1 THE FINITE ELEMENT PROGRAM Z88

1.1 GENERAL OVERVIEW FEA PROGRAM Z88

The Z88 philosophy:

+ Fast and compact: Developed for PC, no ported mainframe system

+ Flexible and transparent: Controlled by text files

+ "Small is beautifull" - a modular system vs. monolithic monsters

+ native UNIX and Windows programs, no emulation

+ UNIX and Windows programs use the same computing kernels

+ Full data exchange from and to CAD systems with DXF-Interface

+ mesh import from Pro/ENGINEER

+ Context sensitive online-help under Windows and UNIX

+ No copy protection, no annoying passwords

+ Simplest installation: No subdirectories, no change of system files

+ Under UNIX: Automatic control and cumulative runs possible

Notes:

Always compare FE calculations with analytical rough calculations, results of experiments, plausibility considerations and other tests without exception!

Keep in mind that sign definitions of Z88 (and also other FEM programs) differ from the usual definitions of the analytical technical mechanics from time to time .

Z88 is a complex computer program. How Z88 deals with other programs and utilities etc. is not predictable. We cannot give any advice and support here! You should switch off at first all other programs and utilities. Run Z88 "purely" and then start further programs step-by-step. Z88 uses only documented operating system calls of Windows and UNIX !

Summary of the Z88 element library:
(
You will find the exact description of the element library in chapter 4.)

Twodimensinal problems: Plane stress, plates, beams, trusses

Plane Stress Triangle Element No. 3

- Shape functions quadratic

- Quality of displacements very good

- Quality of stresses in the center of gravity good

- Computing effort: average

- Size of element stiffness matrix: 12 * 12


Plane Stress Isoparametric Element No. 7

- Quadratic Isoparametric Serendipity element

- Quality of displacements very good

- Quality of stresses in the Gauss- points very good

- Quality of stresses in the corner nodes good

- Computing effort: High

- Size of element stiffness matrix: 16 * 16

Truss No. 9

- Linear function

- Quality of displacements exact (Hooke 's law)

- Quality of stresses exact (Hooke ' s law)

- Computing effort: Minimal

- Size of element stiffness matrix: 4 * 4



Plane Stress Isoparametric Element No. 11

- Cubic Isoparametric Serendipity element

- Quality of displacements excellent

- Quality of stresses in the Gauss- points excellent

- Quality of stresses in the corner nodes good

- Computing effort: Very high

- Size of element stiffness matrix: 24 * 24


Beam No. 13

- Linear function for tensile stress, cubic function for bending stress

- Quality of displacements exact (Hooke 's law)

- Quality of stresses exact (Hooke ' s law)

- Computing effort: Low

- Size of element stiffness matrix: 8 * 8

Plane Stress Isoparametric Element No. 14

- Quadratic Isoparametric Serendipity element

- Quality of displacements very good

- Quality of stresses in the Gauss- points very good

- Quality of stresses in the corner nodes good

- Computing effort: High

- Size of element stiffness matrix: 12 * 12



Isoparametric Plate Element No. 18

- Quadratic Isoparametric Serendipity element following Reissner- Mindlin's theory

- Quality of displacements very good

- Quality of stresses in the Gauss- points good

- Quality of stresses in the corner nodes acceptable

- Computing effort: medium

- Size of element stiffness matrix: 18 * 18

Isoparametric Plate Element No. 19

- Cubic Isoparametric Lagrange element following Reissner- Mindlin's theory

- Quality of displacements very good

- Quality of stresses in the Gauss- points very good

- Quality of stresses in the corner nodes good

- Computing effort: High

- Size of element stiffness matrix: 48 * 48

Isoparametric Plate Element No. 20

- Quadratic Isoparametric Serendipity element following Reissner- Mindlin's theory

- Quality of displacements very good

- Quality of stresses in the Gauss- points good

- Quality of stresses in the corner nodes quite good

- Computing effort: medium

- Size of element stiffness matrix: 24 * 24


Axisymmetric problems:

Torus No. 6

- Linear function

- Quality of displacements average

- Quality of stresses in the corner nodes inaccurate

- Computing effort: Low

- Size of element stiffness matrix: 6 * 6


Torus No. 8

- Quadratic Isoparametric Serendipity element

- Quality of displacements very good

- Quality of stresses in the Gauss- points very good

- Quality of stresses in the corner nodes good

- Computing effort: High

- Size of element stiffness matrix: 16 * 16

Cam No. 5

- Linear function for torsion and tensile stress, cubic function for bending stress

