A method, system, apparatus, and/or device for cutting, slicing, or grating cheese. The method, system, apparatus, and/or device may include a receptacle that include a cavity to store a piece of cheese, wherein the receptacle includes an open end. The method, system, apparatus, and/or device may include a platform located within the cavity, the platform comprising a floor for the piece of cheese to sit on, where the floor includes a set of grooves. The method, system, apparatus, and/or device may include a drive system connected to the platform, the drive system being configured to extend the platform out of the open end and retract the platform within the cavity, where the drive system comprises a gear comprising a set of teeth configured to engage one or more grooves of the set of grooves of the floor. The method, system, apparatus, and/or device may include a handle configured to attach to the open end of the receptacle, the handle comprising a first accessory to engage the piece of cheese.

A winder unit (1) is for use with a cutting filament (such as a wire) in cutting out a vehicle glazing panel. The winder unit has a winder spool (3, 4) for winding cutting filament and a mount (2) for mounting the unit. The winder spool (3, 4) is movable relative to the mount (2) between first and second operational positions for example by means of being pivoted or tilted.

A winder unit (1) is for use with a cutting filament (such as a wire) in cutting out a vehicle glazing panel. The winder unit has a winder spool (3, 4) for winding cutting filament and a mount (2) for mounting the unit. The winder spool (3, 4) is movable relative to the mount (2) between first and second operational positions for example by means of being pivoted or tilted.

A photovoltaic module includes a first protective element, a second protective element, photovoltaic cells that are located between the first protective element and the second protective element, an envelope in which the photovoltaic cells are encapsulated. The envelope links the first protective element to the second protective element and includes a first portion that is located between the photovoltaic cells and the first protective element, and a second portion that is located between the photovoltaic cells and the second protective element. The disassembly method includes separating the photovoltaic cells with respect to the first protective element and cutting the first portion of the envelope by an abrasive wire.

The invention discloses a device (1) for releasing glasses (2) from the bodies (3) of vehicles where the device (1) comprises a frame (4), at least one suction pad (5), one guide pulley (6) fitted with two guide grooves (7) for guiding a cutting wire (8), or two guide pulleys (6) with a common central line, and two winding pulleys (9). The winding pulleys are fitted with winding grooves (10) for winding the cutting wire (8) and a spacing element or a spacing pulley (11) keeping the cutting wire (8) at a safe distance from the suction pad (5). During releasing the glass (2) the cutting angle () of the cutting wire (8) does not exceed the value of 90. Each end of the cutting wire (8) is wound onto the winding pulleys (9) due to the guide grooves (7) wherein a safe distance from the suction pad (5) is ensured to eliminate their damage.

The invention discloses a device (1) for releasing glasses (2) from the bodies (3) of vehicles where the device (1) comprises a frame (4), at least one suction pad (5), one guide pulley (6) fitted with two guide grooves (7) for guiding a cutting wire (8), or two guide pulleys (6) with a common central line, and two winding pulleys (9). The winding pulleys are fitted with winding grooves (10) for winding the cutting wire (8) and a spacing element or a spacing pulley (11) keeping the cutting wire (8) at a safe distance from the suction pad (5). During releasing the glass (2) the cutting angle () of the cutting wire (8) does not exceed the value of 90. Each end of the cutting wire (8) is wound onto the winding pulleys (9) due to the guide grooves (7) wherein a safe distance from the suction pad (5) is ensured to eliminate their damage.

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).

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.

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.