Screen printing — also written as screenprinting — is one of the oldest and most durable printing methods still in active use today. From custom t-shirts to fine art prints, from industrial electronics to promotional merchandise, the process remains remarkably versatile. Yet despite its apparent simplicity, achieving consistently excellent results requires a solid understanding of the physics behind ink transfer, mesh behavior, and substrate interaction.
This guide covers everything you need to know: the complete screenprinting process step by step, essential equipment, ink types, mesh selection, and a detailed breakdown of the most common mistakes that cause failed prints — and exactly how to fix them.
What Is Screen Printing?
Screen printing (screenprinting) is a stencil-based printing technique in which ink is forced through a mesh screen onto a substrate — most commonly a t-shirt, paper, or other flat material. A photo-reactive emulsion blocks areas where ink should not pass; the remaining open mesh areas allow ink to transfer.
The core principle has not changed in centuries: a screen, a stencil, ink, and a squeegee. What has changed is the precision with which each variable can be controlled, and the range of inks and substrates available.
The Screen Printing Process: Step by Step
1. Artwork Preparation and Film Output
Everything starts with a clean, high-contrast piece of artwork. For single-color prints, you need one piece of film (a transparency). For multi-color work, each color requires a separate film — each one a grayscale representation of that color channel.
Key rules for artwork:
- Work in vector format where possible (Adobe Illustrator, CorelDraw)
- For photographic images, rasterize at a minimum of 300 DPI at final print size
- Output films at 1200–2400 DPI for crisp edges
- Blacks must be solid — any gray will result in partial exposure
2. Screen Preparation: Mesh and Tension
The screen is a wooden or aluminum frame stretched with a fine mesh fabric — historically silk, now predominantly polyester. Mesh count is expressed as threads per inch (TPI) or threads per centimeter (T/cm).
Mesh count selection is critical and depends on the type of print:
| Mesh Count | Use Case |
|---|---|
| 25–40 TPI | Glitter, metallic inks, thick pastes |
| 55–86 TPI | Underbase white, heavy coverage |
| 110–160 TPI | General t-shirt printing, spot colors |
| 180–230 TPI | Halftones, detailed artwork, fine lines |
| 260–355 TPI | Fine detail, fine halftone, thin inks |
Screen tension directly affects print quality. A properly tensioned screen (typically 20–25 N/cm² for retensionable frames) ensures consistent ink deposit and clean snap-off. Low tension is one of the most overlooked causes of poor registration and ink bleed.
3. Coating with Photopolymer Emulsion
Emulsion is the photosensitive material that creates your stencil. It is applied to the mesh in a darkroom environment using an emulsion scoop coater — a metal trough with a rounded edge that spreads a uniform layer onto the mesh.
Standard application technique: one wet coat on the squeegee side (inside the screen), one coat on the print side (outside), then dry horizontally, print side down, at room temperature or with gentle heat (max 40°C / 104°F). A second coat on the print side — called the emulsion over mesh (EOM) — builds up a thicker ink dam, which is important for halftone work and fine detail.
Emulsion thickness matters. Thin emulsion = ink bleeds under stencil edges. Thick emulsion = longer exposure required, potential pinholes if underexposed.
4. Exposure
Once dry, the emulsion is exposed to UV light (typically a UV lamp or metal halide exposure unit) through the film positive. UV light polymerizes (hardens) the emulsion in the open areas of the film. The black areas of the film block UV, leaving those emulsion areas soluble.
Exposure time is the single most critical variable in screen making. It depends on:
- Emulsion type (diazo, SBQ, dual-cure)
- Emulsion thickness
- UV lamp output (in mW/cm²)
- Distance between lamp and screen
- Mesh color (white mesh reflects UV; orange/yellow mesh absorbs it, improving halftone resolution)
The step wedge/exposure calculator is the professional method to dial in correct exposure. Never guess — an underexposed stencil will wash out during printing; an overexposed one will block fine detail and halftone dots.
5. Washout
After exposure, the screen is washed with a gentle pressure water spray. The unexposed (black areas of film) emulsion dissolves, opening the mesh. The exposed areas remain hard and form the stencil.
Proper washout technique: rinse both sides gently, working from the print side. Never blast high-pressure water directly on the emulsion — it will undercut edges and destroy fine detail.
6. Press Setup: Off-Contact Distance
Off-contact distance is the gap between the bottom of the screen mesh and the top of the substrate. This is one of the most important and least discussed variables in screenprinting.
The correct off-contact creates a “snap-off” — as the squeegee moves forward, the screen springs away from the substrate immediately behind the blade, depositing ink cleanly without smearing. A typical off-contact is 3–6 mm (⅛”–¼”) for textiles, less for paper or rigid substrates.
Zero off-contact (screen resting on substrate) causes:
- Ink smear
- Blurry edges
- Ink buildup on substrate
- Screen sticking to garment
7. Printing: Flood Stroke and Print Stroke
Every screenprinting cycle has two strokes:
Flood stroke: The squeegee (or a separate flood bar) moves across the screen with the blade raised slightly, pushing ink across the mesh to fill the open areas without pressing through to the substrate. This keeps the mesh wet between prints and ensures consistent ink availability.
Print stroke: The squeegee presses down with controlled pressure and angle, moving in the opposite direction, forcing ink through the open mesh onto the substrate.