- Quality of displacements exact (Hooke 's law)

- Quality of stresses exact (Hooke ' s law)

- Computing effort: Low

- Size of element stiffness matrix: 12 * 12

Torus No. 12

- Cubic Isoparametric Serendipity element

- Quality of displacements excellent

- Quality of stresses in the Gauss- points excellent

- Quality of stresses in the corner nodes good

- Computing effort: Very high

- Size of element stiffness matrix: 24 * 24

Torus No. 15

- Quadratic Isoparametric Serendipity element

- Quality of displacements very good

- Quality of stresses in the Gauss- points very good

- Quality of stresses in the corner nodes good

- Computing effort: High

- Size of element stiffness matrix: 12 * 12


Space problems:

Truss No. 4

- Linear function

- Quality of displacements exact (Hooke 's law)

- Quality of stresses exact (Hooke ' s law)

- Computing effort: Minimal

- Size of element stiffness matrix: 6 * 6


Beam No. 2

- Linear function for tensile stress, cubic function for bending stress

- Quality of displacements exact (Hooke 's law)

- Quality of stresses exact (Hooke ' s law)

- Computing effort: Low

- Size of element stiffness matrix: 12 * 12

Hexahedron No. 1

- Linear shape functions

- Quality of displacements average

- Stresses in the Gauss- points useable

- Stresses in corner nodes inaccurate

- Computing effort: very high

- Size of element stiffness matrix: 24 * 24


Hexahedron No. 10

- Quadratic Isoparametric Serendipity element

- Quality of displacements very good

- Stresses in the Gauss- points very good

- Stresses in corner nodes good

- Computing effort: extremely high

- Size of element stiffness matrix: 60 * 60

Tetrahedron No. 17

- Linear shape functions

- Quality of displacements bad

- Stresses in the Gauss- points inaccurate

- Stresses in corner nodes very inaccurate

- Computing effort: medium

- Size of element stiffness matrix: 12 * 12


Tetrahedron No. 16

- Quadratic Isoparametric Serendipity element

- Quality of displacements very good

- Stresses in the Gauss- points very good

- Stresses in corner nodes good

- Computing effort: very high

- Size of element stiffness matrix: 30 * 30

The Z88 computing units:

Overview:

Z88 always exclusively works at the tasks required at the moment. Thus, Z88 is no gigantic, monolithic program, but consists of several separate running modules according to the UNIX philosophy "Small Is Beautiful". They are loaded into the main memory according to your requirements, execute their tasks and release the main memory again. In this way Z88's achieves its enormous speed and faultlessness beating many other FE programs! The Z88 modules communicate by files, cf. Chapter 3.

Short description of the modules:

I. The Solver

The solver is the heart of any FEA system. It reads the general structure data Z88I1.TXT and the boundary conditions Z88I2.TXT. Basically, the Z88 input files can be created by CAD converter Z88X, by COSMOS converter Z88G, by net (or mesh) generator Z88N, by editor or word processor system or by a mixed procedure, e.g. by CAD and editor. The solver generates prepared structure data Z88O0.TXT and processed boundary conditions Z88O1.TXT, calculates the element stiffness matrices, compiles the total stiffness matrix, scales the system of equations, solves the (huge) system of equations and stores the displacements in Z88O2.TXT. Therefore, the main task of every FEA system, the calculation of displacements, is solved. Thereupon, if you wish, the stresses can be calculated by Z88D and/or nodal forces by Z88E.

Z88 features two totally different solvers:

Z88F: This is a so-called direct solver with skyline storing scheme and an in-situ Cholesky solver. It is the standard solver of Z88, easy to handle and very fast for small and medium structures. However, like any direct solver Z88F reacts badly on ill- numbered nodes but you may improve the situation with the Cuthill- McKee program Z88H. Z88F is your choice for small and medium structures, up to 20,000 ... 50,000 degrees of freedom.

