Disclosed is an Off-Road Rolling Film Vision System comprising a Controller Module (200), a Takeup Module (300), and a Rollout Module (400). The Controller Module (200) comprises a Command Input (205), a Controller Process Module (210), a Command Transmitter (215), and a Power Supply (220). The Controller Module (200) is configured to remotely control a Motor (325) in the Takeup Module (300). The Command Input (205) comprises at least one Button configured to accept a knuckle bump for controlling a Motor (325) in the Takeup Module (300) when the Controller Module (200) is attached to a handlebar of an off-road vehicle. The at least one Button configured to accept a knuckle bump may be configured to be adjacent to a user's metacarpophalangeal index finger joint. The at least one Button configured to accept a knuckle bump may be configured to be adjacent to a user's metacarpophalangeal thumb joint. The Takeup Module (300) comprises a Motor Compartment (305), a Takeup Spool Compartment (310), a Takeup Spool Gear Compartment (315), a Takeup Film Window (320), a Motor (325), a Motor Gearbox (330), and at least one Takeup Spool Gear (340). The Takeup Module (300) may further comprise a Takeup Spool Window (350) configured to provide a view of a Takeup Spool (345) within the Takeup Module (300). Also disclosed is a Takeup Spool (500) comprising a Spool Alignment Tab Wheel (505), a Spool Ribbed Shaft (510), a Rib Quarter Section Cutout (515), a Spool Alignment Slot Wheel (525), a Spool Alignment Tab (530), a Spool Alignment Slot (535), a Plurality of Wheel Cutouts (540), and a Plurality of Wheel Slots (545). Also disclosed is a method for maintaining clear vision with goggles comprising receiving a command input via a knuckle bump, transmitting a designated signal to a module comprising a Motor and a Takeup Spool, activating the Motor to cause the Takeup Spool to rotate, and winding a Transparent Film a designated distance over goggles.

Disclosed is an Off-Road Rolling Film Vision System comprising a Controller Module (200), a Takeup Module (300), and a Rollout Module (400). The Controller Module (200) comprises a Command Input (205), a Controller Process Module (210), a Command Transmitter (215), and a Power Supply (220). The Controller Module (200) is configured to remotely control a Motor (325) in the Takeup Module (300). The Command Input (205) comprises at least one Button configured to accept a knuckle bump for controlling a Motor (325) in the Takeup Module (300) when the Controller Module (200) is attached to a handlebar of an off-road vehicle. The at least one Button configured to accept a knuckle bump may be configured to be adjacent to a user's metacarpophalangeal index finger joint. The at least one Button configured to accept a knuckle bump may be configured to be adjacent to a user's metacarpophalangeal thumb joint. The Takeup Module (300) comprises a Motor Compartment (305), a Takeup Spool Compartment (310), a Takeup Spool Gear Compartment (315), a Takeup Film Window (320), a Motor (325), a Motor Gearbox (330), and at least one Takeup Spool Gear (340). The Takeup Module (300) may further comprise a Takeup Spool Window (350) configured to provide a view of a Takeup Spool (345) within the Takeup Module (300). Also disclosed is a Takeup Spool (500) comprising a Spool Alignment Tab Wheel (505), a Spool Ribbed Shaft (510), a Rib Quarter Section Cutout (515), a Spool Alignment Slot Wheel (525), a Spool Alignment Tab (530), a Spool Alignment Slot (535), a Plurality of Wheel Cutouts (540), and a Plurality of Wheel Slots (545). Also disclosed is a method for maintaining clear vision with goggles comprising receiving a command input via a knuckle bump, transmitting a designated signal to a module comprising a Motor and a Takeup Spool, activating the Motor to cause the Takeup Spool to rotate, and winding a Transparent Film a designated distance over goggles.

A roll (10) of glass ribbon (20) and an interleaf material (40) disposed in alternating layers, wherein a layer of the interleaf material is pinned to an adjacent layer of the glass ribbon by an electrostatic force that is of a value so that a shear force required to cause slip between the interleaf material and the glass ribbon is greater than or equal to 10 times that required to cause slip between them when not electrostatically pinned together. Methods for winding and unwinding the roll, as well as an apparatus for winding the glass ribbon and interleaf material into a roll, are also disclosed.

A roll (10) of glass ribbon (20) and an interleaf material (40) disposed in alternating layers, wherein a layer of the interleaf material is pinned to an adjacent layer of the glass ribbon by an electrostatic force that is of a value so that a shear force required to cause slip between the interleaf material and the glass ribbon is greater than or equal to 10 times that required to cause slip between them when not electrostatically pinned together. Methods for winding and unwinding the roll, as well as an apparatus for winding the glass ribbon and interleaf material into a roll, are also disclosed.

A roll (10) of glass ribbon (20) and an interleaf material (40) disposed in alternating layers, wherein a layer of the interleaf material is pinned to an adjacent layer of the glass ribbon by an electrostatic force that is of a value so that a shear force required to cause slip between the interleaf material and the glass ribbon is greater than or equal to 10 times that required to cause slip between them when not electrostatically pinned together. Methods for winding and unwinding the roll, as well as an apparatus for winding the glass ribbon and interleaf material into a roll, are also disclosed.

