Tag: 3dprinting

Getting the print to stick to the bed is a common challenge for 3D printer users. If the print does not adhere well, it can warp, curl, or detach during printing. To avoid this, many users apply some adhesive to the bed before printing. But what kind of adhesive should you use? And how do you apply it correctly? Here are some of the most popular adhesives for 3D printing and their pros and cons.

A glue stick is a cheap and easy option that works for most filaments and beds. You just need to apply a thin layer of glue stick to the bed in a circular motion. Glue stick provides good adhesion and can be removed with water or alcohol. However, glue stick can leave a residue on the print, affect its appearance or quality, and dry out over time.

Hairspray is a spray-on product that contains polymers that bond to the bed and the filament when heated. Hairspray works for PLA and ABS filaments and can be used on glass, metal, or plastic beds. You just need to spray a thin and even layer of hairspray on the bed before heating it up. Hairspray provides strong adhesion and can smooth out minor imperfections on the bed. However, hairspray can be messy, sticky, clog the nozzle or fan of your printer, and be difficult to remove from the bed and the print.

Painter’s tape is a type of masking tape that has a low-tack adhesive that does not leave any residue. Painter’s tape works for PLA and PETG filaments and can be used on glass, metal, or plastic beds. You just need to cut strips of tape and apply them to the bed in parallel lines, overlapping them slightly. Painter’s tape provides decent adhesion and can be removed by peeling it off. However, painter’s tape can wear out quickly, need to be replaced often, and affect the texture and appearance of the bottom layer of your print.

These are some of the most popular adhesives for 3D printing, but there are others. You may also want to try Kapton tape, PEI sheet, Magigoo, BuildTak, or 3DLac. The best adhesive for you may depend on your preference, filament type, bed material, printer settings, and budget. You may also want to experiment with different adhesives and techniques to find what works best for you. The key is to ensure that your print sticks well without causing any damage or difficulty in removal.

You might have heard of Klipper, a firmware that runs on a Raspberry Pi and communicates with your printer’s microcontroller. But what are the advantages of Klipper over stock Marlin firmware?

Klipper can improve your print quality, speed, and reliability. It can also unlock features that are not available in Marlin, such as pressure advance, input shaping, and automatic bed leveling.

How does Klipper achieve these benefits? The main difference is that Klipper offloads the complex calculations from the microcontroller to the Raspberry Pi, which has much more processing power and memory. This allows Klipper to use more advanced algorithms and higher precision for motion planning and control.

Imagine being able to print faster and smoother, with less ringing, ghosting, and blobs. Imagine having more control over your printer settings and parameters, without having to recompile and flash the firmware every time. Imagine having a web interface that lets you monitor and manage your printer from anywhere. These are some of the things that Klipper can offer you.

If you are interested in trying out Klipper, you will need a Raspberry Pi, a USB cable, and some patience. You can find detailed instructions on how to install and configure Klipper on its official website: https://www.klipper3d.org/. You can also join the Klipper community on Discord or Reddit for support and tips. Happy printing!

If you are new to 3D printing, you might encounter some problems with your prints that can be frustrating and confusing. One of the most common issues is a clogged nozzle, which can affect the quality and accuracy of your prints. In this blog post, I will explain how to diagnose a clogged nozzle and what symptoms to look for on your 3D printed part.

A clogged nozzle is when the filament gets stuck or blocked inside the nozzle, preventing it from extruding properly. This can happen for various reasons, such as using low-quality filament, printing at the wrong temperature, or having dust or debris in the nozzle.

A clogged nozzle can cause several problems with your prints, such as under-extrusion, stringing, blobs, gaps, or layer shifts. These symptoms can ruin your print and waste your time and filament. It is important to diagnose a clogged nozzle as soon as possible and fix it before it gets worse.