Z88I1 and Z88I2: This is a so-called iteration solver featuring two modules. Z88I1 computes the pointers for the storage scheme of the total stiffness matrix. Z88I2 computes the stiffness matrices, addes the boundary conditions and solves the system of equations by the method of conjugate gradients featuring SOR- preconditioning or precontitioning by an incomplete Cholesky decomposition depending on your choice. Like any iteration solver Z88I1/Z88I2 deals well with bad node numbering, a run with the Cuthill- McKee program Z88H may improve the situation further, however. Z88I1/Z88I2 is your choice for large structures.

II. The link to CAD programs

The CAD converter Z88X converts DXF files from CAD systems into Z88 input files ( net generator input file Z88NI.TXT, general structure data Z88I1.TXT, boundary conditions Z88I2.TXT and stress parameters file Z88I3.TXT ) or, and this is the real goodie, also converts Z88 input files into DXF files. You cannot only produce input data in the CAD system and then use in Z88, but you can also complete Z88 entry files which are always simple ASCII files, e.g. by text editor, by word processing, by EXCEL or e.g. by your own special programs and then convert the data sets back into the CAD system by CAD converters Z88X. In the CAD system you can add more informations, then push the data again to Z88. This flexibility is unique!

The COSMOS converter Z88G reads FEA input files following the COSMOS or the NASTRAN format and generates the Z88 input files Z88I1.TXT, Z88I2.TXT and Z88I3.TXT automatically. You may produce COSMOS or NASTRAN data files by various CAD programs. However, Z88G is properly tested with Pro/ENGINEER with the Pro/MECHANICA option by Parametric Technology, USA. Thus, you may directly use Pro/ENGINEER 3D models with Z88 !

The Cuthill- McKee program Z88H was mainly designed for use with Z88G. It allows the re-numbering of finite elements meshes and may heavily decrease the memory needs for meshes generated by automeshers i.e. Pro/MECHANICA.

III. The net generator for ordered meshes

The net (or mesh) generator Z88N reads the super structure data Z88NI.TXT and computes the general structure data Z88I1.TXT. In principle, the net generator file Z88NI.TXT has the same construction as the file of the general structure data Z88I1.TXT. It can also be generated by CAD converters Z88X, by editor or word processor system or with a mixed procedure.

IV. The postprocessors

Stresses are calculated by Z88D. Z88F or Z88I1 and Z88I2 must have run before. Z88D reads a small parameter file Z88I3.TXT and stores the stresses in Z88O3.TXT.

Nodal forces are calculated by Z88E. Z88F or Z88I1 and Z88I2 must have run before. Z88E stores the nodal forces in Z88O4.TXT.

The plot program Z88P and Z88O plot deflections and stresses on the CTR, Z88P also on a HP-GL plotter or a printer capable of HP-GL, e.g. HP LaserJet. Z88P and Z88O are suitable for a quick inspection of the undeflected and the deflected structures as well as for showing the stresses. Of course, you can show undeflected structures on your CAD program capable of DXF via CAD converter Z88X, too, but Z88O and Z88P are much faster.

V. The file checker

The Filechecker Z88V checks the input files Z88NI.TXT or Z88I1.TXT to Z88I3.TXT for formal correctness. In addition, it can show the actual memory defined by you in the file Z88.DYN.

All modules of Z88 request Memory dynamically:

The user can define this in the file Z88.DYN. Z88 is delivered with default values which you can and also should change if necessary. This is possible at any time. The Z88 modules are genuine 32 bit (or 64 bit) programs and request their memory by operating system calls via calloc. The header file Z88.DYN provides how much memory shall be requested. You can request all virtual memory (virtual memory = main memory + swap area), which is provided by the operating system. Therefore there is no limit for the size of the Z88 finite element structures ! You can also fix whether Z88 works with English or German language in Z88.DYN: Keyword ENGLISH or GERMAN .

Multitasking of Z88:

Absolute multitasking is possible under Windows and UNIX, i. e. several Z88 modules or other genuine Windows programs can run parallel. Make sure that you do not overlap the windows (put them side by side), as if the Z88 modules have once started they are not evaluating WM_PAINT signals for speed reasons. This means, that, although the Z88 programs are properly working, displays and window images can be destroyed if you enlarge, reduce, move or cover Z88 windows by other programs. This does not have any influence on the computing results and only by this trick the outstanding speed of Z88 can be gained. Keep in mind that big space structures, e.g. with 20 nodes hexahedrons, can put very heavy load on your computer which can slow down the machine totally. Thus, let Z88 run alone and do not start any memory eaters like the various office programs.

