Versions Compared

Version Old Version 3 New Version 4
Changes made by

Harika Inanc (Unlicensed)

Harika Inanc (Unlicensed)

Saved on

Key

  • This line was added.
  • This line was removed.
  • Formatting was changed.

...

Extracting Displacement

...

Extracting Force

force(Case,Element,Station) → List of Number ([Fx,Fy,Fz,MxMy,Mz])

forceFx(Case,Element,Station) = force(Case,Element,Station)[0] → Number (Fx)

forceFy(Case,Element,Station) = force(Case,Element,Station)[1] → Number (Fy)

forceFz(Case,Element,Station) = force(Case,Element,Station)[2] → Number (Fz)

forceMx(Case,Element,Station) = force(Case,Element,Station)[3] → Number (Mx)

forceMy(Case,Element,Station) = force(Case,Element,Station)[4] → Number (My)

forceMy(Case,Element,Station) = force(Case,Element,Station)[5] → Number (Mz)

Case : Object

Element : Object

Station : Number

T=”AnalysisCase“

T=”Combination”

T=”Node”

T=”FELine”

T=”FESurface”

T=”FEComposite”

Node → Leave empty

FELine → 0 for start edge, 1 for end edge

FESurface → 0,1,2,4 for edge nodes

FEComposite → The distance from the start point of FEComposite path

force(Case,Node Coordinate) → List of Number ([Fx,Fy,Fz,MxMy,Mz])

forceFx(Case,Node Coordinate) = force(Case,Node Coordinate)[0] → Number (Fx)

forceFy(Case,Node Coordinate) = force(Case,Node Coordinate)[1] → Number (Fy)

forceFz(Case,Node Coordinate) = force(Case,Node Coordinate)[2] → Number (Fz)

forceMx(Case,Node Coordinate) = force(Case,Node Coordinate)[3] → Number (Mx)

forceMy(Case,Node Coordinate) = force(Case,Node Coordinate)[4] → Number (My)

forceMy(Case,Node Coordinate) = force(Case,Node Coordinate)[5] → Number (Mz)

Case : Object

Node Coordinate : List of Number

T=”AnalysisCase“

T=”Combination”

[X coordinate, Y coordinate, Z coordinate] → If you don't have direct access to the node object, you can pass in a coordinate as a list of 3 numbers (this only applies to nodes, will not work for finite element). OpenBrIM will find the node that is closest to the specified coordinate and return the results.

...

forceNeg(Case,Element,Station) → List of Number ([Fx,Fy,Fz,MxMy,Mz])

forceFxNeg(Case,Element,Station) = forceNeg(Case,Element,Station)[0] → Number (Fx)

forceFyNeg(Case,Element,Station) = forceNeg(Case,Element,Station)[1] → Number (Fy)

forceFzNeg(Case,Element,Station) = forceNeg(Case,Element,Station)[2] → Number (Fz)

forceMxNeg(Case,Element,Station) = forceNeg(Case,Element,Station)[3] → Number (Mx)

forceMyNeg(Case,Element,Station) = forceNeg(Case,Element,Station)[4] → Number (My)

forceMyNeg(Case,Element,Station) = forceNeg(Case,Element,Station)[5] → Number (Mz)

Case : Object

Element : Object

Station : Number

T=”AnalysisCase“

T=”Combination”

T=”Node”

T=”FELine”

T=”FESurface”

T=”FEComposite”

Node → Leave empty

FELine → 0 for start edge, 1 for end edge

FESurface → 0,1,2,4 for edge nodes

FEComposite → The distance from the start point of FEComposite path

forceNeg(Case,Node Coordinate) → List of Number ([Fx,Fy,Fz,MxMy,Mz])

forceFxNeg(Case,Node Coordinate) = forceNeg(Case,Node Coordinate)[0] → Number (Fx)

forceFyNeg(Case,Node Coordinate) = forceNeg(Case,Node Coordinate)[1] → Number (Fy)

forceFzNeg(Case,Node Coordinate) = forceNeg(Case,Node Coordinate)[2] → Number (Fz)

forceMxNeg(Case,Node Coordinate) = forceNeg(Case,Node Coordinate)[3] → Number (Mx)

forceMyNeg(Case,Node Coordinate) = forceNeg(Case,Node Coordinate)[4] → Number (My)

forceMyNeg(Case,Node Coordinate) = forceNeg(Case,Node Coordinate)[5] → Number (Mz)

Case : Object

Node Coordinate : List of Number

T=”AnalysisCase“

T=”Combination”

[X coordinate, Y coordinate, Z coordinate] → If you don't have direct access to the node object, you can pass in a coordinate as a list of 3 numbers (this only applies to nodes, will not work for finite element). OpenBrIM will find the node that is closest to the specified coordinate and return the results.

