ColorFabb ColorFabb LW-PLA-HT - 1.75mm (4 pack)
If you're in the market for a lightweight 3D printing material that offers exceptional temperature resistance, look no further than ColorFabb's LW-PLA-HT. This innovative formula is specifically engineered for applications requiring durability and heat tolerance, making it ideal for creating 3D printed structures that can endure heat from external sources for extended periods.
- LW-PLA-HT significantly outperforms standard LW-PLA when it comes to temperature resilience, ensuring your prints maintain integrity even in warmer conditions.
- This advanced manufacturing technique results in lightweight 3D printed parts that don’t compromise strength or performance.
- Unlike many other materials, LW-PLA-HT retains its shape well when exposed to heat, making it a reliable choice for various projects.
- Customize your 3D prints effortlessly—LW-PLA-HT is fully compatible with paints, allowing for easy personalization of your models.
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ColorFabb LW-PLA-HT Filament - 1.75mm (0.75kg) - 4 Pack
Lightweight with Enhanced Heat Resistance
An advanced 3D printing material that offers lightweight properties alongside enhanced heat resistance, ColorFabb's LW-PLA-HT stands out. Whether for hobbyist projects or professional applications, this material provides the strength and versatility needed for high-quality 3D printed creations.
Key Features of the ColorFabb LW-PLA-HT Filament - 1.75mm (0.75kg) - 4 Pack:
- This material offers excellent heat resistance thanks to its high-temperature formula.
- The active foaming process produces strong yet lightweight 3D parts with higher density.
- The darker colors in this 4-pack (Black, Olive Green, and Dark Gray) exhibit better shape retention.
- The four neutral colors feature a matte finish and can be customized further with paint.
- Thin and lightweight 3D prints can be easily modified through sanding, trimming, and cutting.
Versatile and Creative Applications
LW-PLA-HT is ideal for a wide range of applications, including RC planes, cosplay items, and general lightweight objects that will retain their shape and strength.
- Build lightweight, heat-resistant components for your remote-controlled aircraft.
- Create durable, custom cosplay accessories that can withstand the rigors of conventions and events.
- From prototypes to unique designs, this material enables the creation of a range of structures that are both light and sturdy.
Strength Under High Heat
Thin 3D printed structures will be able to handle heat from external sources, such as the sun, for a prolonged period of time.
- LW-PLA-HT contains a foaming agent that activates at around 220 °C printing temperature.
- 3D printed parts will retain their structure and shape, even under high heat.
- Black, Olive Green, and Dark Gray will exhibit better shape retention.
Upgrading from LW-PLA to LW-PLA-HT
What you need to know when upgrading from LW-PLA to LW-PLA-HT.
CALIBRATE YOUR SETTINGS
YOU ONLY NEED 11 GRAMS OF FILAMENT AND 50 MINUTES OF PRINTING TIME.
LW-PLA-HT contains a foaming agent that activates at around 220 °C (depending on the other settings used). To calibrate your 3D printer settings, we developed a simple but effective 4-step process:
- 3D print our calibration cubes.
- Measure the wall thickness of the cubes.
- Enter the values in our Excel file
- Test print to confirm calculated values. Adjust the flow setting until the part has the strength you need.
Step 1.
You can download the files over at Printables, click here. Beware that our premade calibration file is for printing at 0.2mm layer height using a 0.4mm nozzle and 40 mm/s print speed. You can change these values to reflect your preferred settings.
Step 2.
After printing the calibration cubes, before removing them, label each cube with the printing temperature as reflected in your file settings. You need to measure the thickness of the perimeter line at each side of the cube and use our excel file to process the data.
Step 3.
Insert the values into the excel file included in our files (click here) and have a graph plotted of the average values per cube, for each printing temperature.
We also plotted a secondary graph, which shows you the relation between Material Flow [percentage] as a function of the printing temperature. In this graph, you can easily see which percentage of flow you would need at a minimum to achieve the expected perimeter wall thickness. For this graph, we used the following calculation: New Material flow = (100% Flow / (max perimeter width/perimeter width at 210°C))
Step 4.
Now you can select a part to test the calculated values you found for your setup.
Usually, the calculated flow value is lower than you would actually use for a sufficiently strong part. You might need to increase the flow rate by 5-10%. For RC planes, we found 230C - 0.2mm layer height - 50/60% flow to result in sufficiently strong prints on our Prusa MK3s
Keep in mind that if the pre-made files you bought have very different print speed or layer height values than what you’ve tested with our calibration file, the value for the flow percentage will deviate. It would be best to repeat the calibration file with the key settings, such as speed and layer height, the same as set in the files you bought.
Curious which values we found? Below you can find the values we found for the LW-PLA-HT colors.
| LW-PLA-HT | ||||||
| 210 | 220 | 230 | 240 | 250 | 260 | |
| LW-PLA-HT Black | ||||||
| Average | 0.455 | 0.535 | 0.8475 | 1.0325 | 1.035 | 0.9675 |
| LW-PLA-HT Olive green | ||||||
| Average | 0.46 | 0.535 | 0.8625 | 1.0175 | 1.0275 | 0.9475 |
| LW-PLA-HT White | ||||||
| Average | 0.46 | 0.545 | 0.88 | 1.0275 | 1.0325 | 0.94 |
| LW-PLA-HT Dark grey | ||||||
| Average | 0.465 | 0.5475 | 0.875 | 1.0375 | 1.055 | 1.0425 |
LW-PLA-HT various colors - wall thickness vs print temperature. Sliced at 0.2mm layerheight / 40 mm/s / 0.4mm nozzle.
