menu.data2

Triangular mesh processing tool, currently very few people use this software, but it allows us to gr

  OL:BOUNDARY
  OR:ELEMENT
  ORPT:MESH
  ORPT:SETS
  PAD:GRAPHICS
  PAINFO:MISC
  PARA:MISC
  PATCH:MESH
  PB:MESH
  PBS:MESH
  PINFO:PARTS
  PLANE:BOUNDARY
  PLINFO:BOUNDARY
  PM:SPRING/MASS
  POR:MATERIAL
  PORI:MATERIAL
  POSTSCRIPT:GRAPHICS
  PR:FORCE
  PRAMP=:FORCE
  PRI:FORCE
  PROJECT:SURFACE
  PROJCUR:3D CURVE
  PSCUR:3D CURVE
  PTOL:MERGING
  PVPN:SURFACE
  Q:MESH
  R:VIEWING
  RAAD:GRAPHICS
  RABB:INTERFACE
  RACD:3D CURVE
  RAD:GRAPHICS
  RAP:PARTS
  RASD:SURFACE
  RB:RADIATION
  RBB:INTERFACE
  RBBS:INTERFACE
  RBI:RADIATION
  RCD:3D CURVE
  RCDS:3D CURVE
  RE:RADIATION
  READMESH:PARTS
  REI:RADIATION
  REG:BOUNDARY
  REGI:BOUNDARY
  RELAX:MESH
  RELAXI:MESH
  RES:MESH
  RESO:VIEWING
  RESTORE:VIEWING
  RESUME:MISC
  RG:PEEL
  RGI:PEEL
  RGRP:CAD
  RIGBM:MERGING
  RINDEX:GRAPHICS
  RLN:2D CURVE
  RLNS:2D CURVE
  RLV:CAD
  RMSEG:3D CURVE
  ROTATION:DIS/VEL/ACC
  RP:PARTS
  RPS:PARTS
  RRG:PEEL
  RRGI:PEEL
  RSD:SURFACE
  RSDS:SURFACE
  RX:VIEWING
  RY:VIEWING
  RZ:VIEWING
  SAVE:OUTPUT
  SAVEIGES:CAD
  SAVEPART:PARTS
  SC:MATERIAL
  SCALE:VIEWING
  SD:SURFACE
  SDEDGE:3D CURVE
  SDINFO:SURFACE
  SDINT:GRAPHICS
  SET:GRAPHICS
  SETSOR:RADIATION
  SETSORI:RADIATION
  SF:MESH
  SFI:MESH
  SFB:BOUNDARY
  SFBI:BOUNDARY
  SHSO:MATERIAL
  SI:INTERFACE
  SID:INTERFACE
  SII:INTERFACE
  SIINFO:INTERFACE
  SIND:ELEMENT
  SLICE:GRAPHICS
  SMGAP:SURFACE
  SPD:SPRING/MASS
  SPDP:SPRING/MASS
  SPINFO:SPRING/MASS
  SPLINE:3D CURVE
  SPLINT:MESH
  SPP:MESH
  SPRING:SPRING/MASS
  SSF:ELEMENT
  SSFI:ELEMENT
  ST:MERGING
  STP:MERGING
  SUBANG:MISC
  SUPBLK:OUTPUT
  SW:BOUNDARY
  SWI:BOUNDARY
  SYF:BOUNDARY
  SYFI:BOUNDARY
  T:MERGING
  T1:MESH
  T2:MESH
  T3:MESH
  TE:RADIATION
  TEI:RADIATION
  TEMP:RADIATION
  TEPRO:RADIATION
  TF:MESH
  TFI:MESH
  TH:ELEMENT
  THI:ELEMENT
  THIC:ELEMENT
  TITLE:MISC
  TM:RADIATION
  TME:MESH
  TMEI:MESH
  TMI:RADIATION
  TMM:MATERIAL
  TMPLT:MESH
  TP:MERGING
  TPARA:MISC
  TR:MESH
  TRI:MESH
  TRBB:INTERFACE
  TRANS:VIEWING
  TRIAD:GRAPHICS
  TRICENT:MISC
  TRP:BOUNDARY
  TRSD:SURFACE
  TWSURF:3D CURVE
  U:VIEWING
  UNDO:EDIT
  UNFIX:VIEWING
  UNIFM:MESH
  UNIFMI:MESH
  UPDATE:MESH
  USEIGES:CAD
  V:ELECTRIC
  VACC:DIS/VEL/ACC
  VACCC:DIS/VEL/ACC
  VACCS:DIS/VEL/ACC
  VACCI:DIS/VEL/ACC
  VACCCI:DIS/VEL/ACC
  VACCSI:DIS/VEL/ACC
  VCV:RADIATION
  VCVI:RADIATION
  VD:SURFACE
  VE:DIS/VEL/ACC
  VEI:DIS/VEL/ACC
  VELOCITY:DIS/VEL/ACC
  VERBATIM:OUTPUT
  VFL:RADIATION
  VFLI:RADIATION
  VHG:RADIATION
  VHGI:RADIATION
  VI:ELECTRIC
  VPSD:CAD
  VRB:RADIATION
  VRBI:RADIATION
  VTM:RADIATION
  VTMI:RADIATION
  VVHG:RADIATION
  WIGES:CAD
  WRSD:CAD
  X:MESH
  XSCL:VIEWING
  Y:MESH
  YSCL:VIEWING
  Z:MESH
  ZB:VIEWING
  ZF:VIEWING
  ZSCL:VIEWING
  ZTOL:MERGING
  expressions:MISC
  hierarchy:MESH
PART subject commands
  MESH: shape the mesh
  EDIT: modify commands
  GRAPHICS: draws components of part and graphics control parameters
  VIEWING: manipulates the picture
  PEEL: choose components in picture
  DIS/VEL/ACC: acceleration or velocity
  FORCE: force, pressures, and displacement boundary conditions
  BOUNDARY: boundary and constraint conditions
  RADIATION: initial and boundary radiation and temperature assignment
  ELECTRIC: initial, boundary, and interface conditions
  SPRING/MASS: springs, dampers, and point masses
  INTERFACE: (sliding) interface definitions
  MATERIAL: properties and assignment
  ELEMENT: element properties
  DIAGNOSTIC: analyze the mesh
  PARTS: select the present part for the picture and part info
  REPLICATE: part replication and transformation
  MERGING: node merging
  OUTPUT: output format types
  2D CURVE: defines and draws 2D curves
  3D CURVE: defines and draws 3D curves
  SURFACE: surfaces for graphics and geometry
  CAD: import CAD/CAM geometry
  SETS: define sets of nodes, faces, and elements
  MISC: miscellaneous commands
BOUNDARY and constraint commands:
  B: nodal displacement and rotation constraints.
