A windshield removal tool has elongate arm with a claw at its distal end. The device also includes a winch actuated by a motor at the proximal end of the arm. When a cutting wire is positioned along an adhesive bead about a periphery of a fixed glass or panel, the cutting wire is threaded through a puncture in the adhesive bead and attached to the winch. The claw engages a location along the adhesive bead as the winch wines in the cutting wire. A pulley near the distal end of the arm guides the wire. The device may be removed from an initial anchored position and anchored at a new position by removing the claw and placing it at another point along the periphery.

A windshield removal tool has elongate arm with a claw at its distal end. The device also includes a winch actuated by a motor at the proximal end of the arm. When a cutting wire is positioned along an adhesive bead about a periphery of a fixed glass or panel, the cutting wire is threaded through a puncture in the adhesive bead and attached to the winch. The claw engages a location along the adhesive bead as the winch wines in the cutting wire. A pulley near the distal end of the arm guides the wire. The device may be removed from an initial anchored position and anchored at a new position by removing the claw and placing it at another point along the periphery.

A glazing panel removal device comprising a winder unit (1) having first and second winder spools (10, 11) for winding a cutting filament (100) and a drive, for driving the winder spools (10). The drive means includes a single or common drive input for driving both the first and second winder spools (10, 11). The drive maybe a rotary input drive, and driving the rotary input in a first rotary direction may cause winding of the filament (100) onto the first winder spool (10) and driving the rotary input in the opposite direction causes winding of the filament (100) onto the second winder spool (11).

A glazing panel removal device comprising a winder unit (1) having first and second winder spools (10, 11) for winding a cutting filament (100) and a drive, for driving the winder spools (10). The drive means includes a single or common drive input for driving both the first and second winder spools (10, 11). The drive maybe a rotary input drive, and driving the rotary input in a first rotary direction may cause winding of the filament (100) onto the first winder spool (10) and driving the rotary input in the opposite direction causes winding of the filament (100) onto the second winder spool (11).

Apparatuses and methods for decoupling an element that is bonded to a surface by an adhesive are provided. In one example, the apparatus includes a body, a first spool that is rotationally coupled to the body, and a cable having a first cable end portion that is coupled to the first spool, a second cable end portion that is coupled to the body, and a cable intermediate portion that is disposed between the first cable end portion and the second cable end portion. The apparatus is configured to be positioned adjacent to at least one of the element and the surface with the cable intermediate portion disposed adjacent to the adhesive such that when the first spool is rotated, the cable wraps about the first spool, thereby pulling the cable intermediate portion through the adhesive.

A glazing panel removal device includes a winder unit having first and second winder spools for winding a cutting filament and a drive, for driving the winder spools. The drive means includes a single or common drive input for driving both the first and second winder spools. The drive maybe a rotary input drive, and driving the rotary input in a first rotary direction may cause winding of the filament onto the first winder spool and driving the rotary input in the opposite direction causes winding of the filament onto the second winder spool.

A glazing panel removal device includes a winder unit having first and second winder spools for winding a cutting filament and a drive, for driving the winder spools. The drive means includes a single or common drive input for driving both the first and second winder spools. The drive maybe a rotary input drive, and driving the rotary input in a first rotary direction may cause winding of the filament onto the first winder spool and driving the rotary input in the opposite direction causes winding of the filament onto the second winder spool.

A system for removing glass sealed to an object such as an automobile is shown. The glass removal system includes a cord and wire glass removal tool and a remote control device. The cord and wire glass removal tool includes a body, a motor, a vacuum pump, an attachment mechanism and a power source. The cord and wire glass removal tool can be paired with a remote control device allowing a user to place the tool on an inner surface of the glass and operate the tool from a position adjacent to the outside surface of the glass.

A housing has a first end and a second end, an inner surface of the housing defining a channel that is configured to slidably receive therein a food product. A food product motivating mechanism is configured to engage a food product, the food product motivating mechanism being slidably receivable in the first end of the housing, the food product motivating mechanism and the housing being configured to cooperatively slidably urge a food product from the first end of the housing toward the second end of the housing. A rotating cutting mechanism is removably attachable to an outer surface of the second end of the housing, the rotating cutting mechanism being configured to rotate about the second end of the housing, the rotating cutting mechanism being further configured to cuttingly engage a food product.

A cutting device of cutting a soft honeycomb mold body in a cutting direction perpendicular to an axial direction of the honeycomb mold body. A cutting device has a wire, a tension supply part and a pair of ultrasonic generators. The wire has a contact part which is stretched and in contact with the honeycomb mold body when the honeycomb mold body is cut. The tension supply part supplies tensile to the contact part when the honeycomb mold body is cut. The pair of ultrasonic generators have respective vibrator terminals arranged in contact with the contact part of the wire. The ultrasonic generators generate ultrasonic vibration in the cutting direction and supply the generated ultrasonic vibration directly to the wire.