Squeegee variables that affect print quality:
- Durometer (hardness): 60–65A for heavy ink deposits, 70–75A for general printing, 80–85A for halftones and fine detail
- Angle: typically 75°–80° from horizontal; steeper angle = less ink deposit
- Speed: faster = thinner deposit; slower = thicker deposit
- Pressure: minimum necessary to transfer ink cleanly
8. Curing
Plastisol inks (the most common for t-shirt printing) require heat curing — typically 160°C (320°F) for 30–90 seconds in a conveyor dryer or flash cure unit. Undercured ink will wash out. Overcured ink will crack.
Water-based inks require both heat and airflow to evaporate the water carrier.
Types of Screen Printing Ink
| Ink Type | Properties | Best For |
|---|---|---|
| Plastisol | Oil-based PVC, no drying on screen, requires heat cure | Most t-shirt printing |
| Water-based | Eco-friendly, softer hand, needs airflow to cure | Fashion, soft-hand prints |
| Discharge | Removes dye from garment, replaces with pigment | Soft vintage look on dark shirts |
| High-density | Very thick, builds up raised 3D effect | Specialty graphic printing |
| Metallic / Shimmer | Contains metallic particles, low mesh required | Decorative work |
| Puff | Expands when heated | Raised texture effects |
Troubleshooting: Common Screen Printing Problems
Problem 1: Ink Bleeding / Fuzzy Edges
Symptoms: Clean stencil edges but blurry print edges, ink spreading beyond design boundaries.
Causes and fixes:
- Too much off-contact: Reduce off-contact distance by 1–2 mm increments
- Screen tension too low: Re-tension screen or replace with a pre-tensioned mesh
- Squeegee pressure too high: Reduce pressure — the squeegee should glide, not dig
- Ink too thin: Add viscosity modifier or curable reducer only as needed
- Emulsion underexposed: Expose longer; check with step wedge
Problem 2: Pinholes in Emulsion
Symptoms: Small random holes in solid stencil areas allowing ink through.
Causes and fixes:
- Dust on film during exposure: Clean film and exposure glass before every exposure
- Emulsion coat too thin: Apply a second coat to build EOM
- Air bubbles in emulsion: Degas emulsion after mixing diazo; apply coater slowly
- Old or contaminated emulsion: Check shelf life; store emulsion in sealed container in cool dark location
Problem 3: Poor Ink Coverage / Show-Through
Symptoms: Substrate texture visible through ink, uneven coverage.
Causes and fixes:
- Mesh count too high: Switch to a coarser mesh for heavier coverage
- Ink viscosity too low: Use ink without excessive thinning
- Single stroke not enough: Consider printing with an underbase white first (wet-on-wet or with flash)
- Squeegee too hard: Use a softer squeegee (60A) for thick coverage
Problem 4: Ink Not Curing / Washing Out After Curing
Symptoms: Ink peels, cracks, or fades after first wash.
Causes and fixes:
- Temperature too low: Check conveyor belt temperature with a donut probe or temp strips — not just the air temperature inside the dryer
- Belt speed too fast: Slow down; plastisol needs time at temperature, not just exposure to heat
- Ink migration on polyester: Use low-bleed inks or blocking underbase on synthetic fabrics
Problem 5: Ghosting / Haze After Reclaiming
Symptoms: Ghost image visible in mesh after stripping emulsion.
Causes and fixes:
- Ink not fully cleaned before stripping: Always degrease and remove all ink before applying emulsion remover
- Ink dried in mesh (water-based): Use enzyme-based haze remover after reclaiming
- Stencil left on screen too long: Reclaim promptly after use; old stencils are harder to remove
Common Mistakes in Screen Printing (and How to Avoid Them)
1. Skipping the exposure test. Every new emulsion batch, every new lamp, every change in mesh count requires a fresh exposure test. Experienced printers use a step wedge as standard practice — not a luxury.
2. Ignoring screen tension. Low-tension screens are the silent killer of print quality. Invest in a tension meter and check screens regularly. Replace mesh when tension falls below 15 N/cm².
3. Printing at zero off-contact. This seems like it would give better ink contact, but the opposite is true. Off-contact is essential for clean snap-off and sharp edge definition.
4. Not running a flood stroke between prints. Skipping the flood stroke allows mesh to dry, causing ink to clog open cells — especially critical with water-based inks and fine halftone screens.
5. Curing by touch or visual inspection only. Ink can feel dry on the surface while the lower layers remain undercured. Always use a wash test: wash a test print with hot water and detergent after curing to verify durability.
6. Mixing incompatible inks. Mixing plastisol brands is generally safe, but mixing plastisol with water-based or discharge inks can cause curing failure and unpredictable color shifts.
7. Using the same mesh for everything. A 160 TPI screen that works beautifully for halftones will give poor coverage for an athletic block print that needs a 110 TPI. Match mesh to the job.
Summary: Screen Printing Process Checklist
- Artwork at correct DPI and format
- Film output at 1200+ DPI
- Correct mesh count for the job
- Screen tension checked (>20 N/cm²)
- Emulsion applied with correct EOM
- Exposure tested with step wedge
- Off-contact set to 3–6 mm
- Ink at correct viscosity
- Squeegee durometer matched to job
- Cure temperature verified with probe
Screen printing rewards precision. Master the fundamentals — tension, exposure, off-contact, curing — and you will solve 90% of all print quality problems before they happen.
Dragonfly Colors provides professional color separations and screen printing prepress services. Contact us to discuss your next project.