Difference between revisions of "Vertical Stand"

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1 Description

Figure 1: CAD Geometry

The vertical stand (see xx--CrossReference--dft--fig:cad--xx) represents a structural part of a machine tool. On one of its surfaces a pair of guide rails is located. Caused by a machining process a tool slide is moving on these rails. The machining process produces a certain amount of heat which is transported through the structure into the vertical stand. This heat source is considered to be a temperature input at the guide rails. This transfered heat amount leads to deformations within the device induced by the prevailed temperature field denoted by $x$ . The evolution of this field is modeled by the heat equation

c_p\rho\frac{\partial{x}}{\partial{t}}=\nabla.(\lambda\nabla x)=0

with the boundary conditions

\lambda\frac{\partial x}{\partial n}=q \qquad\qquad\qquad

on

\Gamma_{slide}

(surface where the tool slide is moving on the guide rails),

describing the heat transfer between the tool slide and the vertical stand. The heat transfer to the ambience is given by the Robin-type boundary condition

\lambda\frac{\partial x}{\partial n}=\kappa(x-x_{ext})

on

\Gamma_{surf}

(remaining boundaries),

which describes t.

Geometrical dimensions:

Stand: Width ( $x$ direction): $519mm$ , Height ( $y$ direction): $2\,010mm$ , Depth ( $z$ direction): $480mm$

Slide: Height $500mm$

Guide rails: $y\in [519, 2\,004] mm$

The heat load $q$ induced by the slide and the external temperature $x_{ext}$ serve as the input $u$ of the corresponding state-space system.

The motion of the tool slide and the associated variation of the affected input boundary are modeled by two different system representations.

1.1 Switched linear system

File:Slide stand scheme.pdf

Figure 2: Schematic segmentation

For the switched linear systems approach, the guide rails of the machine stand are modeled as 15 equally distributed horizontal segments (see Figure xx--CrossReference--dft--fig:segm--xx). Any of these segments is assumed to be completely covered by the tool slide if its midpoint (in y-direction) lies within the height of the slide. On the other hand, each segment whose midpoint is not covered is treated as not in contact and therefore the slide always covers exactly $5$ segments at each time. This in fact allows the stand to reach $11$ distinct, discrete positions given by the model restrictions. These distinguishable setups define the subsystems of the switched linear system

E_{th}\dot{T}=A_{th}^{\alpha}T+B_{th}z^{\alpha}, y=\bar{C}T,

where $\alpha$ is a piecewise constant function of time, which takes its value from the index set $\mathcal{J}=\{1,\dots,11\}$ .

1.2 Linear Parameter-varying system

2 Acknowledgement & Origin

The base model was developed ^[1], ^[2] in the Collaborative Research Centre Transregio 96 Thermo-Energetic Design of Machine Tools funded by the Deutsche Forschungsgemeinschaft .

The following specific model representations have been developed and investigated in ^[3], ^[4].

3 Data

3.1 Switched System Data

3.2 Parametric System Data

The data file Data_VertStand.tar.gz contains a MAT_File matrices.mat which consists of the matrices

E,A\in\mathbb{R}^{n\times n},B_{slide}\in\mathbb{R}^{n\times 1},B_{surf}\in\mathbb{R}^{n\times 5}, n=16\,626

in sparse format and a file with the coordinates of the mesh nodes called coord.txt.

Here $B_{slide}$ consists of all nodes located on the guide rails.

In order to get a parameter dependent matrix $B_{slide}(\mu)$ one has to pick the "active" nodes (nodes hit by tool carriage) at vertical position $\mu$ . The "active" nodes are in the interval of $[\mu-\frac{d}{2},\mu+\frac{d}{2}]$ , where $d$ is the heigth of the slide.

The file coord.txt provided in Data_VertStand.tar.gz includes a column with indices followed by three additional columns containing the spatial coordinates $x,y,z$ of the corresponding nodes.

The matrix $B_{surf}$ describes the locations where the external temperatures act on. The first column is responsible for the input of the temperature at the clamped bottom slice of the structure. Column 2 describes the ... part of the stand. Columns 3 to 5 describe different thresholds with respect to the height of ambient air temperature. The third column includes the nodes of the lower third $(y\in[0,670)mm)$ of the stand. In column 4 all nodes of the middle third $(y\in[670,1\,340)mm)$ of the geometry are contained and the fifth column of $B_{surf}$ includes the missing upper $(y\in[1\,340,2\,010]mm)$ part.

