Stay Plugged In With Canon
Latest News & Updates

Print reliability begins with understanding how the first layer behaves. Brims extend only a thin perimeter outward, increasing surface area without altering part geometry, which stabilizes edges and minimizes warping on tall or flexible components. They are especially useful for materials prone to lift, such as ABS or nylons, and for parts with fine edges or small footprints that might otherwise peel away. A properly tuned brim should be visible but not intrusive, serving as a temporary anchor that is easy to remove after cooling. When used with slow, controlled retracing and a moderate nozzle temperature, brims become an efficient, low-impact solution for challenging starts and imperfect bed uniformity alike.

Rafts provide a different kind of foundation, creating a sacrificial layer beneath the entire print. They help when adhesion is inconsistent across a wide area or when vertical walls have trouble forming from a flat bed. Rafts distribute heat and stress more evenly, reducing localized warping on curved surfaces or parts with large contact footprints. However, rafts increase material use and post-processing time, so they’re best reserved for difficult materials like PETG with ooze tendencies or flexible polymers where corner lifting is common. From a workflow perspective, choose a raft when level bed calibration alone cannot guarantee stable first layers, and you’re seeing persistent detachment despite brim usage.

If you’re printing with glossy or fragile materials, a brim can act as a gentle anchor to prevent corner lifts during cooling contraction. Start with a modest brim width and gradually adjust based on observed edge behavior. Monitor how the temperature gradient along the first layer affects adhesion, and tweak bed heat or enclosure settings to maintain uniform cooling. It’s important to separate brim design from the main geometry so that the brim can be removed cleanly without compromising delicate features. Also consider a slight over-extrusion allowance on the brim to ensure a secure bond without creating excess filament that could mar the finish of the final part.

When you opt for a raft, select a lattice pattern that balances support with ease of removal. A fine, honeycomb-like raft provides adequate surface contact while reducing the effort needed to detach after printing. Adjust the raft’s thickness to match the material’s viscosity and the print’s expected mechanical stresses. For complex geometries or parts with undercuts, a raft can prevent filament from curling at inaccessible areas, preserving the integrity of features that would otherwise fail to form properly. Remember to prune the raft early in the post-processing sequence to minimize cleanup time and surface blemishes on the print’s bottom.

Adhesive aids extend beyond liquids—though glue sticks and specialty sprays remain common. For many printers, a light application of a water-soluble glue stick can dramatically improve bed adhesion on materials like PLA with tiny footprints or cool-bed plastics prone to warping. The trick lies in balancing a strong initial grip with easy removal after cooling. Apply a thin, even layer to the build plate and allow it to become tacky before laying down the print. This approach minimizes filament pull during separation and reduces the risk of tearing at the corners, especially for parts with sharp inner corners or narrow walls.

Alternative adhesive aids include polyimide tape, ABS slurry, and specialized adhesion sheets. Each option has its own compatibility profile with different materials and bed surfaces. Tape provides robust, repeatable adhesion for variable bed textures, while ABS slurry can help with high-temperature plastics during warm-up phases. Adhesive sheets offer consistent performance for large, flat areas, helping to prevent edge curling and corner lift. The key is to match the method to the material’s thermal behavior and to the environmental conditions in your workspace, ensuring consistent results from one print to the next.

For geometries with overhangs and steep walls, a brim can stabilize the initial layers while preventing poor layer bonding near the edges. When the brim is combined with a gentle airflow and a tuned extrusion multiplier, the first few layers form a reliable base. Avoid excessive brim thickness, which can complicate removal and leave marks on the finished surface. In some cases, enabling a minor raft assist for problematic corners further caps the risk of warping without dramatically increasing cleanup. These small refinements can save hours of failed prints, especially on large-scale projects with tight tolerances.

Advanced users often combine multiple strategies to address stubborn challenges. A small brim paired with a light raft under critical sections can deliver the best of both worlds: strong edge adhesion and robust internal feature formation. Use software presets to define bridging and cooling parameters that favor strong first layers. Fine-tuning bed temperature alongside nozzle temperature can reduce thermal stress during the early phase, improving sheet bonding and reducing the likelihood of warping as parts cool. Documentation of each trial helps with reproducibility, turning a single success into a reliable repeatable process.

Start with a thorough bed leveling check, then establish a baseline using a simple test print to observe how a brim behaves on your material. If you find consistent lift along a single edge, it could indicate an uneven bed section or a slight nozzle clog affecting extrusion width. In those cases, a brim can be a quick fix while you address the root cause, but ensure you don’t over-rely on it. Document temperatures, brim width, and any raft defaults for future reference, enabling you to reproduce or adjust settings quickly when similar materials or geometries appear again.

When you’re dealing with a series of challenging prints, consider developing a standard operating procedure that outlines which base strategy to deploy for each material and geometry class. A consistent approach reduces guesswork, saves material, and shortens print cycles. Include guidelines for brim thickness, raft presence, and adhesive selections across common plastics. Pair this with a simple bed-cleaning ritual before every print to maintain adhesion consistency. The result is a predictable workflow that minimizes failed starts and improves overall print quality across diverse runs.

Building confidence begins with small, controlled experiments. Start with PLA on a glass bed using a light glue stick and a narrow brim. Observe how far the filament adheres before feedback from the nozzle occurs, then adjust accordingly. If you notice warping on a corner, test a thin raft for that region to determine whether internal stress relief is beneficial. Record your observations and modify your settings in small increments. Over time, these micro-tests become a practical library that guides future decisions about brims, rafts, and adhesives.

Finally, adopt a mindset of continuous learning. Materials evolve, and so do printer designs and bed surfaces. Stay curious about emerging adhesive formulations, new raft patterns, and fresh brim geometries that claim to improve outcomes for stubborn parts. Pair periodic community tips with your own test prints to validate ideas before applying them broadly. By combining methodical testing with disciplined documentation, you’ll consistently push the boundaries of what’s possible with challenging geometries and tough materials.