Web Guiding

Mechanical Master/Slave (legacy): The Master sensor is mounted on a motorized slide that physically chases the web position. The Slave sensor is mechanically linked to move the same distance. This creates wear parts, lag, and "loop within a loop" tuning problems.

Electronic Master/Slave (Roll-2-Roll Technologies): Both sensors connect to a single controller. The controller reads the Master position and electronically adjusts the Slave guide point in real-time—no physical sensor movement. This eliminates mechanical lag, wear parts, and tuning instability.

The electronic approach also enables capabilities impossible with mechanical systems, such as centerline matching between webs of different widths.

No. Roll-2-Roll® Sensors are available in apertures from 48mm to 960mm, allowing a single sensor to accommodate a wide range of web widths without repositioning.

For example, an ODC 288 sensor can detect edges anywhere within its 288mm (11.3 in) sensing range. Whether you're running a 100mm web or a 250mm web, the sensor detects the edge without adjustment.

This eliminates:

• Changeover time: No 2–5 minute delays for sensor repositioning between SKUs
• Operator error: No risk of incorrect sensor positioning
• Motorized positioners: No additional hardware cost or maintenance

Combined with material-agnostic detection (no recalibration between clear films, opaque substrates, or metallic foils), Roll-2-Roll® Sensors enable true "set and forget" operation.

Telescoped (uneven) roll edges typically result from:

• Response lag: Hydraulic systems have inherent lag from valve response and fluid compressibility. By the time the guide reacts, the web has already wandered.
• Valve balancing issues: Unequal extension/retraction speeds cause inconsistent correction.
• Improper sensor mounting: If the sensor is fixed to the floor instead of the moving stand, or if the mounting arm is flexible, the system receives incorrect position feedback.

The Roll-2-Roll Technologies solution:

• Zero-backlash actuators: Electromechanical actuators respond immediately without the "spongy" feel of hydraulics
• Stiff control loop: Fast response prevents lag-induced wander, especially on outer roll layers
• Proper mounting guidance: Sensor on the moving stand, observing web at a fixed upstream idler, with structurally rigid mounting

The result is perfectly straight-sided rolls without the "drift" that causes telescoping during shipping and handling.

Yes. The SCU5 and SCU6x controllers can process two sensors simultaneously with independent enable/disable control. This is ideal for bidirectional coating machines that run forward and backward between passes.

Typical dual-sensor configuration:

• Sensor 1: Mounted on the rewind moving frame—enabled during forward winding
• Sensor 2: Mounted on the fixed machine frame—enabled during reverse (unwind) direction

Instead of repositioning a single sensor when direction changes, operators simply switch which sensor is active via the controller touchscreen or a PLC command over EtherNet/IP, PROFINET, or EtherCAT.

This eliminates sensor repositioning time, enables instant direction changes, and simplifies machine design by removing the need for motorized sensor positioners.

Roll-2-Roll Technologies rewind guides use electromechanical actuators (RLA and BLA series) instead of traditional hydraulic cylinders. This completely eliminates:

• Hydraulic fluid—no oil to leak, change, or dispose of
• Filters and seals—no consumables to replace quarterly
• Valve balancing issues—no unequal extension/retraction speeds
• Contamination risk—critical for food, pharmaceutical, and medical applications
• Hydraulic pumps—quieter operation without pump noise

Typical plants using hydraulic systems report spending 10–20 hours annually on rewind guide maintenance alone. Electromechanical systems reduce this to near-zero, with only periodic inspection required.

The SCU6x controller includes an integrated motor driver, eliminating the need for separate drive cabinets and simplifying installation.

Roll-2-Roll Technologies electromechanical rewind guides can handle loads up to 30,000 lbs (13,600 kg) when paired with low-friction linear rail bearings (coefficient ~0.01).

Key specifications:

• Maximum thrust: 50–1,500 lbf (222–6,670 N)
• Stroke length: 1–12 in (25–300 mm)
• Maximum speed: Up to 2 in/sec (51 mm/sec)

The critical factor for sizing is breakaway force—the static friction the actuator must overcome to start moving the loaded stand. Using low-friction linear rail bearings dramatically reduces the required actuator size compared to sliding shaft designs (coefficient ~0.25).

For extremely heavy loads, the RLA Series ball screw actuators provide thrust up to 1,500 lbf while maintaining precision positioning.

In rewind chasing applications, the sensor must be mechanically attached to the shifting stand because the control system is designed to keep the sensor output at "zero." When the sensor moves with the roll, the system naturally drives the stand until the sensor aligns with the web edge.

If the sensor were fixed to the floor (like in intermediate guiding), the system would lose the relative position between the web and the roll face. The result would be telescoped or uneven rolls because the guide has no reference point for where the roll edge should be.

The sensor should observe the web at a fixed idler immediately upstream of the shifting stand. This provides a stable reference point while the stand—and sensor—move together.

The choice between edge guiding and line guiding depends on what defines "correct position" for your process:

Use Edge Guiding When:

• The physical web edge is your reference (e.g., die-cutting to edge, edge-aligned lamination)
• Material has consistent, clean edges
• Processing unprinted or solid-color materials

Use Line Guiding When:

• Processing pre-printed materials where print registration matters more than edge position
• Web edges are inconsistent (ragged, variable width) but printed marks are reliable
• Guiding to a coating edge rather than the substrate edge
• Running materials with printed registration marks or tracking lines

The Roll-2-Roll Technologies Advantage: With ODC 960 wide-aperture sensors, you can switch between edge and line guiding modes without changing hardware. This is particularly valuable for slitter rewinder applications that process both plain substrates (edge guide) and pre-printed materials (line guide) on the same machine.

The sensor automatically adapts to detect either the physical edge or a contrast line based on your selection in the SCU5 or SCU6x controller interface.

Roll-2-Roll Technologies actuators are specifically designed for hydraulic cylinder replacement in unwind and rewind guiding applications:

What You Eliminate:

• Hydraulic fluid and the risk of product contamination from leaks
• Filter changes and fluid maintenance (typically 2-4 times per year)
• Seal replacement and valve rebalancing
• Hydraulic power unit (HPU) maintenance and energy costs

What You Gain:

• Clean, dry operation—critical for food, pharmaceutical, and medical applications
• Full thrust at zero speed (hydraulics struggle with static positioning)
• Smooth response at variable speeds without the "stick-slip" behavior of hydraulics
• Digital communication via EtherNet/IP, PROFINET, or EtherCAT for integration with modern PLCs

Retrofit Options:

• RLA Series: Rotary stepper with belt/pulley and ball screw, thrust up to 2,000 lbf
• BLA Series: Inline stepper with external ball screw for terminal guide applications

Most hydraulic retrofits can be completed in a scheduled maintenance window without major mechanical modifications to the existing stand structure.

The "fixed sensor rule" is fundamental to unwind guiding physics and is the opposite of rewind chasing:

The Logic: In unwind guiding, you are positioning the web to enter the machine at a specific target location. The sensor acts as that target. The controller moves the shifting stand until the web edge aligns with the fixed sensor position.

The Common Mistake: If you mount the sensor on the moving stand (as you would in a rewind chasing application), the sensor moves with the error. When the stand shifts left, the sensor shifts left too—so from the sensor's perspective, nothing has changed. The system cannot detect or correct the misalignment relative to the machine frame.

Proper Configuration:

• Sensor: Fixed to the machine frame (floor or fixed structure)
• At least one idler roller: Mounted on the shifting stand (moves with it)
• Sensor position: Immediately downstream of the shifting idler

This configuration ensures the sensor sees true web position relative to the machine, while the shifting idler maintains a consistent web plane as roll diameter changes.