training Manual Inventory #001445 March 15, 2001 3-135 In the Solution Processor Files Created During the Solution For a linear, static single load step analysis, the thermal results file, jobname.rth is written by default when the solution is executed and results are also stored in database memory. By default ANSYS stores end of load step results only. Use Output Controls to force other substep results to be stored. The jobname.out file (ASCII) can also be written if requested.

136. Training Manual Inventory #001445 March 15, 2001 3-136 Once the solution has been obtained, begin postprocessing to check results. Results can be viewed with either the General Postprocessor (POST1), and/or the Time-History Postprocessor (POST26). Postprocessing Reviewing Results POST1 POST26

137. Training Manual Inventory #001445 March 15, 2001 3-137 Postprocessing: Reviewing Results General Postprocessor (POST1) The General Postprocessor, POST1, is used to review results at a particular substep or timestep for the entire model, or for selected entities. For single load step, single substep analyses. Typical output from POST1 includes: –contour displays –vector displays –tabular listings of results –error estimation –load case combinations –results data calculations –path operations

138. Training Manual Inventory #001445 March 15, 2001 3-138 Postprocessing: Reviewing Results Time-History Postprocessor (POST26) The Time-History Postprocessor, POST26, is used to review results at specified points in the model over many time steps. The Time-History Postprocessor can be used to: –produce graphs of results versus time. –produce tables of results versus time. –operate on tables of data More information on POST26 is covered in Chapter 5, Transient Analysis.

139. Training Manual Inventory #001445 March 15, 2001 3-139 Postprocessing: Reviewing Results Postprocessing 101 - Fundamentals What results are stored on the jobname.rth file? Primary Data Items –Nodal temperatures (TEMP) –Nodal Reaction Heat Flow Rates (HEAT) Secondary Data Items –Thermal Fluxes (TFX, TFY, TFZ) –Thermal Gradients (TGX, TGY, TGZ) Special Data Items –Element Table Items –Solution summary items –etc.

140. Training Manual Inventory #001445 March 15, 2001 3-140 Postprocessing: Reviewing Results Postprocessing 101 - Fundamentals When plotting contours of results, you can choose either nodal or element quantities: –Nodal DOF Results are values of temperature calculated directly at nodes. Temperature contours will be continuous across element boundaries which share nodes. –Element Gradient/Flux Results are items derived from the temperature solution (e.g., x component of thermal flux). These quantities are initially computed at element integration points and are then extrapolated to the element’s nodes. Since these quantities are computed on an element-by-element basis and are not averaged at common nodes, contour plots of these items often appear to be discontinuous. –Nodal Gradient/Flux Results are elemental items which are averaged at common nodes. Because there is only one average value at each node (like nodal DOF solution), contours plots of nodal element quantities appear to be continuous.

141. Training Manual Inventory #001445 March 15, 2001 3-141 Postprocessing: Reviewing Results Postprocessing 101 - Fundamentals Getting a summary of load steps/titles on the jobname.rth file: Enter the General Postprocessor to review results for the example problem. Use Results Summary to list and read load steps and titles from the results file. For a nonlinear or transient analysis, there may be several solutions available for review.

142. Training Manual Inventory #001445 March 15, 2001 3-142 Postprocessing: Reviewing Results Postprocessing 101 - Basic Operations Contour plots can be produced for component or resultant quantities based on either the nodal solution or element solution.

143. Training Manual Inventory #001445 March 15, 2001 3-143 Plot Temperatures Postprocessing: Reviewing Results Postprocessing 101 - Basic Operations Plot nodal solution, temperatures

144. Training Manual Inventory #001445 March 15, 2001 3-144 Temperature Plot NOTE: This plot has all model entities selected, including the extra node. Postprocessing: Reviewing Results Postprocessing 101 - Basic Operations

145. Training Manual Inventory #001445 March 15, 2001 3-145 Plotting Temperature Contours Produce a contour plot of temperatures Select all Type 1 (PLANE55) elements for postprocessing Select everything below the selected elements Produce a contour plot of temperatures Select all Type 1 (PLANE55) elements for postprocessing Select everything below the selected elements Postprocessing: Reviewing Results Postprocessing 101 - Basic Operations

146. Training Manual Inventory #001445 March 15, 2001 3-146 Postprocessing: Reviewing Results Postprocessing 101 - Basic Operations Notice the temperature scale is reset.

