Makro Halb-Rumpf Modell

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Macro Half-Hull Model

Beschreibung
Dieses Makro erzeugt sowohl dreidimensionale Halb- als auch Vollrumpfmodelle aus einer Reihe von 2D-Linienzeichnungen.
Dieses Makro erstellt einfache Modelle der Rümpfe von Booten und Schiffen. Es soll Menschen helfen, die Rümpfe modellieren oder entwerfen, indem es die Oberfläche des Rumpfes in einer einfachen und zeitnahen Weise bereitstellt, so dass sie den zeitaufwendigen vollständigen Prozess vermeiden können.

Versionsmakro : 1.0
Datum der letzten Änderung : 2016-01-25
FreeCAD version : <= 0.16
Herunterladen : WerkzeugLeiste Symbol
Autor: Piffpoof
Autor
Piffpoof
Herunterladen
WerkzeugLeiste Symbol
Links
Macro-Version
1.0
Datum der letzten Änderung
2016-01-25
FreeCAD-Version(s)
<= 0.16
Standardverknüpfung
None
Siehe auch
None

Beschreibung

Dieses Makro erstellt einfache Modelle der Rümpfe von Booten und Schiffen. Es soll Personen, die Rümpfe modellieren oder entwerfen, helfen, indem es die Oberfläche des Rumpfes auf einfache und zeitnahe Weise bereitstellt, so dass sie den zeitaufwändigen vollständigen Prozess vermeiden können.

Temporary code for external macro link. Do not use this code. This code is used exclusively by Addon Manager. Link for optional manual installation: Macro


# This code is copied instead of the original macro code
# to guide the user to the online download page.
# Use it if the code of the macro is larger than 64 KB and cannot be included in the wiki
# or if the RAW code URL is somewhere else in the wiki.

from PySide import QtGui, QtCore

diag = QtGui.QMessageBox(QtGui.QMessageBox.Information,
    "Information",
    "This macro must be downloaded from this link\n"
    "\n"
    "http://pastebin.com/raw/tZMpUi6F" + "\n"
    "\n"
    "Quit this window to access the download page")

diag.setWindowFlags(QtCore.Qt.WindowStaysOnTopHint)
diag.setWindowModality(QtCore.Qt.ApplicationModal)
diag.exec_()

import webbrowser 
webbrowser.open("http://pastebin.com/raw/tZMpUi6F")
<class="rawcodeurl"><a href="http://pastebin.com/raw/tZMpUi6F">raw code</a>


Hintergrund

Seit der Antike mussten Bootsbauer Boote entwerfen und sie dann in einer dreidimensionalen Umgebung realisieren, in der nur wenige Linien gerade, nur wenige Flächen eben und keine Winkel über eine Strecke konstant sind. Anhand von Rumpfmodellen wurden maßstabsgetreue Modelle angefertigt, die dann zur Überprüfung des Entwurfs oder zur Kommunikation von Konzepten mit anderen Personen verwendet werden konnten. Die Gesetze der Hydrodynamik verlangen, dass jedes Schiff, das sich durch eine Flüssigkeit bewegt, im Querschnitt symmetrisch sein muss, wenn es genau verfolgt werden soll (sich in einer geraden Linie bewegen soll). Folglich genügte es, eine Seite des Rumpfes im Modell zu bauen - wenn der halbe Rumpf perfekt war, dann würde auch sein Spiegelbild perfekt sein. In späteren Jahren wurden Halbrümpfe für symbolische Zwecke wie Plaketten und nautische Kunst verwendet.

Dieser Code entstand aus einem Projekt zur Erstellung eines Modells in FreeCAD von einem 12,5 Meter langen Segelboot. Die Erbauer hatten keine Zeichnungen mehr und der Sohn des ursprünglichen Besitzers bezweifelte, dass es jemals vollständige Zeichnungen gab. Folglich mussten die Rumpfabmessungen gemessen und dann ein Modell in der Software konstruiert werden. Moderne Softwarepakete wie FreeCAD bieten viele vorteilhafte Funktionen wie Symmetriebeschränkungen, aber wenn die endgültige Messung ein Modell ist, das "einfach zu sehen" ist, ist viel "Massieren" von Modellen erforderlich. Dieser Code wurde geschrieben, um diesen Prozess zu automatisieren.

