Difference between revisions of "Introduction to Revit"
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== 2. Designing the NYU Keychain == | == 2. Designing the NYU Keychain == | ||
# First, ensure that the units of your drawing are in inches. They are in the Browser on the left side of the window under "Document Settings". | # First, ensure that the units of your drawing are in inches. They are in the Browser on the left side of the window under "Document Settings". | ||
# Start a 2D Sketch by clicking "Create Sketch" (Figure 2). [[Image: | # Start a 2D Sketch by clicking "Create Sketch" (Figure 2). [[Image:Lab 1B2 V2.jpg|thumb|center|600px|Figure 2: Sketch Mode]] | ||
# Select the XZ plane (Figure 3). [[Image:Lab 1B3.jpg|thumb|center|600px|Figure 3: XZ Plane]] | # Select the XZ plane (Figure 3). [[Image:Lab 1B3.jpg|thumb|center|600px|Figure 3: XZ Plane]] | ||
# Select the 2-Point Rectangle from the "Sketch" section of the toolbar (Figure 4). [[Image:Lab 1B4.jpg|thumb|center|600px|Figure 4: 2-Point Rectangle]] | # Select the 2-Point Rectangle from the "Sketch" section of the toolbar (Figure 4). [[Image:Lab 1B4 V2.jpg|thumb|center|600px|Figure 4: 2-Point Rectangle]] | ||
# Draw a 2.6” × 0.7” rectangle <b>starting at the origin.</b> Click once at the origin to place one point of the rectangle and click one more time to place the second point of the rectangle. The length values can be typed in before placing the second point of the rectangle (switching which value is changed is done using the Tab key). | # Draw a 2.6” × 0.7” rectangle <b>starting at the origin.</b> Click once at the origin to place one point of the rectangle and click one more time to place the second point of the rectangle. The length values can be typed in before placing the second point of the rectangle (switching which value is changed is done using the Tab key). | ||
# Select the Center Diameter Circle from the "Sketch" section of the toolbar. | # Select the Center Diameter Circle from the "Sketch" section of the toolbar. | ||
# Draw a 0.7” diameter circle centered in the middle of one of the 0.7" sides of the rectangle (the cursor should become a blue X with a triangle and snap to the midpoint of the line when you get close. | # Draw a 0.7” diameter circle centered in the middle of one of the 0.7" sides of the rectangle (the cursor should become a blue X with a triangle and snap to the midpoint of the line when you get close) (Figure 5). Similar to the 2-Point Rectangle, the diameter of the circle can by typed. [[Image:Lab 1B5.jpg|thumb|center|600px|Figure 5: Center Diameter Circle]] | ||
# Draw another circle 0.45” in diameter in the same position. The sketch should look like Figure 6.[[Image:Lab 1B6.jpg|thumb|center|600px|Figure 6: Circles of Keychain Base]] | # Draw another circle 0.45” in diameter in the same position. The sketch should look like Figure 6.[[Image:Lab 1B6.jpg|thumb|center|600px|Figure 6: Circles of Keychain Base]] | ||
# Fillet (round) the corners of the base. Select the Fillet tool from the "Sketch" section of the toolbar (Figure 7). [[Image:Lab 1B7.jpg|thumb|center|600px|Figure 7: Fillet Tool]] | # Fillet (round) the corners of the base. Select the Fillet tool from the "Sketch" section of the toolbar (Figure 7). [[Image:Lab 1B7.jpg|thumb|center|600px|Figure 7: Fillet Tool]] |
Revision as of 00:23, 21 January 2020
Objective
This exercise will introduce Autodesk Fusion 360, which is a drafting software that is used by technical professionals, and basic technical design methods will be shown using this computer-aided design (CAD) software. This software will be used in the semester-long design project (SLDP) by constructing physical prototypes with 3D printing. To practice this prototyping procedure, an NYU logo keychain will be created in Autodesk Fusion 360 and prepared in Cura to be 3D printed.
Overview
Computer-Aided Design
CAD programs, which include Autodesk's Fusion 360, AutoCAD, and Revit; Dassault Systèmes SolidWorks; and Google SketchUp, allow engineers to make dimensioned, scaled drawings. These drawings are used to manufacture equipment, build infrastructure, and allow designers to display their designs with complete specifications and detail. Orthographic views (top, bottom, side, front, back) can be used to document the technical specifications in drawings needed for production while axonometric views (isometric, dimetric, trimetric) can be used to view the final 3D representation of a product.