Calculating the theoretical material flow percentage needed for an extrusion width similar to the width when printed without foaming at 210°C:
New Material flow = (100% Flow / (max perimeter width/perimeter width at 210°C))
* Usually, the calculated flow value is lower than you would actually use for a sufficiently strong part. You might need to increase the flow rate by 5-10%. For RC planes, we found 230C - 0.2mm layer height - 50/60% flow to result in sufficiently strong prints on our Prusa MK3s
Keep in mind that if the pre-made files you bought have very different print speed or layer height values than what you’ve tested with our calibration file, the value for the flow percentage will deviate. It would be best to repeat the calibration file with the key settings, such as speed and layer height, the same as set in the files you bought.
IN CASE YOU BOUGHT PRE-MADE GCODES / FACTORY FILES
If you don't want to go through the process of calibrating your printer, because you bought pre-made Factory files or G-codes, you can use the following tips & tricks to get a smooth transition to LW-PLA-HT.
3MF / FACTORY FILE
If the RC plane you bought includes premade 3MF / Factory files, then you have the possibility to adjust all relevant settings. We suggest adjusting the following settings:
| LW-PLA | LW-PLA-HT | |
| 1st layer temp | Same as other layers | 200-210C |
| 1st layer flow | Same as other layers | 100% flow |
| 1st layer perimeter | Same as other layers | 2 perimeters |
| layerheight | Sometimes sliced at 0.3mm | Maximum 0.2mm (for 0.4mm nozzle) |
| temperature | 230-240C | 230-240C |
| Flowrate | 40-45% | 50-60% |
| Heated bed | 50C | 60C |
| Bed Adhesion | - | Brim for large parts |
| Adhesion promoter | - | 3DLac |
The first layer is partially stuck to the plate. To prevent these issues, we recommend the following settings.
- 1st layer print temp – 200/210°C
- 1st layer flow – 100% flow (we’re not activating the foaming agent at these temperatures)
- 1st layer perimeter – 2 perimeters for additional strength.
Perfect flat part and is easy to remove. You can download the Simplify3D template file here: LW-PLA-HT template factory file.
GCODE ONLY
If the plane you bought includes premade G-codes only, then you’ll have to adjust the flow rate manually using your 3D printer control panel. How much you need to increase the flow rate depends on the flow rate that has been set in the file. It’s expected that you need to increase anywhere between 10-20% increased flow rate. Try printing a small part and measuring the thickness of the extruded perimeter to see if this matches what it should be.
Technical Specifications
| Mechanical Properties - 3D Printed | Method | Value at Foaming | Unit |
| 210˚C; 100%|230%; 60% | |||
| Youngs Modulus | Tensile, ISO 527-1A | 3000|1050 | MPa |
| Tensile Strength | Tensile, ISO 527-1A | 35|9 | MPa |
| Elongation at break | Tensile, ISO 527-1A | 3|1.8 | % |
| Flexural Modulus | Flexural, ISO 178 | N/A|N/A | MPa |
| Flexural Strength | Flexural, ISO 178 | N/A|N/A | MPa |
| Impact Strength | Charpy Notch, ISO 179 | 2.6|<1 | kJ/m2 |
| Heat Deflection Temp. | HDT-B, ISO 75 | 72|N/A | |
| Mechanical Properties – Injection Molded* | Method | Value | Unit |
| Youngs Modulus | Tensile, ISO 527-1A | 3800 | MPa |
| Tensile Strength | Tensile, ISO 527-1A | 55 | MPa |
| Elongation at break | Tensile, ISO 527-1A | 3 | % |
| Flexural Strength | Flexural, ISO 178 | N/A | MPa |
| Impact Strength | Charpy Notch, ISO 179 | 2.8 | kJ/m2 |
| Density | ISO 1183 | 1,2 | g/cm3 |
*These results are obtained from printed samples of UNFOAMED PLA-HP
| Thermal Properties* | Method | Value | Unit |
| Glass Transition Temp. | DSC, ISO 11357 | N/A | ˚C |
| Melting Temp. | DSC, ISO 11357 | N/A | ˚C |
| Decomposition Temp. | TGA, ISO 11358 | N/A | ˚C |
| Heat Deflection Temp. | HDT-B, ISO 75 | 135 | ˚C |
| Melt Flow Index | MFI, (210˚C/2.16 kg), ISO 1133-A |
N/A | g/10min |
| Melt Flow Index | MFI, (190˚C/1,16 kg), ISO 1133-A |
N/A | g/10min |
*These results are obtained from printed samples of UNFOAMED PLA-HP
| Filament Specifications | Unit | ||
| Diameter | mm | 1.75 | 2.85 |
| Max. roundness deviation | mm | ± 0.05 | ± 0.1 |
| Net. Filament weight | g | 750 | 750 |
| Guideline for print settings | Unit | |
| Nozzle Temp. | ˚C | 195-240 |
| Bed Temp. | ˚C | 50-60 |
| Bed/surface modification | - | - |
| Active cooling fan | % | - |
| Print Speed | mm/s | 40-100 |