Stretched grid method
The stretched grid method is a numerical technique for finding approximate solutions of various mathematical and engineering problems that can be related to an elastic grid behavior.
In particular, meteorologists use the stretched grid method for weather prediction and engineers use the stretched grid method to design tents and other tensile structures.
FEM and BEM mesh refinement
In recent decades the finite element and boundary element methods have become a mainstay for industrial engineering design and analysis. Increasingly larger and more complex designs are being simulated using the FEM or BEM. However, some problems of FEM and BEM engineering analysis are still on the cutting edge. The first problem is a reliability of engineering analysis that strongly depends upon the quality of initial data generated at the pre-processing stage. It is known that automatic element mesh generation techniques at this stage have become commonly used tools for the analysis of complex real-world models. With FEM and BEM increasing in popularity comes the incentive to improve automatic meshing algorithms. However, all of these algorithms can create distorted and even unusable grid elements. Several techniques exist which can take an existing mesh and improve its quality. For instance smoothing is one such method, which repositions nodal locations, so as to minimize element distortion. The Stretched Grid Method allows the obtaining of pseudo-regular meshes very easily and quickly in a one-step solution.Let one assume that there is an arbitrary triangle grid embedded into plane polygonal single-coherent contour and produced by an automeshing procedure It may be assumed further that the grid considered as a physical nodal system is distorted by a number of distortions. It is supposed that the total potential energy of this system is proportional to the length of some -dimensional vector with all network segments as its components.
Thus, the potential energy takes the following form
where
- - total number of segments in the network,
- - The length of segment number,
- - an arbitrary constant.
It may also be supposed that co-ordinate vector of all nodes is associated with non-distorted network and co-ordinate vector is associated with the distorted network. The expression for vector may be written as
The vector determination is related to minimization of the quadratic form by incremental vector, i.e.
where
- - is the number of interior node of the area,
- - the number of co-ordinate
where
- - symmetrical matrix in the banded form similar to global stiffness matrix of FEM assemblage,
- and - incremental vectors of co-ordinates of all nodes at axes 1, 2,
- and - the right part vectors that are combined by co-ordinates of all nodes in axes 1, 2.
As above systems are linear, the procedure elapses very quickly to a one-step solution. Moreover, each final interior node position meets the requirement of co-ordinate arithmetic mean of nodes surrounding it and meets the Delaunay criteria too. Therefore, the SGM has all the positive values peculiar to Laplacian and other kinds of smoothing approaches but much easier and reliable because of integer-valued final matrices representation. Finally, the described above SGM is perfectly applicable not only to 2D meshes but to 3D meshes consisting of any uniform cells as well as to mixed or transient meshes.
Minimum surface problem solution
Mathematically the surface embedded into a non-plane closed curve is called minimum if its area is minimal amongst all the surfaces passing through this curve. The best-known minimum surface sample is a soap film bounded by wire frame. Usually to create a minimum surface, a fictitious constitutive law, which maintains a constant prestress, independent of any changes in strain, is used. The alternative approximated approach to the minimum surface problem solution is based on SGM. This formulation allows one to minimize the surface embedded into non-plane and plane closed contours.al surface
The idea is to approximate a surface part embedded into 3D non-plane contour by an arbitrary triangle grid. To converge such triangle grid to grid with minimum area one should solve the same two systems described above. Increments of the third nodal co-ordinates may be determined additionally by similar system at axis 3 in the following way
Solving all three systems simultaneously one can obtain a new grid that will be the approximating minimal surface embedded into non-plane closed curve because of the minimum of the function where parameter.
As an example the surface of catenoid which is calculated by the described above approach is presented in Fig 3. The radii of rings and the height of catenoid are equal to 1.0. The numerical area of catenoidal surface determined by SGM is equal to 2,9967189.