147. Training Manual Inventory #001445 March 15, 2001 3-147 Plot TFSUM, thermal flux magnitude for the example problem. Postprocessing: Reviewing Results Postprocessing 101 - Basic Operations Plot Thermal Flux

148. Training Manual Inventory #001445 March 15, 2001 3-148 Postprocessing: Reviewing Results Postprocessing 101 - Basic Operations NOTE: Due to the geometric discontinuity in this model (re-entrant corner) flux and gradient results in the corner region are not accurate (singularity exists).

149. Training Manual Inventory #001445 March 15, 2001 3-149 Plot TGSUM, thermal gradient magnitude for the example problem. Note that component options are available as well. Postprocessing: Reviewing Results Postprocessing 101 - Basic Operations

150. Training Manual Inventory #001445 March 15, 2001 3-150 Postprocessing: Reviewing Results Postprocessing 101 - Basic Operations NOTE: Due to the geometric discontinuity in this model (re-entrant corner) flux and gradient results in the corner region are not accurate (singularity exists).

151. Training Manual Inventory #001445 March 15, 2001 3-151 Element solution data (unaveraged) is also available for plotting. Plot TFSUM - unaveraged for the example problem. Postprocessing: Reviewing Results Postprocessing 101 - Basic Operations

152. Training Manual Inventory #001445 March 15, 2001 3-152 NOTE: Due to the geometric discontinuity in this model (re-entrant corner) flux and gradient results in the corner region are not accurate (singularity exists). Note the difference in the element solution plot compared to the smooth contours in the nodal solution plot. This is one way to help gauge mesh error. (See Chapter 2). Postprocessing: Reviewing Results Postprocessing 101 - Basic Operations

153. Training Manual Inventory #001445 March 15, 2001 3-153 Plot TGSUM, unaveraged. Postprocessing: Reviewing Results Postprocessing 101 - Basic Operations

154. Training Manual Inventory #001445 March 15, 2001 3-154 Note the difference in the element solution plot compared to the smooth contours in the nodal solution plot. This is one way to help gauge mesh error. (See Chapter 2). Postprocessing: Reviewing Results Postprocessing 101 - Basic Operations NOTE: Due to the geometric discontinuity in this model (re-entrant corner) flux and gradient results in the corner region are not accurate (singularity exists).

155. Training Manual Inventory #001445 March 15, 2001 3-155 Predefined vector plots include thermal flux vectors and thermal gradient vectors. Vector Plot of Thermal Gradient Postprocessing: Reviewing Results Postprocessing 101 - Basic Operations

156. Training Manual Inventory #001445 March 15, 2001 3-156 Postprocessing: Reviewing Results Postprocessing 101 - Basic Operations NOTE: Due to the geometric discontinuity in this model (re-entrant corner) flux and gradient results in the corner region are not accurate (singularity exists).

157. Training Manual Inventory #001445 March 15, 2001 3-157 thermal flux Postprocessing: Reviewing Results Postprocessing 101 - Basic Operations Produce Vector Plot of Thermal Flux

158. Training Manual Inventory #001445 March 15, 2001 3-158 Postprocessing: Reviewing Results Postprocessing 101 - Basic Operations NOTE: Due to the geometric discontinuity in this model (re-entrant corner) flux and gradient results in the corner region are not accurate (singularity exists).

