A device for cutting material on a supporting surface has at least one cutting unit, which can be motor-driven in a controlled manner above and across the supporting surface in a direction of an X- and Y-axis of a Cartesian coordinate system that is parallel to the material supporting surface. The at least one cutting unit comprises an oscillation drive and a cutting knife. The oscillation drive sets the cutting knife into linear oscillations having an oscillation axis that is perpendicular to an advancing direction of the cutting knife. For changing an angle of inclination of the oscillation axis with respect to the material supporting surface, the oscillation drive with the cutting knife is pivotable around a pivot axis that is parallel to the material supporting surface. The oscillation drive comprises an electric motor having a rotary drive shaft that is parallel to the material supporting surface. The rotary axis of the rotary drive shaft is aligned with the pivot axis.

A device for use in creating custom tiles for installation adjacent an angled vertical surface is disclosed. An example device includes first and second elongated members coupled via a hinge configured to selectively prevent pivoting at the hinge. The device further includes a slide piece coupled to the first member and configured to slide lengthwise along the first member. The slide piece may be selectively operated to prevent movement along the first member. The slide piece may further include a body. The body may comprise a longitudinal alignment element and a perpendicular lateral alignment element that together define a recess configured to receive a corner of an installed tile. The body may further include a spacer configured to selectively extend from or retract into the body. The spacer and the lateral alignment element may define a space therebetween.

A mold separation method includes the following steps: providing a mold separation device including a carrying mechanism, a scraping mechanism, and two separation mechanisms, wherein the scraping mechanism is disposed at an edge of the carrying mechanism, and the separation mechanisms are disposed at the edge of the carrying mechanism and are located on two opposite sides of the scraping mechanism; placing a first mold and a second mold bonded to the first mold on the carrying mechanism; causing the scraping mechanism to scrape off a spilled glue produced when the first mold is bonded to the second mold; and after scraping off the spilled glue, causing the separation mechanisms to pull open the first mold and the second mold so that the first mold and the second mold are separated from each other.

A mold separation method includes the following steps: providing a mold separation device including a carrying mechanism, a scraping mechanism, and two separation mechanisms, wherein the scraping mechanism is disposed at an edge of the carrying mechanism, and the separation mechanisms are disposed at the edge of the carrying mechanism and are located on two opposite sides of the scraping mechanism; placing a first mold and a second mold bonded to the first mold on the carrying mechanism; causing the scraping mechanism to scrape off a spilled glue produced when the first mold is bonded to the second mold; and after scraping off the spilled glue, causing the separation mechanisms to pull open the first mold and the second mold so that the first mold and the second mold are separated from each other.

A sheet processing apparatus (1) includes a first processing section (1000), a second processing section (2000), and a third processing section (3000) arranged on a straight line, and conveys a sheet (4200) therebetween. The first processing section (1000) forms a plurality of first processing lines extending in a first direction (an X axial direction) on the sheet (4200), by moving a plurality of tools (1110-1260) to the first direction in relation to the sheet (4200). The second processing section (2000) forms a plurality of second processing lines to a second direction (a Y axial direction) orthogonal to the first direction on the sheet (4200), by moving a plurality of tools to the second direction in relation to the sheet (4200). The third processing section (3000) forms a third processing line (aslant line, curve line) on the sheet, by relatively moving the sheet (4200) and the tool (3110, 3120).

A mold separation device includes a carrying mechanism, a scraping mechanism, and two separation mechanisms. The carrying mechanism is adapted to carry a first mold and a second mold bonded to the first mold. The scraping mechanism is disposed at an edge of the carrying mechanism and is adapted to scrape off a spilled glue produced when the first mold is bonded to the second mold. The separation mechanisms are disposed at the edge of the carrying mechanism and are located on two opposite sides of the scraping mechanism. The separation mechanisms are adapted to pull open the first mold and the second mold so that the first mold and the second mold are separated from each other.

A device for use in creating custom tiles for installation adjacent an angled vertical surface is disclosed. An example device includes first and second elongated members coupled via a hinge configured to selectively prevent pivoting at the hinge. The device further includes a slide piece coupled to the first member and configured to slide lengthwise along the first member. The slide piece may be selectively operated to prevent movement along the first member. The slide piece may further include a body. The body may comprise a longitudinal alignment element and a perpendicular lateral alignment element that together define a recess configured to receive a corner of an installed tile. The body may further include a spacer configured to selectively extend from or retract into the body. The spacer and the lateral alignment element may define a space therebetween.

A method is provided for automatically modifying the cutting paths for parts to be cut out from a flexible material by automatically moving a cutter tool along predetermined cutting paths. The cutting paths are associated with each part being defined by a succession of cutting segments forming a polygon. Two cutting segments are identified and belonging to two different parts for cutting out in the material and for which a maximum distance condition between these cutting segments is satisfied. Two cutting segments are verified for being situated facing each other, and that no other cutting segments lie between the two cutting segments. A common cutting path for the two cutting segments is computed, and a common cutting path is connected to the cutting paths of the two parts for cutting out to obtain modified cutting paths for the two parts for cutting out.

A device for the cutting of material on a plane material supporting surface, the device having at least one cutting unit which can be motor-driven in a controlled manner above the material supporting surface in the direction of the X- and Y-axis of a Cartesian coordinate system that is parallel to the material supporting surface, and having an oscillation drive and a cutting knife, wherein the oscillation drive sets the cutting knife into linear oscillations along an oscillation axis that is perpendicular to the advancing direction of the cutting knife. The cutting knife is pivotable around a pivot axis that is parallel to the material supporting surface and is aligned with the rotary axis of a rotary drive shaft of an electric motor of the oscillation drive.

A method is provided for automatically modifying the cutting paths for parts to be cut out from a flexible material by automatically moving a cutter tool along predetermined cutting paths. The cutting paths are associated with each part being defined by a succession of cutting segments forming a polygon. Two cutting segments are identified and belonging to two different parts for cutting out in the material and for which a maximum distance condition between these cutting segments is satisfied. Two cutting segments are verified for being situated facing each other, and that no other cutting segments lie between the two cutting segments. A common cutting path for the two cutting segments is computed, and a common cutting path is connected to the cutting paths of the two parts for cutting out to obtain modified cutting paths for the two parts for cutting out.