4 Citation

To cite this benchmark, use the following references:

For the benchmark itself and its data:

The MORwiki Community. Vertical Stand. MORwiki - Model Order Reduction Wiki, 2018. http://modelreduction.org/index.php/Vertical_Stand

   @MISC{morwiki_vertstand,
    author = {The {MORwiki} Community},
    title = {Vertical Stand},
    howpublished = {{MORwiki} -- Model Order Reduction Wiki},
    url = {http://modelreduction.org/index.php/Vertical_Stand},
    year = {2014}
   }

For the background on the benchmark:

   @Article{morLanSB14,
     author =       {Lang, Norman and Saak, Jens and Benner, Peter},
     title =        {Model Order Reduction for Systems with Moving Loads},
     journal =      {at-Automatisierungstechnik},
     year =         2014,
     volume =       62,
     number =       7,
     pages =        {512--522},
     month =        {June},
     publisher =    {deGruyter},
     doi =          {10.1515/auto-2014-1095}
   }

5 References

↑ A. Galant, K. Großmann, and A. Mühl, Model Order Reduction (MOR) for Thermo-Elastic Models of Frame Structural Components on Machine Tools. \textit{ANSYS Conference \& 29th CADFEM Users’ Meeting 2011, October 19-21, 2011, Stuttgart, Germany
↑ A. Galant, K. Großmann and A. Mühl, Thermo-Elastic Simulation of Entire Machine Tool , In: Thermo Energetic Design of Machine Tools, Lecture Notes in Production Engineering, 69-84, 2015
↑ N. Lang and J. Saak and P. Benner, Model Order Reduction for Systems with Moving Loads , in De Gruyter Oldenbourg: at-Automatisierungstechnik, Volume 62, Issue 7, Pages 512-522, 2014
↑ N. Lang, J. Saak and P. Benner, Model Order Reduction for Thermo-Elastic Assembly Group Models , In: Thermo Energetic Design of Machine Tools, Lecture Notes in Production Engineering, 85-92, 2015

6 Contact

Jens Saak

[GalGM11-1] A. Galant, K. Großmann, and A. Mühl, Model Order Reduction (MOR) for Thermo-Elastic Models of Frame Structural Components on Machine Tools. \textit{ANSYS Conference \& 29th CADFEM Users’ Meeting 2011, October 19-21, 2011, Stuttgart, Germany

[GalGM15-2] A. Galant, K. Großmann and A. Mühl, Thermo-Elastic Simulation of Entire Machine Tool , In: Thermo Energetic Design of Machine Tools, Lecture Notes in Production Engineering, 69-84, 2015

[morLanSB14-3] N. Lang and J. Saak and P. Benner, Model Order Reduction for Systems with Moving Loads , in De Gruyter Oldenbourg: at-Automatisierungstechnik, Volume 62, Issue 7, Pages 512-522, 2014

[LanSB15-4] N. Lang, J. Saak and P. Benner, Model Order Reduction for Thermo-Elastic Assembly Group Models , In: Thermo Energetic Design of Machine Tools, Lecture Notes in Production Engineering, 85-92, 2015

[1]

[2]

[3]

[4]

@@ Line 14: / Line 14: @@
 <figure id="fig:cad">
-[[File:Staender_Geom_white.jpg|150px|thumb|right|<caption>CAD Geometry</caption>]]
+[[File:Staender_Geom_white.jpg|180px|thumb|right|<caption>CAD Geometry</caption>]]
 </figure>
@@ Line 40: / Line 40: @@
 '''Geometrical dimensions:'''
 Stand: Width  (<math>x</math> direction):  <math>519mm</math>, Height (<math>y</math> direction): <math>2\,010mm</math>, Depth  (<math>z</math> direction):  <math>480mm</math>
 Slide: Height <math>500mm</math>
+Guide rails: <math>y\in [519, 2\,004] mm</math>
@@ Line 64: / Line 68: @@
 distinguishable setups define the subsystems of the switched linear
 system
+:<math>
-\begin{align}
+  E_{th}\dot{T}=A_{th}^{\alpha}T+B_{th}z^{\alpha},
-  \begin{aligned}
+              y=\bar{C}T,
-    E_{th}\dot{T}&=A_{th}^{\alpha}T+B_{th}z^{\alpha},\\
+</math>
-    y&=\bar{C}T,
+where <math>\alpha</math> is a piecewise constant function of time, which takes
-  \end{aligned}\label{eq:bls14:schur_switch}
+its value from the index set <math>\mathcal{J}=\{1,\dots,11\}</math>.
-\end{align}
-where $\alpha$ is a piecewise constant function of time, which takes
-its value from the index set $J=\{1,\dots,11\}$.
 ====Linear Parameter-varying system====