Der ursprüngliche Zweck dieses Codes war es, einen symmetrischen Rumpf bereitzustellen, der formbar war, damit er an das zu konstruierende 3D Modell angepasst werden konnte. Im weiteren Verlauf wurde die Software verallgemeinert, so dass sie hoffentlich für Personen von Nutzen sein wird:

  • Bootskonstrukteure, die Bootspläne erstellen, aus denen gebaut werden kann
  • Bootsbauer, die versuchen, das zu modellieren, was auf ihren Plänen beschrieben ist
  • Modell Rumpf Bauer.

Sicherlich haben gewerbliche Bootskonstrukteure alle Arten von High End Software, um ihre Arbeit zu unterstützen, dies ist nicht dazu gedacht, dies zu ersetzen. Vielmehr ist dies für den Bastler oder Heimwerker zum Herumtüfteln gedacht.

Nautische Blaupausen haben eine eigene Geschichte in Bezug auf Bauten und sind daher etwas anders in der Darstellung. Dies ist ein Beispiel für ein Segelboot, das mehr als ein Jahrhundert alt ist:

Eines der Endziele dieser Software ist es, mit der Entwurf Arbeitsbereich einige dieser Pläne zu generieren, indem das Modell zur Erzeugung der Linien verwendet wird.

Hinweis zu Einheiten in FreeCAD:

Zur Zeit gibt es kein wirkliches Einheiten Handhabungssystem in FreeCAD, aber natürlich braucht ein Bootsbauer oder Modellbauer ein genaues Bemaßungssystem. Um dieses Makro zu verwenden, entscheide dich, die FreeCAD Rastergröße auf das einzustellen, was immer für deine Arbeit angemessen ist (z.B. mm, cm, Zoll, Fuß). FreeCAD ist konsistent, eine FreeCAD Einheit wird immer gleich einer FreeCAD Einheit sein. Und wenn du dich entschieden hast, dass eine FreeCAD Einheit einer bestimmten physikalischen Länge entspricht, dann werden deine Zeichnungen konsistent bemaßt bleiben. Zur Zeit wird an einem Einheitensystem für FreeCAD gearbeitet, so dass sich diese Situation bald ändern könnte.

Beschreibung

Für dieses Makro werden die Rumpfformen durch ein Minimum von 3 FreeCAD Skizzen definiert: eine in der YZ Ebene, eine oder mehrere in der XZ Ebene, eine in der XY Ebene. Hier ist der minimale Rumpf, der von diesem Makro unterstützt wird, er hat nur 3 Skizzen:

Anmerkung: In der obigen Abbildung schauen wir direkt auf das Heck, der Bug zeigt vom Standpunkt weg.

From front to back (bow to stern) the 3 Sketches are:

stemline
YZ plane
red line in sketch
cross-section
XZ plane
green line in Sketch
transom
XY plane
blue line in Sketch


Vielleicht ist es mit 7 Skizzen (eine in der YZ Ebene, eine in der XY Ebene und 5 in der XZ Ebene) einfacher zu sehen:

Mit 5 Skizzen in der XZ Ebene wird es immer einfacher, die Form des Rumpfes zu erkennen. Die nächsten 2 Bilder zeigen die Skizzenlinien, die dem von FreeCAD konstruierten Modell überlagert sind,

das zweite ist das gleiche Modell um 90 Grad gedreht, so dass der Bug im Vordergrund ist:

Some points to consider:

  • the Sketches are only for:
    • the stemline (or bow line) in the YZ plane (red in the above diagram);
    • the top of the transom in the XY plane (blue in the above diagram);
    • multiple cross-sections of the hull in the XZ plane (green in the above diagram)
  • only the starboard side of the hull is drawn in the Sketches, the port side will be generated as a mirror image
  • each multiple-segment line must be in a separate Sketch
  • each Sketch must have the same number of line segments (which is 3 in the previous examples)
  • the more line segments in each Sketch, the closer the FreeCAD generated model will approximate a curved hull
  • there is no limit to the number of line segment in each Sketch, any number from one up
  • there is no limit to the number of Sketches in the XZ plane (i.e. cross-sections), any number from one up

