3.1 Heat Transfer & Zone Control

Heat in a reflow oven is both the sculptor and the saboteur of solder joints. Controlled correctly, it melts alloys evenly, activates fluxes, and locks components in place with clean, reliable joints. Left unchecked, the same forces warp boards, split BGAs, and leave weak, inconsistent connections. By breaking down conduction, convection, and radiation into manageable levers—zone temperature, blower speed, and belt timing—the process shifts from a black box into a repeatable recipe. What emerges is not just soldering, but thermal choreography that makes high-yield manufacturing possible.

3.1.1 The physics in one page (no stress)

Conduction: heat flowing through contact—board on conveyor fingers/rails, parts into pads. Good conduction evens out temperatures but can also steal heat from the center of a thin panel.
Convection: hot air/N₂ blown across the board. This is the main act in modern ovens; blower speed sets how hard the air scrubs heat into every corner.
Radiation: IR from heaters. It’s always there, but on convection ovens it’s the supporting cast, smoothing things out.

Think of your oven like weather: setpoints are the climate (how hot the zones are), blowers are the wind (how fast heat moves), and belt speed is time (how long the board stays in each climate).

3.1.2 The four reflow segments (and the knobs that matter)

Typical lead-free SAC guidance—always check your paste datasheet.

Segment	What you want	“Typical” targets	Which knob moves it most
Preheat (ramp)	Gently warm everything	~0.7–2.0 °C/s to ~150–170 °C	Belt speed first, then early zone temps
Soak	Even out temps, activate flux	~60–120 s around 150–180 °C	Zone temps in middle zones, blower balance
Reflow/TAL	Fully melt, wet, collapse	Time Above Liquidus (217 °C for SAC): ~40–80 s; Peak ~235–250 °C	Peak zone temps and belt speed
Cool	Solidify without stress	~2–4 °C/s down through 180→100 °C	Cooler/blower settings, exit fans

Two guardrails:

Keep ΔT across the board tight (aim <10–12 °C at peak for most builds).
Don’t break datasheet ramp/TAL limits (especially for large BGAs and plastic connectors).

3.1.3 Zone control—what each dial is really for

Zone setpoint (temperature): raises/lowers the ceiling in that segment. Use it to hit peak and shape soak.
Blower/fan speed: boosts convection (heat transfer coefficient). Use it to reduce ΔT across big/heavy boards or dense areas. Too high can kick parts or dry flux early—nudge, don’t slam.
Top vs bottom balance: top a little hotter for heavy top-side copper or tall parts; bottom up a touch when large ground planes live underneath.
Belt speed: your time knob. Faster belt → shorter soak/TAL; slower belt → more time everywhere.

Rule of thumb:

Missed peak / short TAL? Slow the belt a bit or lift late-zone temps.
Overheating / long TAL? Speed the belt or drop late-zone temps.
Hot edges, cold center? Increase blower and give a calmer, longer soak.

3.1.4 A simple tuning playbook (start here)

Load the vendor’s starter recipe for your alloy.
Run a profile board with 4–6 thermocouples (see 9.1.5).
Use belt speed to get TAL in range.
Use late-zone temps to nail peak.
Use blower speed and mid-zone temps to tighten ΔT (edges vs center, light vs heavy components).
Lock it, label it, and rerun once the oven is heat-soaked (after a few boards).

3.1.5 Thermocouples that tell the truth

Where you stick TCs matters more than how many you use.

Attach well: high-temp epoxy or small solder dots; Kapton tape only as a helper.
Pick smart spots:
- “Cold spot” (usually a shadowed BGA center or large copper area)
- “Hot spot” (small passive cluster near open copper)
- Heavy thermal pad (QFN/LFPAK slug)
- Edge rail vs board center (to see ΔT)
- Connector / plastic risk (watch peak)
Do both sides on double-sided builds—second pass often needs a softer recipe to protect the first side’s joints and plastics.

3.1.6 Air vs nitrogen (what changes)

Nitrogen (low O₂) improves wetting/cosmetics, often trims voiding on big thermal pads, and can help marginal pastes at lower peaks. Heat transfer is similar enough that your zone temps won’t jump wildly—but you may be able to lower peak a few degrees or shorten TAL while keeping quality.
Air is cheaper and fine for most assemblies if printing and profiles are solid. Save N₂ for dense BGAs/QFNs, tight cosmetics, or finicky flux.

3.1.7 Common symptoms → fastest fixes

Symptom	First move	If still there…
Hot edges, cool center	Raise blower, lengthen soak	Add center supports in oven; lower early-zone setpoints to reduce edge preheat
BGA HIP (head-in-pillow)	Slightly longer TAL and steadier soak	Consider N₂; verify paste and VIPPO fill; check warpage support
QFN voiding	Longer, gentler soak; try small peak reduction	Switch paste or add N₂; revisit stencil windowing (7.4)
Skew/tombstones	Smooth ramp (≤2 °C/s), tighten ΔT	Revisit aperture balance (7.4), paste health (7.2)
Solder balls/splatter	Shorten soak, reduce peak a touch	Paste age/handling; understencil cleaning cadence (7.5)
Dull joints/cosmetics	Raise peak a little or add N₂	Check flux family (7.1), finish (2.4)

3.1.8 Don’t fight warp with heat

Warp/bow makes TCs lie and parts skate. Fix mechanically first: edge rails, center fingers, and board supports in printer and PnP. Then profile. Using heat to “bend a board flat” usually backfires.

3.1.9 Keep the oven happy (little things that pay)

Warm-up & soak: give the oven a few boards to reach steady state before final profiling.
Exhaust & filters: clogged filters change convection—clean them on schedule.
Recipe names: encode alloy, side, panel mass, N₂/air in the name (e.g., “SAC_Top_4upHeavy_Air_v3”).
One change at a time when tuning; note what you touched and why in the recipe comments.

3.1.10 Release checklist (tape this to the oven PC)

Profile board run with 4–6 TCs (hot/cold spots covered)
Ramp, soak, TAL, peak within paste datasheet limits
ΔT at peak within target (≤10–12 °C typical)
Top/bottom balance set; blower tuned for evenness
Recipe saved (clear name + comments); Golden plot attached
Air/N₂ choice documented; second-side recipe (if needed) created

A disciplined approach to profiling—balancing thermal physics with paste limits, smart thermocouple placement, and clear recipe management—turns reflow ovens into consistent production tools. Done well, it prevents defects, preserves components, and ensures that every board leaving the line meets both electrical and cosmetic expectations.