The good news is that diagnosing a clogged nozzle is not very difficult. You just need to pay attention to some signs that indicate that something is wrong with your nozzle. Here are some of the most common symptoms of a clogged nozzle:

  • Under-extrusion: This is when the nozzle does not extrude enough filament to fill the gaps between the layers or the perimeters. This results in thin or missing walls, weak infill, or holes in the print.
  • Stringing: This is when the nozzle oozes filament during travel moves, creating thin strings or hairs between different parts of the print. This can make your print look messy and require post-processing to remove them.
  • Blobs: This is when the nozzle extrudes too much filament at certain points, creating bumps or lumps on the surface of the print. This can affect the smoothness and accuracy of your print and make it look unprofessional.
  • Gaps: This is when the nozzle skips or misses some parts of the print, leaving empty spaces or holes in the model. This can compromise the integrity and functionality of your print and make it look incomplete.
  • Layer shifts: This is when the nozzle moves out of alignment during printing, causing the layers to shift or misalign. This can distort the shape and dimensions of your print and make it unusable.

If you notice any of these symptoms on your 3D printed part, check your nozzle for clogging and either fix or replace the nozzle.

Sometimes, in Cura, you may encounter gaps in your prints that affect the quality and appearance of your parts. I want to explain how to fill in any gaps in Cura using some simple settings and tips. I’m assuming a properly calibrated 3d printer. If you haven’t done that, do that first.

Gaps can occur in different parts of your prints, such as the top and bottom layers, the walls, or the infill. There are different reasons for these gaps, such as under-extrusion, incorrect nozzle size, low flow rate, or wrong layer height. To fix these gaps, you need to adjust some settings in Cura that affect the amount and distribution of material in your prints.

One of the most important settings to check is the line width, which determines how wide each extruded line is. The line width should match your nozzle size or be slightly larger (up to 120% of the nozzle size). If the line width is too small, there will be gaps between the lines. You can find the line width settings under the Quality category in Cura.

Another setting that affects the gaps is the flow rate, which controls how much material is extruded by the printer. The flow rate should be 100% by default, but you can increase it slightly (up to 110%) if you notice under-extrusion or gaps in your prints. However, be careful not to over-extrude, as this can cause other problems such as blobs or stringing. You can find the flow rate setting under the Material category in Cura.

A third setting that can help you fill in the gaps is the top/bottom pattern, which determines how the top and bottom layers are printed. The top/bottom pattern can be either lines, concentric, zigzag, or triangles. The lines pattern is the fastest and most common option, but it can leave gaps between the lines if they are not aligned properly. The concentric pattern can create a smoother surface, but it can also create gaps if the nozzle moves too far from the center. The zigzag pattern can fill in the gaps better than the lines or concentric patterns, but it can also create more travel moves and stringing. The triangles pattern can create a strong and uniform surface, but it can also increase the print time and material usage. You can find the top/bottom pattern setting under the Shell category in Cura.

A clogged nozzle is one of the most common problems that can affect your 3D printer. It can cause poor print quality, filament jams, and even damage your printer. I talk a lot about how to fix something after something has gone wrong, but I realized that it would be much better to explain how to avoid having a problem in the first place.

The first step is to choose the right filament for your printer. Different filaments have different melting temperatures, flow rates, and properties. Some filaments, such as ABS, PLA, and PETG, are easy to print with and have low chances of clogging. Other filaments, such as wood, metal, or glow-in-the-dark, have additives that can increase the risk of clogging. If you want to use these filaments, make sure you have a nozzle that can handle them, such as a hardened steel or ruby nozzle.

The second step is to clean your nozzle regularly. You can use a needle or a wire to poke through the nozzle hole and remove any debris or filament residue. You can also use a cold pull technique, which involves heating up the nozzle, inserting a piece of filament, letting it cool down slightly, and then pulling it out with a quick motion. This can help remove any material that is stuck inside the nozzle.

The third step is to calibrate your printer settings. You should check your extrusion multiplier, retraction distance, retraction speed, and temperature settings. These settings affect how much filament is pushed through the nozzle and how fast it cools down. If these settings are too high or too low, they can cause over-extrusion or under-extrusion, which can lead to clogging. You can use a calibration cube or a test print to fine-tune your settings and achieve optimal results.

One of the most common problems that 3D printing enthusiasts face is getting their prints to stick to the bed properly. If the print does not adhere well to the bed, it can warp, curl, or detach during the printing process, resulting in a failed print. This can be frustrating and wasteful, especially if you are printing large or complex models.

So what is the best way to get a 3D print to stick to the bed properly? There is no definitive answer to this question, as different printers, filaments, and settings may require different solutions. However, there are some general tips and tricks that can help you improve your bed adhesion and avoid common issues.