With enough Sketches the model generated may even approach:

Das HalbRumpf Makro erzeugt 4 Modelle:

  • starboard half-hull
  • port half-hull
  • complete hull
  • bulkheads for the complete hull, either with a flush deck or with a coachhouse

These models are all output in the unified location space of FreeCAD so they can be fitted together - for example the bulkheads can be inserted into the complete hull seamlessly. This is a picture of bulkheads in a boat model during construction:

As well as the bulkheads generated by the macro (note that these bulkheads are for a coachhouse rather than a flush deck):

The composite image below shows the main outputs from this software (the port side half-hull is actually not shown but it is the mirror of the starboard half-hull which is shown). The outputs are in clockwise order from the upper left corner:

  • starboard half-hull
  • complete hull
  • bulkheads (for flush deck, the bulkheads in the previous image were for a coachhouse deck)
  • the complete hull with the bulkheads inserted

As novelty features, the macro will also optionally produce plaques for the half-hulls, and even a bottle for the complete hull:

Installation

All the code for halfHullModel.FCMacro is in one macro. So installation is comprised of copying the code to the appropriate Macro directory and invoking the Build Utility from the Macro menu, the Python console or a toolbar button (the preferred method).

Anwendung

The FreeCAD operations involved in generating the hull model are rather complex and numerous. Things like the direction a line is drawn can cause the FreeCAD construction of the hull to either abort or turn out like:

Consequently the steps below need to be followed closely. The macro does allow for certain data inconsistencies but generally if the data (i.e. the Sketches) are incorrect then the output will look like a cheese grater or the macro fill fail with an error.

The following instructions refer to the quadrants of the XY graph, this refers to the 4 quarters of the XY graph and they are labelled as follows:

Create a New Document

The very first thing is to create a new document in FreeCAD . This document will hold all the Sketches that make up your hull definition.

Create the Stemline

The first step is one of creating data for the hull model to be made from. The data is supplied in the form of Sketches within FreeCAD. After the hull model is generated, if changes are to be made then the Sketches are simply edited, and the second step of running the macro repeatedly.

  1. create a new sketch , in the YZ-Plane
  2. start at origin (0,0) and draw upwards into Quadrant I
  3. the bottom end of the stemline is at the origin (0,0) - this will be the point from where the placement of all the cross-sections and transom will be made
  4. the number of line segments in this Sketch determines the number which will be required in each other Sketch
  5. save sketch
  6. for ease of identification it is probably worth naming the Sketch something like "stemline sketch"

Create the Cross-section Sketch(es)

  1. create a new sketch , in the XZ-Plane
  2. the following dialog will appear:

    The dialog is asking how far from the origin the Sketch should be placed. This will refer to how far the cross-section is from the bottom of the stemline (which was placed at (0,0)). The cross-sections can be equally spaced but need not be. The forward-most cross-section will be at Y=0 (i.e. the origin where the stemline bottom ends) or at Y<=0. The cross-sections will be at increasingly negative Y values until the transom is at the most negative Y value. In the example above, the cross-section Sketch will be placed 50 FreeCAD units from the origin on the negative Y axis.
  3. start on the Y axis and draw upwards into Quadrant I
    - the first (i.e. foremost) cross-section should start at origin (0,0) (or it will look odd as the stemline ends at 0,0) but other cross-sections need only start on the Y axis.
  4. use the same number of line segments as in the Stemline Sketch
  5. save sketch
  6. repeat as this step necessary, it may be quicker to copy this sketch and then space the copies on the Y-axis, modifications may be made to the individual Sketches as required
  7. for naming, it will make things easier to give some sort of sequence to the cross-sections, starting at the bow (i.e. the stemline) and increasing towards the stern (i.e. the transom)