Hints for the start of Z88:

Windows:

All Z88 modules can be started directly via Explorer, from a group which contains the various Z88 modules or via Start > Run. It suffices to call the Z88-Commander Z88COM for launching all other modules.

UNIX:

Launch the modules directly from a UNIX shell, from the Z88-Commander Z88COM, or, as an extended possibility, e.g. for large-caliber night runs, from a shell-script (sh, bash, ksh etc.). You have all unlimited liberties of the UNIX operating system. All modules except Z88COM, Z88O and Z88P can be started in text mode from consoles, but naturally also in an X window. As Motif programs the Z88-Commander Z88COM and the plot programs Z88O and  Z88P are to start from an X-term.

For a convenient use of Z88, fire up your X-Window-manager, open an X-term and launch Z88COM. Put Z88COM and the X-Term, which started Z88COM, side-by-side or over-and-under to see both.

The Input and Output of Z88:

The input and output files are generated either by an editor (e.g. the editor or notepad of Windows, DOS editors like edit, UNIX tools like vi, emacs, joe), word processor program (e.g. WinWord etc.), spreadsheet program (e.g. Excel) or via CAD converter Z88X directly in a CAD program, which can read and write DXF files (e.g. AutoCAD) or by converting a COSMOS or NASTRAN file with Z88G, which came from a 3D CAD program e.g. Pro/ENGINEER..

For the user this means maximum flexibility and transparency, as the input and output files of Z88 are quite simple ASCII text files. You can fill the files by arbitrary tools or by hand, and also by self-written programs, of course. Only make sure to meet the Z88 conventions for the respective file structure cf. Chapter 3.

You can modify output files as you like, enlarge them with your own comments, reduce them to the essential or use them as input for other programs.

Dimensions, i. e. measurement units, are not used explicitly. You can work in optional measurement systems, e.g. in the Metric or Imperial measurement system. Use inches, Newtons, pounds, tons, millimeters, meters, yards - whatever you prefer. But make sure to keep the one chosen measurement units throughout all computations of this structure. Example: You want to work with mm and N so Young's modulus must be used in N/mm*mm.

Note:

The Z88 input files read always:

+ Z88G.COS COSMOS Input file coming from a 3D CAD program, for converter Z88G
+ Z88G.NAS NASTRAN Input file coming from a 3D CAD program, for converter Z88G

+ Z88X.DXF Exchange file for CAD programs and for CAD converter Z88X

+ Z88NI.TXT Input file for the net generator of Z88N

+ Z88I1.TXT Input file (general structure data) for the FE processor of Z88F

+ Z88I2.TXT Input file (boundary conditions) for the FE processor of Z88F

+ Z88I3.TXT Input file (control values) for the stress processor of Z88D

+ Z88I4.TXT Input file (control values) for the iteration solver Z88I1/Z88I2

The Z88 output files read always

+ Z88O0.TXT Prepared structure data for documentation purposes

+ Z88O1.TXT Prepared boundary conditions for documentation purposes

+ Z88O2.TXT Computed displacements

+ Z88O3.TXT Computed stresses

+ Z88O4.TXT Computed nodal forces

These file names are expected from the Z88 modules and they must reside in the same Directory as the Z88 modules. You cannot allocate your own names for data sets. Of course, you may rename the Z88*.* files after all calculations have been done and save them in other directories.

Making:

You may allways create the net generator file Z88NI.TXT, the general structure data file Z88I1.TXT, the boundary conditions file Z88I2.TXT and the control values file Z88I3.TXT for the stress prozessor by hand using an editor or the like.

Using automatic generation consider the following possibilities:

CAD system, e.g. creates converter creates net generator creates






Pro/ENGINEER

(with Pro/MECHANICA

Z88G.COS
Z88G.NAS
Z88G Z88I1.TXT,

Z88I2.TXT,

Z88I3.TXT


not necessary
files

still

exist

AutoCAD Z88X.DXF Z88X Z88NI.TXT Z88N Z88I1.TXT
AutoCAD Z88X.DXF Z88X Z88I1.TXT,

Z88I2.TXT,

Z88I3.TXT


not necessary
files

still

exist

Z88 protocol files:

The Z88 modules always store protocol files .LOG, e.g. Z88F.LOG documents the steps or errors of the calculation of Z88F. Look at the various .LOG files in case of doubt. They also document the current memory needs. UNIX: If different users work in the same Z88 directory, make sure to have the proper permissions for the .LOG files, too. Use umask.