  BI: nodal displacement and rotation constraints by index progression.
  CFC: conditions command for the CF3D output option.
   Each condition is associated with a name.
   The data for the output is then sorted by these identifiers.
    FV for fixed velocity
    FT for fixed temperature
    FSP for fixed species
    OL for an outlet
    IL for an inlet
    WALL for a wall with 0 velocity
    UFL for u-flux
    VFL for v-flux
    WFL for w-flux
    TFL for temperature flux
    SPF for species flux
    OB for obstruction
  CFCI: conditions command by index progression for the CF3D output option.
   Each condition is associated with a name.
   The data for the output is then sorted by these identifiers.
    FV for fixed velocity
    FT for fixed temperature
    FSP for fixed species
    OL for an outlet
    IL for an inlet
    WALL for a wall with 0 velocity
    UFL for u-flux
    VFL for v-flux
    WFL for w-flux
    TFL for temperature flux
    SPF for species flux
    OB for obstruction
  DETP: create detonation points and lighting times for high explosives.
   A line of detonators can also be created.
  FBC: Fluent boundary condition.
  FBCI: Fluent boundary condition by index progressions.
  IL: identifies a face of the mesh as an inlet for fluid flow.
  ILI: identifies a face of the mesh by index progression 
   as an inlet for fluid flow.
  JD: each numbered joint created by this command assigns constraints
   to a set of nodes to be identified later using the JT command.
   A joint can have up to 16 nodes assigned to it.
   Some joint types require less and any additional nodes assigned to
   that joint will be ignored.  When a node is assigned to a numbered joint, it
   is also assigned a sequence number or local node number within
   that joint definition.
   There are two basic types of joints.
   The first basic type (SJ, RJ, CJ, PJ, UJ, and TJ) require a specific set
   of nodes where each node may play a different role in the behavior of
   the joint.
   The second basic type is an arbitrary set of nodes constraints to share
   certain degrees of freedom. The second basic type is simply multiple
   constrained nodes and can also be accomplished using the MPC command
   in the merge phase.
   Nodes are assigned to the joint definition
   using the JT command either in the part or merge phase.
   It is best to define the joint with JD before referencing it with JT.
   The REPE option makes multiple joint definitions.
   This is useful when parts containing joints are replicated.
   The JT command also allows for a joint number increment
   so that the corresponding nodes in the different copies of the part
   can each be assigned to its corresponding numbered joint.
    SJ for spherical joint 
    RJ for revolute joint 
    CJ for cylindrical joint 
    PJ for planar joint 
    UJ for universal joint 
    TJ for translational joint 
    PNLT for joint penalty used with SJ, RJ, CJ, PJ, UJ, and TJ
    REPE for repeated joint definitions
    SW for spotwelded nodal constraints
    DX, DY, and DZ for shared nodal displacement
    RX, RY, and RZ for shared nodal rotation
  JTINFO: write information about defined joints.
  JT: assign a node to a numbered joint defined by JD.
   Each node in a joint is assigned a node sequence number which is referred
   to as its local node number.
   Each type of joint requires a different number of nodes and the role
   a node plays in the joint depends on the joint type and the nodes
   local node number.
   The simplest example of a joint is when a set of nodes share constraints.
   In this case the ordering of the nodes are not important.
   Up to 16 nodes can be included in a shared constraint joint.
   Note that the nodal constraints available in this command apply to new
   nodes (N) and should not be confused with the shared constraint joint
   selected with the JD command.
   The INC option makes it possible to change the joint number referenced
   by this command, depending on the replication of the part.
   For example, if a part contains a node assigned to joint number 2, and