This exercise will teach the basics of Autodesk Fusion 360, 3D file formats, the basics of 3D printing, and the skills needed to create simple 3D files and prepare them to be 3D printed.
3D Printing
3D printing allows rapid prototyping and onsite manufacturing of products. Initially done with plastic, 3D printing now uses new techniques with new materials, such as aluminum, bronze, and glass. Biomaterials are also being used, such as 3D printing ear cartilage and liver tissue. As the 3D printing industry grows, 3D printing has become a significant part of many engineering fields.
In this course, 3D printing can be used to produce prototype components, building models, SLDP course modifications, robot parts, and a company logo.
Procedure
1. Setting up the File
- Launch AutoDesk Fusion 360, click Create Account, and fill in the information. Important: Make sure to use an NYU email (Figure 1).
2. Designing the NYU Keychain
- First, ensure that the units of your drawing are in inches. They are in the Browser on the left side of the window under "Document Settings".
- Start a 2D Sketch by clicking "Create Sketch" (Figure 2).
- Select the XZ plane (Figure 3).
- Select the 2-Point Rectangle from the "Sketch" section of the toolbar (Figure 4).
- Draw a 2.6” × 0.7” rectangle starting at the origin. Click once at the origin to place one point of the rectangle and click one more time to place the second point of the rectangle. The length values can be typed in before placing the second point of the rectangle (switching which value is changed is done using the Tab key).
- Select the Center Diameter Circle from the "Sketch" section of the toolbar.
- Draw a 0.7” diameter circle centered in the middle of one of the 0.7" sides of the rectangle (the cursor should become a blue X with a triangle and snap to the midpoint of the line when you get close) (Figure 5). Similar to the 2-Point Rectangle, the diameter of the circle can by typed.
- Draw another circle 0.45” in diameter in the same position. The sketch should look like Figure 6.
- Fillet (round) the corners of the base. Select the Fillet tool from the "Sketch" section of the toolbar (Figure 7).
- Select one of the two intersecting lines that form the right angles on the base. Set the fillet radius to 0.125" and repeat on the other corner. The sketch should look like Figure 8.
- Remove the extra lines using the trim tool. Select the trim tool from the “Sketch” section of the toolbar.
- Select all interior lines that divide the keychain.
- If error messages are indicated, remove the dimensions on the rest of the keychain.
- The sketch should look like Figure 9.
- Exit the sketch using the "Stop Sketch" button.
- After creating a 2D sketch, the next step is to use that to create a 3D object. In this lab the extrude tool will be used to create a 3D block. In the future, the revolve or other tools can be used to create more advanced geometry.
- Select the “Extrude” tool from the “Create” section of the toolbar (Figure 10).
- Select the profile of the object to be extruded, which is the object that was just created.
- Change the extrusion thickness to 0.15” and press Enter.
- The model will look like Figure 11.
- Select the “Extrude” tool from the “Create” section of the toolbar (Figure 10).
- The next step is to add the design to the key chain. For this lab, a vector graphics file will be used in the dxf format provided by NYU. In the future, a logo can be designed using the sketch tool.
- Download the NYU Tandon Vector Logo (This logo was converted from the file provided on NYU's identity page).
- Select “Insert DXF" under the "Insert" section of the toolbar. (Figure 12)
- Select the top surface of the key chain (Figure 13).
- Rotate the camera again to orient the top correctly.
- Click on the file folder on the window that pops up and select .dxf file you downloaded.
- The logo should appear. (Figure 14)
- Make sure you change the units to inches.
- For this side of the key chain the "Tandon School of Engineering" portion of the logo is not needed.
- Select the bar and everything to the right using click and drag (Figure 15).
- Delete this portion with the “Delete” key on the keyboard (Not Backspace).
- The logo needs to be scaled to fit the key chain. To keep the spacing of the design, select an appropriate base point. Use the midpoint of the line on the right side of the box.
- Select the point tool under the "Sketch" section of the toolbar.
- Place a point at the center point of the right side of the box.