Create the Transom Sketch in the XY Plane

  1. create a new sketch , in the XY-Plane
  2. start on the Y axis between quadrant III and IV, and draw upwards into Quadrant IV so that the end point is coincident with the rightmost point of the lowest cross-section Sketch in the YZ-plane
  3. use the same number of line segments as in the stemline Sketch
  4. save sketch
  5. for ease of identification it is probably worth naming the Sketch something like "transom sketch"

Save the New Document

Now save the document which contains the Sketches that will define the hull shape, giving it some name that is descriptive

Once the Sketches have all been created and positioned, the document should look like this from the top view :

The principal limitations for constructing the model are:

  • the stemline bottom should end at (0,0)
  • the bottom centremost end of each cross-section should end at the Y axis - note that it can have any Z value

This concludes the first step which is one of creating the data which the macro will use to create both half-hulls and complete-hulls. The second step is described in the following section which is titled User Interface

User Interface

In this step the macro will gather some information from the user and then process the input Sketches to generate the desired hull models. This is the only GUI image for the macro and is primarily configuration details for the production of the hull models from the Sketches:

The choices on the GUI window are:

  • Starboard half-hull
    - checking this will cause the macro to produce a starboard half-hull model
    • Mounting plaque
      - if checked the macro will mount the half-hull on a plaque
      • Allow space for keel
        - if checked will cause the half hull to be mounted higher on the plaque than the centre position, this is so a separately generated keel could be placed below the hull
  • Port half-hull
    - checking this will cause the macro to produce a port half-hull model
    • Mounting plaque
      - if checked the macro will mount the half-hull on a plaque
      • Allow space for keel
        - if checked will cause the half hull to be mounted higher on the plaque than the centre position, this is so a separately generated keel could be placed below the hull
  • Complete hull
    - checking this will cause the macro to produce a complete model
    • Bottle for complete hull
      - if checked the macro will place the complete hull inside a transparent bottle (complete with cork)
      • Allow space for keel
        - if checked will cause the half hull to be positioned higher in the bottle than the centre position, this is so a separately generated keel could be placed below the hull
  • Bulkheads for flush deck
    - checking this will cause the macro to produce bulkheads whose tops are level with the top of the hull, bulkheads will not be generated for the most forward 2 cross-sections or the aft-most 2 cross-sections
  • Bulkheads for coachhouse
    - checking this will cause the macro to produce bulkheads whose tops are possibly above the top of the hull.
    • Bulkheads to skip at bow determines how many cross-sections will be left without a bulkhead at the bow
    • Bulkheads to skip at stern determines how many cross-sections will be left without a bulkhead at the stern
  • The dimensions of the top of the bulkheads will be configured as per the following diagram:
  • Cancel button
    - the execution is halted and the window closes
  • Re-Use Last File button
    - the execution uses the data file AND SETTINGS from the the last run, any changes to settings are ignored
  • Select File button
    - the standard Open File window is opened where the user can either select a file or Cancel and exit

When the macro runs it takes configuring data from the user and then reads Sketcher sketches in the selected input file.

Note: As the macro works through the Sketches it prints out any exceptions as well as some milestones on the Report View. If you get unexpected results or some parts are missing, that is probably the first place to check.

Options

There are various types of bows and sterns for boats, with sterns having much more variety than bows. Here are examples of transoms and bows from the real world alongside the similar macro output:

Sheer Stern

Probably the most common stern, typical of all sizes of vessels from commercial ships through to rowing boats.

  • the XY transom should be as close to the aftmost cross-section as is possible.

Sugar-Scoop Stern

Most likely to be found on a sailing yacht, it is a product of designing to maximise the length of the waterline to benefit from class rules for racing under sail.

  • place the aftmost 2 cross-sections as close as is feasible, then rotate the aftmost of the two through to an angle of 45 degrees (or whatever is called for) around the X-axis

Canoe Stern

Found on all sizes of water craft, power and sail, pleasure and commercial.

