A method for manufacturing a multi-sided continuously patterned stone panel according to the present invention includes: cutting out stripes (116) in which continuous linear patterns are formed on both sides thereof by cutting an original plate (110) along successively repeated linear paths (continuous linear patterns) (112) while moving a water jet device (120) in a vertical direction; separating the separate stripes (116), and loading each of the separate stripes (116) on a lateral cutting device (130); and cutting out multi-sided continuously patterned stone panel products in which continuous linear patterns are formed on both sides thereof and remaining two sides thereof are cut in rectilinear lines by cutting the stripe (116) with a blade cutter (134), installed on a frame (132) of a lateral cutting device (130), in rectilinear lines in a lateral direction.

A method for manufacturing a multi-sided continuously patterned stone panel according to the present invention includes: cutting out stripes (116) in which continuous linear patterns are formed on both sides thereof by cutting an original plate (110) along successively repeated linear paths (continuous linear patterns) (112) while moving a water jet device (120) in a vertical direction; separating the separate stripes (116), and loading each of the separate stripes (116) on a lateral cutting device (130); and cutting out multi-sided continuously patterned stone panel products in which continuous linear patterns are formed on both sides thereof and remaining two sides thereof are cut in rectilinear lines by cutting the stripe (116) with a blade cutter (134), installed on a frame (132) of a lateral cutting device (130), in rectilinear lines in a lateral direction.

A tile cutting apparatus is provided that includes a main body, a lever coupled to the main body, and a pressing member coupled to the lever. The main body includes a base member, a first plate member coupled to the base member, a second plate member coupled to the base member and disposed adjacent to the first plate member, and a projecting member that includes a projecting body. The projecting member is coupled to the first and second plate members such that a force applied to the first and second plate members towards the base member causes the projecting body to move away from the base member and between the first and second plate members. The lever is configured to be rotatable about an axis such that rotating the lever about the axis moves the pressing member towards or away from the base member.

Disclosed herein is a scribing wheel having a predetermined thickness and a disk shape. The scribing wheel includes: a wheel body configured in such a way that at least a peripheral edge portion thereof is gradually reduced in thickness from the center to the radial outside; and a cutter part including recesses and cutting blade teeth which are alternately arranged along the peripheral edge portion. Each recess is formed by a combination of side recess portions formed in opposite side surfaces of the peripheral edge portion of the wheel body and an edge recess portion formed in the peripheral edge of the wheel body.

A portable tile cutter includes a main unit having a base frame and a guard connected to the base frame, a cutter blade pivotally mounted at the guard, a driving unit connected to the guard and operable to rotate the cutter blade, a first handle connected to the driving unit, and a second handle connected to the guard and providing a grip. The component parts of the portable tile cutter are so arranged that moving one or both the driving unit and the second handle can achieve adjustment of the gap between the first handle and the grip of the second handle. Thus, the portable tile cutter can fit different users having different body sizes.

The present invention relates to a method for separating solid-body slices (1) from a donor substrate (2). The method comprises the steps of: producing modifications (10) within the donor substrate (2) by means of laser beams (12), wherein a detachment region is predefined by the modifications (10), along which detachment region the solid-body layer (1) is separated from the donor substrate (2), and removing material from the donor substrate (2), starting from a surface (4) extending in the peripheral direction of the donor substrate (2), in the direction of the centre (Z) of the donor substrate (2), in particular in order to produce a peripheral indentation (6).

A cutter edge is caused to slide to generate a plastic deformation on a first surface of a brittle substrate, thus forming a trench line. The trench line is formed so as to obtain a crack-free state in which the brittle substrate seamlessly continues in a direction intersecting the trench line directly below the trench line. The crack-free state is then maintained. A crack of the brittle substrate in its thickness direction is extended along the trench line to form a crack line. The brittle substrate is divided along the crack line.

The invention relates to a cutting head (2) that includes sets of bearings comprising fixed bearings (31, 32) and an adjustable bearing (33) that act on races (11, 12) of a monoguide profile disposed on different planes. Each adjustable bearing (33) is mounted on a rocker (4) having a first end (41) rotatably mounted on a shaft (5) fixed to the cutting head (2), and a second end (42) that presses against an elastic element (6) situated between the second end (42) of the rocker (4) and the case of the cutting head (2), the elastic element (6) determining the pressure of the bearings (31, 32, 33) against the races (11, 12) of the monoguide profile (1).

A cutter head includes: a support platform; a double curved surface member mounted on the support platform and having a first curved surface and a second curved surface; a cutter wheel support member and a roller wheel support member moveably mounted on the support platform, respectively; a cutter wheel and a roller wheel mounted on the cutter wheel support member and the roller wheel support member, respectively; a first transmission mechanism mounted on the support platform, configured to be mated with the first curved surface, and connected to the cutter wheel support member, so as to transmit a movement of the double curved surface member to the cutter wheel; and a second transmission mechanism mounted on the support platform, configured to be mated with the second curved surface, and connected to the roller wheel support member, so as to transmit a movement of the double curved surface member to the roller wheel. The cutter head has a compact structure, and it improves the levelness of the cutter wheel and the roller wheel, and increases the mechanical precision.

A manufacturing method for a band-shaped glass film (GF) includes use of: a plurality of rollers (10) configured to change a direction of the falling band-shaped glass film (GF) to a horizontal direction; and a first horizontal-conveyance unit (4) configured to convey the band-shaped glass film (GF) in the horizontal direction after the changing of the direction of the band-shaped glass film (GF). After a lower end of the band-shaped glass film (GF) passes through a position between the plurality of rollers (10) being at a retreated position (P2) and the first horizontal-conveyance unit (4), the plurality of rollers (10) are moved from the retreated position (P2) to a regular position (P1) to apply a pressing force to the band-shaped glass film (GF), to thereby cut the band-shaped glass film (GF) along a width direction by bend-breaking.