- Delete the bottom and the left side of the box. (Figure 16)
- Select the "Scale tool from the "Modify" section of the toolbar.
- Select the box and torch of the logo by clicking and dragging.
- Select the midpoint that was just placed as the base point for scaling
- Enter a scaling factor of 0.75. (Figure 17)
- Redraw the 2 sides of the box we deleted using the line tool in the “Sketch” section of the toolbar. (Figure 18)
- The logo will be positioned on the keychain.
- Select the entire logo and use the “Move” tool from the Modify section of the toolbar to move it off the base so there is space to draw the alignment line.
- Select the line tool and draw a 0.925” line from the center of the circle towards the center of the keychain.
- Select the logo using the move tool again.
- Select “Point to Point” as the move type in the window that appears. (Figure 20)
- Select the midpoint from the side of the box and the end of the line you just created.
- The logo should snap to it. (Figure 21)
- Delete the guideline you created.
- Exit the sketch.
- The final sketch is shown in Figure 22.
- To finish this side of the keychain, the design must be cut into the base. To do this, the extrude tool will be used.
- To cut the design, select “Extrude" from the "Create" section of the toolbar.
- Select the profile of the design to cut, in this case, the area around the torch and each of the letters. (Figure 23)
- Select "Cut" from the drop down menu next to "Operation" in the window that appeared on the right. (Figure 24)
- Select a distance of -0.06".
- The final model is shown in Figure 25.
- To 3D print the design, export the file as an STL. This is the only format that can be opened by the 3d printing software.
- Click on triangle to the left "Document Settings" to expand the menu, and hover over "Units" to click on the "Change Active Units" button on the right to change to millimeters, but DO NOT set millimeters as the default (default units should be inches). This will convert the model into millimeters. Even though the models are built in inches, millimeters is the only unit that 3D printing software will recognize.
- Right click on the box above “Document Settings” and select “Save as STL”. (Figure 26)
- Click "OK" no need to change any of the setting.
- Make sure you save it to a location you'll remember like the desktop.
- The last step of the keychain is to make the white insert that will fit in the center to make it two colors.
- Click “File" in the toolbar at the top of the screen.
- Start a "New Design". (Figure 27)
- Create a rectangle with dimensions 2.2”x0.65”.
- Extrude the rectangle 0.12”.
- This model is shown in Figure 28.
- Save this the same way as before.
Preparing to print
- Now that the logo design is complete, the next step is to put it together in the 3D printing slicer software. We will be using Cura as the software for orienting parts on the printer and selecting the color of each object. It also generates toolpaths that the printer will follow to print the objects.
- Open Cura. If a menu pops up prompting for the printer, select the “Ultimaker 3”
- If a menu does not pop up, make sure the printer currently selected is “Ultimaker 3” on the top right corner
- Otherwise, click the arrow, select the “Add Printer” option, and add “Ultimaker 3.”
- To load your two files from above, select “Open File” on the top left corner and open the STL file containing the base of the keychain
- Using the “Rotate” tool on among the options to the left, rotate the part so the torch is facing up
- Uncheck the “Snap Scaling” option to allow for a more precise rotation
- Select “Open File” again and load the filler rectangle
- Again, orient the part correctly using the “Rotate” tool
- Cura, by default, drops the objects on to the build-plate and keeps objects apart. The following steps are needed to combine the filler rectangle within the keychain:
- Under “Preferences”, select “Configure Cura”
- Under “Viewport behavior,” make sure to deselect both “Ensure models are kept apart” and “Automatically drop models to the build plate” if they are not already deselected
- Save your preferences
- Return to the buildplate and make sure both objects are lying flat on the build-plate by using “Rotate” => “Lay Flat”
- If the “Lay Flat” tool does not lay the object flat, manually type in 0 mm in the “Move” tool for the Z axis
- Select the filler rectangle, and using the “Move” tool on the left, enter 0.15mm as the Z value to raise it vertically
- Select one object and choose a different extruder on the left. That piece will appear as a different color
- Drag the filler piece and place it in the keychain base part
- Export the file as a .gcode and upload it to the website
- Open Cura. If a menu pops up prompting for the printer, select the “Ultimaker 3”
Assignment
A *.gcode file must be submitted to eg.poly.edu. It is required for a lab report grade.
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