Printing of Z88 files

Is not supported by the Z88- Commanders. You print them by the Explorer of Windows or by an editor or word processing program. Use the printing routines of the UNIX operating system.

Which Z88 finite Element types can be produced automatically ?

element type function COSMOS
NASTRAN

(Z88G)

DXF

(Z88X)

super element

(Z88N)

creates FE

(Z88N)







Hexahedron No.1 linear No Yes No -
Hexahedron No.10 quadratic No Yes Yes Hexa No.10 & No.1
Tetrahedron No.16 quadratic Yes No No -
Tetrahedron No.17 linear Yes No No -






Plane stress No.3 quadratic No Yes No -
Plane stress No.7 quadratic Yes Yes Yes Plane stress No.7
Plane stress No.11 cubic No Yes Yes Plane stress No.7
Plane stress No.14 quadratic Yes Yes No -






Torus No.6 linear No Yes No -
Torus No.8 quadratic Yes Yes Yes Torus No.8
Torus No.12 kubisch No Yes Yes Torus No.8
Torus No.15 quadratic Yes Yes No -






Plate No.18 quadratic Yes Yes No -
Plate No.19 cubic No Yes No -
Plate No.20 quadratic Yes Yes Yes Pla No.19 & No.20






Truss No.4 exact No Yes No -
Truss No.9 exact No Yes No -






Beam No.2 exact No Yes No -
Cam No.5 exact No Yes No -
Beam No.13 exact No Yes No -

Z88 files:

Name Type Direction Purpose change, modify MS-Win UNIX







Z88.DYN ASCII Input Memory & Language header file Yes, Recom. Yes Yes







Z88G.COS
ASCII
Input
COSMOS to Z88
Yes, 1)
Yes
Yes
Z88G.NAS
ASCII
Input
NASTRAN to Z88
Yes,1)
Yes
Yes
Z88X.DXF ASCII In/Output DXF from and to Z88 Yes, 1) Yes Yes







Z88NI.TXT ASCII Input net generator input file Yes Yes Yes
Z88I1.TXT ASCII Input general structure data Yes Yes Yes
Z88I2.TXT ASCII Input constraints Yes Yes Yes
Z88I3.TXT ASCII Input stress parameter header file Yes Yes Yes
Z88I4.TXT ASCII Input header file for iteration solver Yes Yes Yes







Z88O0.TXT ASCII Output processed structure data Possible Yes Yes
Z88O1.TXT ASCII Output processed constraints Possible Yes Yes
Z88O2.TXT ASCII Output computed displacements Possible Yes Yes
Z88O3.TXT ASCII Output computed stresses Possible Yes Yes
Z88O4.TXT ASCII Output computed nodal forces Possible Yes Yes







Z88O5.TXT ASCII Output for internal use of Z88P No 2) Yes Yes
Z88O6.TXT ASCII Output Main HP- GL file from Z88P Yes 1) Yes Yes
Z88O7.TXT ASCII Output Aux. HP- GL file from Z88P Yes 1) Yes Yes
Z88O8.TXT
ASCII
Output
for internal use of Z88O No 2) Yes
Yes
Z88P.COL ASCII Input Color header file Z88P MS-Win Possible Yes No
Z88O.OGL
ASCII
Input
Color header file Z88O MS-Win Possible
Yes
No
Z88.FCD ASCII Input Fonts, Colors, Dimens. UNIX for Z88COM, Z88O and Z88P
Possible No Yes







Z88COM.CFG ASCII Input configuration file Z88COM No 2) Yes No







Z88O1.BNY Binary In/Output fast communication file No 3) Yes Yes
Z88O2.BNY Binary In/Output fast communication file No 3) Yes Yes
Z88O3.BNY Binary In/Output fast communication file No 3) Yes Yes
Z88O4.BNY Binary In/Output fast communication file No 3) 4) Yes Yes