Tensile fabric structures form finding
For structural analysis, the configuration of the structure is generally known à priori. This is not the case for tensile structures such as tension fabric structures. Since the membrane in a tension structure possesses no flexural stiffness, its form or configuration depends upon initial prestressing and the loads to which it is subjected. Thus, the load-bearing behaviour and the shape of the membrane cannot be separated and cannot be generally described by simple geometric models only. The membrane shape, the loads on the structure and the internal stresses interact in a non-linear manner to satisfy the equilibrium equations.The preliminary design of tension structures involves the determination of an initial configuration referred to as form finding. In addition to satisfying the equilibrium conditions, the initial configuration must accommodate both architectural and structural requirements. Further, the requirements of space and clearance should be met, the membrane principal stresses must be tensile to avoid wrinkling, and the radii of the double-curved surface should be small enough to resist out-of-plane loads and to insure structural stability. Several variations on form finding approaches based on FEM have been developed to assist engineers in the design of tension fabric structures. All of them are based on the same assumption as that used for analysing the behaviour of tension structures under various loads. However, as it is noted by some researchers it might sometimes be preferable to use the so-called ‘minimal surfaces’ in the design of tension structures.
The physical meaning of SGM consists in convergence of the energy of an arbitrary grid structure embedded into rigid 3D contour to minimum that is equivalent to minimum sum distances between arbitrary pairs of grid nodes. It allows the minimum surface energy problem solution substituting for finding grid structure sum energy minimum finding that provides much more plain final algebraic equation system than the usual FEM formulation. The generalized formulation of SGM presupposes a possibility to apply a set of outer forces and rigid or elastic constrains to grid structure nodes that allows the modelling of various outer effects. We may obtain the following expression for such SGM formulation
where
- - total number of grid segments,
- - total number of nodes,
- - length of segment number,
- - stiffness of segment number,
- - coordinate increment of node at axis,
- - stiffness of an elastic constrain in node at axis,
- - outer force in node at axis.
Unfolding problem and cutting pattern generation
The objective is to develop the shapes described by these data, as close as possible to the ideal doubly curved strips. In general, cutting pattern generation involves two steps. First, the global surface of a tension structure is divided into individual cloths. The corresponding cutting pattern at the second step can be found by simply taking each cloth strip and unfolding it on a planar area. In the case of the ideal doubly curved membrane surface the subsurface cannot be simply unfolded and they must be flattened. For example, in, SGM has been used for the flattening problem solution.
The cutting pattern generation problem is actually subdivided into two independent formulations. These are the generation of a distortion-free plane form unfolding each cloth strip and flattening double-curved surfaces that cannot be simply unfolded. Studying the problem carefully one can notice that from the position of differential geometry both formulations are the same. We may consider it as an isometric mapping of a surface onto the plane area that will be conformal mapping and equiareal mapping simultaneously because of invariant angles between any curves and invariance of any pieces of area. In the case of single-curved surface that can be unfolded precisely equi-areal mapping allows one to obtain a cutting pattern for fabric structure without any distortions. The second type of surfaces can be equi-areal mapped only approximately with some distortions of linear surface elements limited by the fabric properties. Let us assume that two surfaces are parameterized so that their first quadratic forms may be written as follows
The condition of conformal mapping for two surfaces as is formulated in differential geometry requires that
where is the ratio of the surface distortion due to conformal mapping.
It is known that the first quadratic form reflects the distance between two surface points and. When -ratio is close to 1 the above eqn converges to condition of isometric mapping and to equi-areal mapping respectively because of invariant angles between any curves and invariance of any pieces of area. Remembering that the first stage of form finding is based on triangular mesh of a surface and using the for the description of isometric and equi-areal mapping of the minimum surface onto a plane area we may write the following function which is defined by the sum of integrals along segments of curved triangles
where
- - total number of grid cells,
- - weight ratios,
- - the total mapping residual,
- - the constant that does not influence the final result and may be used as a scale ratio.
where
- - initial length of linear segment number,
- - final length of segment number,
- - distortion ratio close to 1 and may be different for each segment.
where
- - co-ordinates of nodes of the initial segment,
- - co-ordinates of nodes of the final segment.
The vector definition is made as previously
After transformations we may write the following two independent systems of non-linear algebraic equations
where all the parts of the system can be expressed as previously and and are vectors of pseudo-stresses at axes 1, 2 that has the following form
where
- - total number of nodes that surround node number,
- - the number of global axes.
The typical sample of cut out — also called a cutout, a gore, or a patch — is presented in Figs. 9, 10, 11.