159. Training Manual Inventory #001445 March 15, 2001 3-159 For the exterior surfaces, use of the element table is required, since we did not use surface effect elements. There are a few steps involved: –select the elements (PLANE55 solid elements) –create an element table item to store heat flow rate due to convection for each element face for each of these elements. (PLANE55 has four faces so this must be done a total of four times). –sum the element table item to get the total. Next, we’ll use two different methods to check results. First, we’ll obtain the heat lost through the exterior tube/fin surfaces to the surrounding fluid. Then we’ll check and the heat input from the hot fluid at the inner tube surface. These values should be equal. Postprocessing: Reviewing Results Postprocessing 101 - Basic Operations

160. Training Manual Inventory #001445 March 15, 2001 3-160 To get similar results data on the interior surface where surface effect elements were applied, there is only one step required: –list the reaction solution at the extra node. Postprocessing: Reviewing Results Postprocessing 101 - Basic Operations

161. Training Manual Inventory #001445 March 15, 2001 3-161 The Element Table - A Quick Review In ANSYS, the element table serves two main functions. –First, it is a tool for performing arithmetic operations on results data. –Secondly, it allows access to certain element results data that are not otherwise directly accessible. The element table can be thought of as a spreadsheet, where each row represents a particular element, and each column contains a specific data item for the elements. For some elements, the ETABLE is the only way to access certain results data (COMBIN, LINK, etc…). Postprocessing: Reviewing Results Postprocessing 101 - Basic Operations

162. Training Manual Inventory #001445 March 15, 2001 3-162 Request help on PLANE55 elements to get a listing of ETABLE items available. Remember the Heat Rate item applies to convection only. NOTE: FC1 refers to element face 1, FC2 to face 2 etc. Data must be collected for all faces of all PLANE55 elements to be complete. Request help on PLANE55 elements to get a listing of ETABLE items available. Remember the Heat Rate item applies to convection only. NOTE: FC1 refers to element face 1, FC2 to face 2 etc. Data must be collected for all faces of all PLANE55 elements to be complete. Postprocessing: Reviewing Results Postprocessing 101 - Basic Operations

163. Training Manual Inventory #001445 March 15, 2001 3-163 Begin Element Table definition to collect the required data. Postprocessing: Reviewing Results Postprocessing 101 - Basic Operations

164. Training Manual Inventory #001445 March 15, 2001 3-164 Define ETABLE items using sequence number. Data is collected from each element face for all PLANE55 elements. Postprocessing: Reviewing Results Postprocessing 101 - Basic Operations

165. Training Manual Inventory #001445 March 15, 2001 3-165 Postprocessing: Reviewing Results Postprocessing 101 - Basic Operations Continue to define ETABLE items heat2, heat3, and heat4 using NMISC 11, 17 and 23.

166. Training Manual Inventory #001445 March 15, 2001 3-166 Postprocessing: Reviewing Results Postprocessing 101 - Basic Operations Entries in the current Element Table:

167. Training Manual Inventory #001445 March 15, 2001 3-167 Postprocessing: Reviewing Results Postprocessing 101 - Basic Operations Element table data may be listed and plotted.

168. Training Manual Inventory #001445 March 15, 2001 3-168 Listing the sum of each item produces the desired results quantities. Postprocessing: Reviewing Results Postprocessing 101 - Basic Operations

169. Training Manual Inventory #001445 March 15, 2001 3-169 Use the ETABLE data to check results. Postprocessing: Reviewing Results Postprocessing 101 - Basic Operations Sum of ETABLE entries represents heat lost by convection through PLANE55 elements. When added to heat flux lost at the fin tip, the result should equal the heat input to the system by the hot fluid at the tube inner diameter. To calculate heat lost at fin tip, calculate the surface area and multiply by the heat flux value:

170. Training Manual Inventory #001445 March 15, 2001 3-170 Continued….Using the ETABLE data to check results. In the example, the total heat lost from exterior surfaces = convection loss + flux loss Next, we’ll compare this result to the reaction solution data from the extra node of the surface effect elements. Postprocessing: Reviewing Results Postprocessing 101 - Basic Operations

171. Training Manual Inventory #001445 March 15, 2001 3-171 After completion of the calculation, use Select >>Everything to continue postprocessing the entire model. Postprocessing: Reviewing Results Postprocessing 101 - Basic Operations

172. Training Manual Inventory #001445 March 15, 2001 3-172 Now, to find the heat flow rate into the tube, simply display the reaction solution. Postprocessing: Reviewing Results Postprocessing 101 - Basic Operations

