Difference between revisions of "Vertical Stand"

Revision as of 07:04, 18 July 2016

1 Description

CAD Geometry

The vertical stand represents a structural part of a machine tool. On one of its surfaces there are guide rails located. On these rails a tool slide is moving due to the machining process the slide has to perform by the machine tool on top. 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 and

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

on

\Gamma_{surf}

(remaining boundaries),

which describes the heat transfer to the ambience.

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 position of the moving slide has been included into the system as a parameter dependency $\mu$ . Due to this motion the region there the input acts on the system is varying and thus one obtains a parameter dependent input matrix $B(\mu)$ .

Finally, the system describing the heat evolution induced by the moving heat source is given by:

\begin{array}{lll} E\dot{x}&=Ax+B_{surf}x_{ext}+B_{slide}(\mu)q,\\ &=Ax+B(\mu)u,\\ \end{array}

where

\begin{array}{lll} B(\mu)&=[B_{surf}, B_{slide}(\mu)],\\ u&=[x_{ext}^T,q]^T.\\ \end{array}

The quantity $x_{ext}$ can be assumed as a vector including different ambient temperatures corresponding to different locations of the geometry.

2 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=16626

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. Therefore the file coord.txt is provided in Data_VertStand.tar.gz.

This file 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 $(y\in[670,1340]mm)$ of the geometry are contained and the fifth column of $B_{surf}$ includes the missing upper $(y\in[1340,2010]mm)$ part.

To clarify this partitioning the geometrical data is given as follows:

Width ( $x$ direction): $519mm$ , Height ( $y$ direction): $2010mm$ , Depth ( $z$ direction): $480mm$

3 Contact

Norman Lang

@@ Line 17: / Line 17: @@
 :<math>
-\lambda\frac{\partial x}{\partial n}=\kappa(x-x_{ext})
+\lambda\frac{\partial x}{\partial n}=q \qquad\qquad\qquad
-</math>   on <math> \Gamma_{surf} </math> (remaining boundaries),
+</math> on <math> \Gamma_{slide} </math> (surface where the tool slide is moving on the guide rails),
-describing the heat transfer to the ambience and
+describing the heat transfer between the tool slide and the '''vertical stand''' and
 :<math>
-\lambda\frac{\partial x}{\partial n}=q \qquad\qquad\qquad
+\lambda\frac{\partial x}{\partial n}=\kappa(x-x_{ext})
-</math> on <math> \Gamma_{slide} </math> (surface where the tool slide is moving on the guide rails),
+</math>   on <math> \Gamma_{surf} </math> (remaining boundaries),
-which describes the heat transfer between tool slide and '''vertical stand'''.
+which describes the heat transfer to the ambience.
 The heat load <math>q</math> induced by the slide and the external temperature <math>x_{ext}</math> serve as the input <math> u </math> of the corresponding state-space system.