The first thing you need to do is make sure your bed is level and clean. A level bed ensures that the nozzle is at a consistent distance from the bed across the entire print area, which affects how well the first layer sticks. You can use a sheet of paper or a feeler gauge to check the gap between the nozzle and the bed at different points and adjust it accordingly. A clean bed prevents dust, oil, or other contaminants from interfering with the adhesion. You can use a cloth with some alcohol or acetone to wipe the bed before each print.

The second thing you need to do is choose the right bed temperature and surface for your filament type. Different filaments have different melting points and properties, which affect how they stick to different materials. For example, PLA usually sticks well to a heated glass bed at around 60°C, while ABS requires a higher temperature of around 100°C and may benefit from a layer of glue stick or hairspray on the bed. You can experiment with different temperatures and surfaces until you find the optimal combination for your filament.

The third thing you need to do is adjust your slicer settings to improve your first layer quality and adhesion. There are several settings that can affect this, such as layer height, line width, print speed, fan speed, and flow rate. Generally speaking, you want your first layer to be slightly thicker and wider than the rest of the layers, as this increases the contact area with the bed. You also want to print your first layer at a slower speed and lower fan speed, as this allows more time for the filament to melt and bond with the bed. You may also need to increase or decrease your flow rate depending on whether your first layer is over- or under-extruded.

When 3d printing, not every model is ready to be printed. Sometimes, the models have errors or defects that need to be fixed before printing. These errors are called non-manifold geometry, and they can cause serious problems if you try to print them.

Non-manifold geometry is when a model has edges or vertices that are shared by more than two faces, or when a model has holes or gaps in its surface. These errors make the model ambiguous and inconsistent, and they confuse the 3D printer. The printer does not know how to interpret the model or how to fill the space inside it.

If you try to print a model that has non-manifold geometry, you may end up with a failed print, a distorted print, or a print that does not match the original model. For example, you may get unwanted holes, gaps, spikes, or blobs in your print. You may also waste time and material on printing something that does not work or look good.

To avoid these problems, you need to repair your model before printing. There are many software tools that can help you detect and fix non-manifold geometry. Some of them are free and some of them are paid. Some of them are online and some of them are offline. Some of them are easy and some of them are complex. You need to choose the tool that suits your needs and preferences.

The extruder is the part of your printer that pushes the filament through the nozzle and melts it to create the layers of your 3D print. If the extruder is not working properly, you may encounter problems such as under-extrusion, over-extrusion, clogging, stringing, or poor adhesion. Here are some steps you can take to diagnose if your printer has an issue with the extruder:

  1. Check the temperature of the extruder. The temperature should match the recommended range for the type of filament you are using. If the temperature is too low, the filament may not melt enough and cause under-extrusion or clogging. If the temperature is too high, the filament may ooze out of the nozzle and cause over-extrusion or stringing. You can adjust the temperature using the printer’s settings or a slicer software.
  2. Check the tension of the extruder. The tension is the force that the extruder applies to the filament to push it through the nozzle. If the tension is too loose, the extruder may not grip the filament well and cause under-extrusion or skipping. If the tension is too tight, the extruder may deform or grind the filament and cause over-extrusion or clogging. You can adjust the tension by tightening or loosening the screws on the extruder.
  3. Check the alignment of the extruder. The alignment is the position of the extruder relative to the nozzle and the print bed. If the alignment is off, the extruder may not deposit the filament evenly and cause poor adhesion or warping. You can check the alignment by printing a test pattern and measuring the distance between the nozzle and the print bed at different points. You can adjust the alignment by leveling the print bed or adjusting the height of the nozzle.
  4. Check for any debris or damage in the extruder. The debris or damage may be caused by dust, dirt, filament residue, or wear and tear. If there is any debris or damage in the extruder, it may obstruct or interfere with the flow of filament and cause clogging, jamming, or inconsistent extrusion. You can check for any debris or damage by inspecting the extruder visually or using a needle or a wire to poke through the nozzle. You can clean or replace any parts that are dirty or damaged.