173. Training Manual Inventory #001445 March 15, 2001 3-173 Here, the reaction solution is shown for node 1000, (the “extra node” used in the surface effect element definition). Now, compare results from the two methods: 1.) ETABLE (for convection) + Heat Flux calculation = 270.74 2.) Reaction Solution for extra node = 270.74 The answers match as expected. Now, compare results from the two methods: 1.) ETABLE (for convection) + Heat Flux calculation = 270.74 2.) Reaction Solution for extra node = 270.74 The answers match as expected. Postprocessing: Reviewing Results Postprocessing 101 - Basic Operations

174. Training Manual Inventory #001445 March 15, 2001 3-174 Listing Results Instead of plotting, list the nodal temperatures. Postprocessing: Reviewing Results Postprocessing 101 - Basic Operations

175. Training Manual Inventory #001445 March 15, 2001 3-175 This is an “unsorted” results listing. It lists the nodes in numerical order by default. Postprocessing: Reviewing Results Postprocessing 101 - Basic Operations Listing Results (continued)

176. Training Manual Inventory #001445 March 15, 2001 3-176 Now sort the nodal data based on the nodal temperatures in descending order, and list. Postprocessing: Reviewing Results Postprocessing 101 - Basic Operations Lists may be sorted based on chosen data items.

177. Training Manual Inventory #001445 March 15, 2001 3-177 Review the list, which now shows descending temperatures. NOTE: Since the entire model is selected, we can also see the applied temperature at node 1000. Review the list, which now shows descending temperatures. NOTE: Since the entire model is selected, we can also see the applied temperature at node 1000. Postprocessing: Reviewing Results Postprocessing 101 - Basic Operations Sorted Listings (continued)

178. Training Manual Inventory #001445 March 15, 2001 3-178 Restore the list to the original order. Postprocessing: Reviewing Results Postprocessing 101 - Basic Operations Un-sorting restores data to the original order.

179. Training Manual Inventory #001445 March 15, 2001 3-179 Element data may be sorted also. Postprocessing: Reviewing Results Postprocessing 101 - Basic Operations

180. Training Manual Inventory #001445 March 15, 2001 3-180 Query Results Querying results enables you to request numerical results by graphical picking. Values are shown right on top of an existing plot. The plot does not have to match the data type being queried. Postprocessing: Reviewing Results Postprocessing 101 - Basic Operations

181. Training Manual Inventory #001445 March 15, 2001 3-181 Postprocessing: Reviewing Results Postprocessing 101 - Basic Operations Use this button to automatically generate 3-D annotation.

182. Training Manual Inventory #001445 March 15, 2001 3-182 Basic Path Operations Produce a plot of temperature as a function of distance along the exterior surfaces of the model. Postprocessing: Reviewing Results Postprocessing 101 - Basic Operations

183. Training Manual Inventory #001445 March 15, 2001 3-183 Postprocessing: Reviewing Results Postprocessing 101 - Basic Operations Pick 3 corner nodes to define the path. 3 2 1

184. Training Manual Inventory #001445 March 15, 2001 3-184 The path can be given a unique name. Name the path “top” Postprocessing: Reviewing Results Postprocessing 101 - Basic Operations

185. Training Manual Inventory #001445 March 15, 2001 3-185 Label the data and map the desired data onto the path. Select Temperature to map onto path. Note the option to average results across element for quantities that are discontinuous; call the data “toptemp” Postprocessing: Reviewing Results Postprocessing 101 - Basic Operations

186. Training Manual Inventory #001445 March 15, 2001 3-186 Create the plot. Produce a plot of “toptemp” data by selecting it from the list of items to be graphed. Postprocessing: Reviewing Results Postprocessing 101 - Basic Operations XG, YG, ZG and S are predefined variables XG, YG, ZG and S are predefined variables

187. Training Manual Inventory #001445 March 15, 2001 3-187 Note the path is 1.75 inches long. Postprocessing: Reviewing Results Postprocessing 101 - Basic Operations

188. Training Manual Inventory #001445 March 15, 2001 3-188 Clearing Path Data Postprocessing: Reviewing Results Postprocessing 101 - Basic Operations