Extracting Concurrent Force

Positive Results

forceFxPosConc(Case,Element,Station) → List of Number ([Fx*,Fy,Fz,Mx,My,Mz])

critical Fx result and its concurrent results

forceFyPosConc(Case,Element,Station) → List of Number ([Fx,Fy*,Fz,Mx,My,Mz])

critical Fy result and its concurrent results

forceFzPosConc(Case,Element,Station) → List of Number ([Fx,Fy,Fz*,Mx,My,Mz])

critical Fz result and its concurrent results

forceMxPosConc(Case,Element,Station) → List of Number ([Fx,Fy,Fz,Mx*,My,Mz])

critical Mx result and its concurrent results

forceMyPosConc(Case,Element,Station) → List of Number ([Fx,Fy,Fz,Mx,My*,Mz])

critical My result and its concurrent results

forceMzPosConc(Case,Element,Station) → List of Number ([Fx,Fy,Fz,Mx,My,Mz*])

critical Mz result and its concurrent results

Case : Object

Element : Object

Station : Number

T=”AnalysisCase“

T=”Combination”

T=”Node”

T=”FELine”

T=”FESurface”

T=”FEComposite”

Node → Leave empty

FELine → 0 for start edge, 1 for end edge

FESurface → 0,1,2,4 for edge nodes

FEComposite → The distance from the start point of FEComposite path

forceFxPosConc(Case,Node Coordinate) → List of Number ([Fx*,Fy,Fz,Mx,My,Mz])

critical Fx result and its concurrent results

forceFyPosConc(Case,Node Coordinate) → List of Number ([Fx,Fy*,Fz,Mx,My,Mz])

critical Fy result and its concurrent results

forceFzPosConc(Case,Node Coordinate) → List of Number ([Fx,Fy,Fz*,Mx,My,Mz])

critical Fz result and its concurrent results

forceMxPosConc(Case,Node Coordinate) → List of Number ([Fx,Fy,Fz,Mx*,My,Mz])

critical Mx result and its concurrent results

forceMyPosConc(Case,Node Coordinate) → List of Number ([Fx,Fy,Fz,Mx,My*,Mz])

critical My result and its concurrent results

forceMzPosConc(Case,Node Coordinate) → List of Number ([Fx,Fy,Fz,Mx,My,Mz*])

critical Mz result and its concurrent results

Case : Object

Node Coordinate : List of Number

T=”AnalysisCase“

T=”Combination”

[X coordinate, Y coordinate, Z coordinate] → If you don't have direct access to the node object, you can pass in a coordinate as a list of 3 numbers (this only applies to nodes, will not work for finite element). OpenBrIM will find the node that is closest to the specified coordinate and return the results.

Negative Results

forceFxNegConc(Case,Element,Station) → List of Number ([Fx*,Fy,Fz,Mx,My,Mz])

critical Fx result and its concurrent results

forceFyNegConc(Case,Element,Station) → List of Number ([Fx,Fy*,Fz,Mx,My,Mz])

critical Fy result and its concurrent results

forceFzNegConc(Case,Element,Station) → List of Number ([Fx,Fy,Fz*,Mx,My,Mz])

critical Fz result and its concurrent results

forceMxNegConc(Case,Element,Station) → List of Number ([Fx,Fy,Fz,Mx*,My,Mz])

critical Mx result and its concurrent results

forceMyNegConc(Case,Element,Station) → List of Number ([Fx,Fy,Fz,Mx,My*,Mz])

critical My result and its concurrent results

forceMzNegConc(Case,Element,Station) → List of Number ([Fx,Fy,Fz,Mx,My,Mz*])

critical Mz result and its concurrent results

Case : Object

Element : Object

Station : Number

T=”AnalysisCase“

T=”Combination”

T=”Node”

T=”FELine”

T=”FESurface”

T=”FEComposite”

Node → Leave empty

FELine → 0 for start edge, 1 for end edge

FESurface → 0,1,2,4 for edge nodes

FEComposite → The distance from the start point of FEComposite path

forceFxNegConc(Case,Node Coordinate) → List of Number ([Fx*,Fy,Fz,Mx,My,Mz])

critical Fx result and its concurrent results

forceFyNegConc(Case,Node Coordinate) → List of Number ([Fx,Fy*,Fz,Mx,My,Mz])

critical Fy result and its concurrent results

forceFzNegConc(Case,Node Coordinate) → List of Number ([Fx,Fy,Fz*,Mx,My,Mz])

critical Fz result and its concurrent results

forceMxNegConc(Case,Node Coordinate) → List of Number ([Fx,Fy,Fz,Mx*,My,Mz])

critical Mx result and its concurrent results

forceMyNegConc(Case,Node Coordinate) → List of Number ([Fx,Fy,Fz,Mx,My*,Mz])

critical My result and its concurrent results

forceMzNegConc(Case,Node Coordinate) → List of Number ([Fx,Fy,Fz,Mx,My,Mz*])

critical Mz result and its concurrent results

Case : Object

Node Coordinate : List of Number

T=”AnalysisCase“

T=”Combination”

[X coordinate, Y coordinate, Z coordinate] → If you don't have direct access to the node object, you can pass in a coordinate as a list of 3 numbers (this only applies to nodes, will not work for finite element). OpenBrIM will find the node that is closest to the specified coordinate and return the results.

...

Extracting Stress

...