If you have ever experienced a partial clog on your 3D printer, you know how frustrating it can be. A partial clog is when the filament does not flow smoothly through the nozzle, resulting in under-extrusion, poor print quality, and sometimes even nozzle jams. We will explain what causes a partial clog, how to identify it, and how to fix it.

What causes a partial clog?

A partial clog can be caused by various factors, such as:

  • Using low-quality or incompatible filament that contains impurities, moisture, or inconsistent diameter.
  • Printing at a wrong temperature that is too high or too low for the filament type.
  • Printing at a wrong speed that is too fast or too slow for the nozzle size and layer height.
  • Leaving the nozzle heated for too long without extruding any filament, causing heat creep and filament degradation.
  • Not cleaning the nozzle regularly or properly, allowing dust, debris, or burnt filament to accumulate inside.

How to identify a partial clog?

A partial clog can manifest itself in different ways, depending on the severity and location of the blockage. Some common signs of a partial clog are:

  • The extruder motor skipping steps or making clicking noises.
  • The filament curling or bending at the nozzle tip instead of coming out straight.
  • The filament coming out thinner or thicker than usual, or with gaps or blobs.
  • The print surface showing signs of under-extrusion, such as missing layers, holes, or roughness.
  • The print quality deteriorating over time, especially on long prints.

How to fix a partial clog?

The best way to fix a partial clog is to prevent it from happening in the first place by using high-quality and compatible filament, printing at the optimal settings for your printer and material, and cleaning the nozzle regularly and properly. However, if you already have a partial clog, here are some steps you can try to clear it:

  • Increase the nozzle temperature by 5-10°C and try to extrude some filament manually. This may help to melt any hardened or stuck filament inside the nozzle.
  • Use a needle or a wire to poke through the nozzle hole and dislodge any debris or burnt filament. Be careful not to damage the nozzle or the heating element.
  • Perform a cold pull or an atomic pull. This is a technique where you heat up the nozzle, insert a piece of filament, let it cool down slightly, and then pull it out quickly with a pair of pliers. This may help to pull out any residue or impurities from the nozzle along with the filament.
  • Replace the nozzle with a new one. This is the last resort if none of the above methods work. Make sure to use a nozzle that matches your printer model and filament type.

One of the most common problems that 3D printing enthusiasts face is when the layers of their prints do not stick together properly. This can result in weak or brittle prints, or even complete failures. In this blog post, I will explain some of the possible causes of this issue and how to fix them.

The first thing to check is the bed leveling. If the bed is not level, the nozzle will not be at the right distance from the surface, and the extruded filament will not adhere well. To level the bed, you can use a piece of paper and slide it under the nozzle while adjusting the screws on the corners of the bed. The paper should feel slightly tight between the nozzle and the bed.

The second thing to check is the bed temperature. If the bed is too cold, the filament will cool down too quickly and shrink, causing it to detach from the bed. If the bed is too hot, the filament will stay soft and deform, causing it to curl up. The optimal bed temperature depends on the type of filament you are using, but a general range is between 50°C and 70°C for PLA and between 80°C and 110°C for ABS.

The third thing to check is the nozzle temperature. If the nozzle is too cold, the filament will not melt properly and will not bond well with the previous layer. If the nozzle is too hot, the filament will ooze out of the nozzle and create blobs or strings on your print. The optimal nozzle temperature also depends on the type of filament you are using, but a general range is between 180°C and 220°C for PLA and between 230°C and 260°C for ABS.

The fourth thing to check is the print speed. If you print too fast, the filament will not have enough time to adhere to the previous layer before moving on to the next one. If you print too slow, the filament will stay in contact with the hot nozzle for too long and degrade or burn. The optimal print speed depends on many factors, such as the size and complexity of your model, but a general range is between 30 mm/s and 60 mm/s.

The fifth thing to check is the fan speed. The fan helps to cool down the filament after it leaves the nozzle and prevent warping or sagging. However, if the fan is too strong, it can also cool down the previous layer too much and prevent it from bonding with the next one. The optimal fan speed depends on the type of filament you are using, but a general rule is to use a low fan speed for ABS (around 10%) and a high fan speed for PLA (around 80%).

These are some of the most common causes of layer adhesion problems in 3D printing. By following these tips, you should be able to improve your prints and avoid frustration. Happy printing!