  • place the aftmost 2 cross-sections as close as is feasible, then rotate the aftmost of the two through to an angle of 45 degrees around the X-axis

Normal Bow

There is a lot less variety in bow shapes than with transoms:

Trireme Bow

Although not seen very frequently in the last 2 millenia, this was once the definitive bow profile for war-making vessels:

  • in order for the bow to be correct the poly-line for the stemline needs to be drawn from the bottom to the top which will mean right to left in the Sketcher

Sample Files

These files are samples of Sketch data to use with the macro, mainly they are the models for the screen snapshots in the Options section above. The files work with the Macro and so can be downloaded and played with to adapt to your specific requirements. The prefix of 5x3 (for example) means the model has 5 cross-sections and 3 line segments per cross-section (i.e. sketch)

To use one of the example files, right-click on the file link and select Save File As... from the menu. The filename will be specified, choose the desired folder/directory to hold the example file.

Remarks

  • almost all the examples on this page are generated with only 3 line segments defining the side of the hull which gives a very faceted appearance, increasing the number of segments in each Sketch would generate a much smoother surface which would increase the realism
  • doesn't do keels, skegs or rudders, in other words, it doesn't do any of the wet area
  • doesn't do square bows like push-boats or towed barges
  • doesn't do submarines (although it will do the lower half of a submarine)

Known Problems

The 'Ruled Surface' feature of FreeCAD is used to generate the hull sections from the Sketches. It can sometimes generate the wrong result and display a grater like surface instead of a smooth planar one. This will typically occur when the Sketches are rotated such as when a Sugar Scoop stern is modeled. Also angling a Sheer Transom stern can cause this. If it occurs then typically it will do so in either the half-hull models or the complete hull model - it never seems to occur in all three models for the same hull. Also it usually only happens at the extreme bow or stern. If it happens to section in the middle of the boat then most likely one of the Sketches was drawn in the wrong direction (i.e. either random sequence or top-down where as all lines should be drawn bottom-up)

It can usually be removed by using the following steps:

  • in the Model tab of the Combo View, click on the faulty segment to select it, the faulty segment will show as highlighted on the display
  • select the Data tab on the bottom half of the Combo View, the lower part of the window will have a Label "Ruled Surface" with a single parameter 'Orientation'
  • there is a popup menu to the right which has the values 'Automatic', 'Forward', 'Reversed', it will initially be set to 'Automatic'
  • try one of the other settings (remembering the faulty segment must still be selected in the upper part of the Combo View) which will usually correct the problem

The following screen snapshot shows the relevant portion of the screen:

Future Possibilities

  • replace line segments of cross-sections with curved lines
    - this is just at the idea stage but would give a much smoother surface in the vertical dimension, however the horizontal surface would still be faceted as it is now
  • integrate with Draft workbench to produce drawings from models
    - an initial goal, but the feasibility has not been investigated
  • handle keels, skegs and rudders
    - one work around for keels with the present system is to model the keel as a half-hull on it's own and then assemble it onto the bottom of the main hull; this would still do nothing for rudders and skegs though

Glossary

As with any ancient and practiced trade, a rich and sometimes confusing vocabulary has developed around ships, boats and nautical practices. In describing this macro it is both awkward and inefficient to describe the process without using the correct and accurate terms. The obvious problem is that the average lay person will be unfamiliar with such terminology, hence this vocabulary:

aft the rear aspect of anything on a boat


chine a planar facet of a hull, can be used to approximate a curved surface or as a finished building technique


coachhouse the part of the central deck which is raised above the deck level - usually to accommodate increased headroom in the interior of the boat


flush deck a deck that runs smoothly from the top of one side of the hull to the other, the converse to a coachhouse deck


forward also 'fore'; the front aspect of anything on a boat


port lefthand side looking forward


starboard righthand side looking forward


stemline the sloped vertical edge which is the bow of a hull


transom the curved top edge of the stern face which can be flat or curved

Links

Script

ToolBar Icon

Macro_Half_Hull_Model.FCMacro

This script is running bug free. But due to the large range of possible inputs it may fail for some inputs. If so please report it.

The script is too long for the Wiki to display so it must be copied or downloaded from unabbreviated script on pastebin.com