A roll (10) of glass ribbon (20) and an interleaf material (40) disposed in alternating layers, wherein a layer of the interleaf material is pinned to an adjacent layer of the glass ribbon by an electrostatic force that is of a value so that a shear force required to cause slip between the interleaf material and the glass ribbon is greater than or equal to 10 times that required to cause slip between them when not electrostatically pinned together. Methods for winding and unwinding the roll, as well as an apparatus for winding the glass ribbon and interleaf material into a roll, are also disclosed.

Disclosed is an Off-Road Rolling Film Vision System comprising a Controller Module (200), a Takeup Module (300), and a Rollout Module (400). The Controller Module (200) comprises a Command Input (205), a Controller Process Module (210), a Command Transmitter (215), and a Power Supply (220). The Controller Module (200) is configured to remotely control a Motor (325) in the Takeup Module (300). The Command Input (205) comprises at least one Button configured to accept a knuckle bump for controlling a Motor (325) in the Takeup Module (300) when the Controller Module (200) is attached to a handlebar of an off-road vehicle. The at least one Button configured to accept a knuckle bump may be configured to be adjacent to a user's metacarpophalangeal index finger joint. The at least one Button configured to accept a knuckle bump may be configured to be adjacent to a user's metacarpophalangeal thumb joint. The Takeup Module (300) comprises a Motor Compartment (305), a Takeup Spool Compartment (310), a Takeup Spool Gear Compartment (315), a Takeup Film Window (320), a Motor (325), a Motor Gearbox (330), and at least one Takeup Spool Gear (340). The Takeup Module (300) may further comprise a Takeup Spool Window (350) configured to provide a view of a Takeup Spool (345) within the Takeup Module (300). Also disclosed is a Takeup Spool (500) comprising a Spool Alignment Tab Wheel (505), a Spool Ribbed Shaft (510), a Rib Quarter Section Cutout (515), a Spool Alignment Slot Wheel (525), a Spool Alignment Tab (530), a Spool Alignment Slot (535), a Plurality of Wheel Cutouts (540), and a Plurality of Wheel Slots (545). Also disclosed is a method for maintaining clear vision with goggles comprising receiving a command input via a knuckle bump, transmitting a designated signal to a module comprising a Motor and a Takeup Spool, activating the Motor to cause the Takeup Spool to rotate, and winding a Transparent Film a designated distance over goggles.

Disclosed is an Off-Road Rolling Film Vision System comprising a Controller Module (200), a Takeup Module (300), and a Rollout Module (400). The Controller Module (200) comprises a Command Input (205), a Controller Process Module (210), a Command Transmitter (215), and a Power Supply (220). The Controller Module (200) is configured to remotely control a Motor (325) in the Takeup Module (300). The Command Input (205) comprises at least one Button configured to accept a knuckle bump for controlling a Motor (325) in the Takeup Module (300) when the Controller Module (200) is attached to a handlebar of an off-road vehicle. The at least one Button configured to accept a knuckle bump may be configured to be adjacent to a user's metacarpophalangeal index finger joint. The at least one Button configured to accept a knuckle bump may be configured to be adjacent to a user's metacarpophalangeal thumb joint. The Takeup Module (300) comprises a Motor Compartment (305), a Takeup Spool Compartment (310), a Takeup Spool Gear Compartment (315), a Takeup Film Window (320), a Motor (325), a Motor Gearbox (330), and at least one Takeup Spool Gear (340). The Takeup Module (300) may further comprise a Takeup Spool Window (350) configured to provide a view of a Takeup Spool (345) within the Takeup Module (300). Also disclosed is a Takeup Spool (500) comprising a Spool Alignment Tab Wheel (505), a Spool Ribbed Shaft (510), a Rib Quarter Section Cutout (515), a Spool Alignment Slot Wheel (525), a Spool Alignment Tab (530), a Spool Alignment Slot (535), a Plurality of Wheel Cutouts (540), and a Plurality of Wheel Slots (545). Also disclosed is a method for maintaining clear vision with goggles comprising receiving a command input via a knuckle bump, transmitting a designated signal to a module comprising a Motor and a Takeup Spool, activating the Motor to cause the Takeup Spool to rotate, and winding a Transparent Film a designated distance over goggles.

A cam-controlled core inserter for a surface winder is disclosed. The cam-controlled core insertion device provides for a shaft having a plurality of cam housings disposed thereabout. A cam cooperatively associated with a respective cam housing is disposed within a first surface of each of the cam housings. A fixed finger plate cooperatively associated with a respective cam housing and having a fixed finger fixably attached thereto is juxtaposed proximate to each of the cam housings and fixably attached to the shaft. A cam follower having a finger shaft that has a movable finger attached thereto is cooperatively associated with each of the cams. The distal end of each of the movable fingers and the distal end of each of the fixed fingers are capable of forming a space therebetween for contacting engagement and containment of a core suitable for the convolute disposal of a web material thereabout.

A surface winder for winding a log of web material convolutely about a core is disclosed. The surface winder has a frame providing the web material with a path therethrough, a first winding roll rotatably mounted in the frame on one side of the path, a stationary finger mounted on the frame on the other side of the path adjacent the first winding roll and spaced therefrom a distance sufficient to receive the core to be wound in the path, the first winding roll cooperating with the stationary finger means to rotate the core, a cam-controlled core insertion device for a surface winder, and a second winding roll rotatably mounted in the frame on the other side of the path and downstream in the direction of web advance from the stationary finger means and forming a nip with the first winding roll.