(Where Geometry Becomes Controlled Deformation)
In Part 1, the profile was defined.
In Part 2, the profile must be engineered.
A profile drawing is static geometry.
A roll forming machine must turn flat strip into that geometry through:
Progressive bending
Controlled strain distribution
Elastic springback compensation
Tension control
Torque transmission
Tooling contact management
Roll forming is not “just bending metal.”
It is controlled elastic-plastic deformation across multiple stations under dynamic load.
If pass design is wrong:
Ribs distort
Edges wave
Oil canning increases
Shafts deflect
Tooling cracks
Width drifts
Bearings overload
This stage determines whether the machine will be stable for 20 years — or problematic from day one.
Before stands are assigned, engineers analyze:
Number of bends
Bend angles
Rib depths
Sharp corners
Hem closures
Material strength
Thickness range
The goal is to answer:
How much strain must be introduced into the strip — and how quickly?
When metal bends:
Outer fibers → tension
Inner fibers → compression
Neutral axis → shifts inward
Approximate outer fiber strain:
ε=t2R\varepsilon = \frac{t}{2R}ε=2Rt
Where:
t = material thickness
R = inside bend radius
Example:
t = 0.75 mm
R = 1.0 mm
ε=0.752(1.0)=0.375\varepsilon = \frac{0.75}{2(1.0)} = 0.375ε=2(1.0)0.75=0.375
That equals 37.5% strain — which exceeds typical elongation limits.
This tells engineers:
The bend radius must increase or strain must be distributed over more passes.
This is why pass count exists.
The flower pattern is the progressive shape development across stations.
It determines:
When each bend begins
How much angle per pass
Where stress accumulates
Whether edges stretch or compress
For a 90° bend:
Bad strategy:
0° → 90° in 2 stations
Good strategy:
0° → 20° → 45° → 70° → 90°
Progressive deformation reduces peak strain.
Deep ribs introduce:
Sidewall buckling risk
Edge stretch
Twisting moments
Increased torque requirement
Engineers often:
Pre-form rib bases early
Gradually lift rib walls
Close angles late
This controls distortion.
Stand count is not guesswork.
It depends on:
Total bend degrees
Material strength
Thickness
Rib height
Profile symmetry
Speed requirement
For light gauge roofing:
15–22 stations typical
For structural deck:
22–30+ stations
Higher yield material requires more stands.
Total bending work increases with:
Work∝σy×t×total bend lengthWork \propto \sigma_y \times t \times \text{total bend length}Work∝σy×t×total bend length
Where:
σy\sigma_yσy = yield strength
t = thickness
Doubling yield strength approximately doubles required forming force.
Increasing thickness increases bending moment exponentially.
This often requires more stations to distribute strain.
This is where engineering becomes mathematical.
For elastic-plastic bending:
M=σyt24M = \frac{\sigma_y t^2}{4}M=4σyt2
Where:
M = bending moment per unit width
σy\sigma_yσy = yield strength
t = thickness
Example:
σy=350\sigma_y = 350σy=350 MPa
t = 1.0 mm
M=350×124=87.5 N\cdotpmm per mm widthM = \frac{350 \times 1^2}{4} = 87.5 \text{ N·mm per mm width}M=4350×12=87.5 N\cdotpmm per mm width
If profile width = 1000 mm:
Total bending moment:
87.5×1000=87,500 N\cdotpmm87.5 \times 1000 = 87,500 \text{ N·mm}87.5×1000=87,500 N\cdotpmm
This is only for one bend zone.
Multiply across bends and stations to estimate total torque demand.
Torque:
T=F×rT = F \times rT=F×r
Where:
F = forming force
r = roll radius
If forming force at one station ≈ 15 kN
Roll radius = 50 mm
T=15,000×0.05=750 N\cdotpmT = 15,000 \times 0.05 = 750 \text{ N·m}T=15,000×0.05=750 N\cdotpm
Multiply by number of active bends in contact.
This determines gearbox size.
Shaft deflection causes:
Uneven rib height
Side wave
Tooling wear
Bearing overload
For simply supported shaft:
δ=FL348EI\delta = \frac{F L^3}{48 E I}δ=48EIFL3
Where:
F = load
L = span
E = modulus of elasticity
I = moment of inertia
For solid shaft:
I=πd464I = \frac{\pi d^4}{64}I=64πd4
Notice deflection is proportional to:
1d4\frac{1}{d^4}d41
Small diameter reduction dramatically increases deflection.
Example:
50 mm shaft vs 60 mm shaft:
(6050)4≈2.07\left(\frac{60}{50}\right)^4 ≈ 2.07(5060)4≈2.07
A 60 mm shaft is more than twice as stiff as 50 mm.
This is why heavy gauge lines require larger shafts.
After leaving the rolls, material elastically recovers.
Springback angle:
θs∝σyE×tR\theta_s \propto \frac{\sigma_y}{E} \times \frac{t}{R}θs∝Eσy×Rt
Higher yield → more springback
Thinner radius → more springback
Engineers compensate by:
Over-bending in final stations
Adjusting flower angles
Modifying final calibration rolls
Failure to compensate results in:
Undersized rib height
Incorrect cover width
As ribs form:
Outer edges stretch
Inner zones compress
Uneven strain leads to:
Edge wave
Camber
Oil canning
Engineers control this through:
Progressive forming
Proper roll contour
Controlled strip tension
Roll forming must distribute load evenly.
If load concentrates in early stations:
Tool wear accelerates
Gear teeth wear unevenly
Vibration increases
Proper pass design balances load across stations.
At higher speed:
Dynamic forces increase
Material inertia increases
Vibration risk increases
High-speed lines require:
Smoother flower transitions
Larger shaft diameters
Stronger frames
Better bearing selection
Pass design changes with speed.
Last 2–4 stations are critical.
Their purpose:
Correct dimensional drift
Remove minor distortion
Set final rib height
Control cover width
These stations carry less bending load — more precision shaping.
Modern manufacturers use:
CAD-based flower modeling
Finite element analysis
Stress mapping
Interference detection
This reduces physical trial and error.
Too few stations
Aggressive early bending
Ignoring springback
Undersized shafts
Inadequate torque calculation
Overestimating speed capability
All lead to production instability.
Pass design is where roll forming becomes engineering.
It determines:
Tool life
Machine lifespan
Dimensional accuracy
Surface quality
Power consumption
Warranty risk
A profile drawing is theoretical.
Pass design converts it into controlled mechanical reality.
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