A method for machining a plurality of surfaces of a respective plurality of drawers in an article of furniture includes mounting the article of furniture to a support structure to form a work piece, positioning the work piece on a base of a vertical gantry router in an orientation such that the plurality of surfaces are generally perpendicular to a cutting head of the vertical gantry router, and machining the plurality of surfaces with the vertical gantry router until the plurality of surfaces are substantially flat and substantially coplanar with one another.

A method for machining a plurality of surfaces of a respective plurality of drawers in an article of furniture includes mounting the article of furniture to a support structure to form a work piece, positioning the work piece on a base of a vertical gantry router in an orientation such that the plurality of surfaces are generally perpendicular to a cutting head of the vertical gantry router, and machining the plurality of surfaces with the vertical gantry router until the plurality of surfaces are substantially flat and substantially coplanar with one another.

A working control module of a woodworking tenoning machine is configured to work a wood material in a desired tenoning shape by using a human machine interface (HMI). The working control module contains: a tool selection module, a tenoning shape selection module, a model calculation module, a three-dimensional (3D) drawing module, a working path module, a feeding module, a working module, and a material returning module. Thereby, the user is capable of selecting the desired tenon shape, inputting the at least one characteristic variable of the desired tenon shape to draw, view or amend the 3D model by using the HMI of the working control module. After confirming the 3D model, the wood material is worked in the desired tenon shape automatically, thus enhancing working efficiency and working accuracy.

A working control module of a woodworking tenoning machine is configured to work a wood material in a desired tenoning shape by using a human machine interface (HMI). The working control module contains: a tool selection module, a tenoning shape selection module, a model calculation module, a three-dimensional (3D) drawing module, a working path module, a feeding module, a working module, and a material returning module. Thereby, the user is capable of selecting the desired tenon shape, inputting the at least one characteristic variable of the desired tenon shape to draw, view or amend the 3D model by using the HMI of the working control module. After confirming the 3D model, the wood material is worked in the desired tenon shape automatically, thus enhancing working efficiency and working accuracy.

The invention relates to a supporting device for a plurality of components (100, 200, 100*) with different geometries, in particular for a plurality of geometrically different motor-vehicle external attachments made of polymer material, having a support frame (30), a drive (40) arranged on the support frame (30) and at least two supporting groups (1, 2, 3, 4, 5) arranged on the support frame (30), wherein each supporting group (1, 2, 3, 4, 5) serves as a supporting surface for a particular component geometry, wherein each supporting group (1, 2, 3, 4, 5) has at least two spaced-apart, disc-shaped supporting elements (1, 1, 1; 2, 2, 2, etc.), the upwardly facing rim (10, 10, 10; 20, 20, 20, etc.) of each of which already has, in the unloaded state, a contour adapted to the geometry of the associated component (100, 200, 100*). By means of the drive (40), the supporting elements (1, 1, 1; 2, 2, 2, etc.) are movable such that only the supporting elements (1, 1, 1; 2, 2, 2, etc.) of a single supporting group (1, 2, etc.) protrude upwards such that the upwardly facing rims (10, 10, 10; 20, 20, 20, etc.) thereof form the supporting surface for the component geometry associated therewith.

A machining device, including: a cart, for carrying a master-piece and a work-piece; a rail, for allowing manual sliding of the cart along the rail thereabove; a first vice for securing the master-piece, the first vice being fixed to the movable cart; a second vice for securing the work-piece, the second vice being fixed to the movable cart; a limiting element, for limiting the manual sliding of the cart upon meeting of the master-piece with the limiting element; and a protrusion including at least two points extending downwards from the rail; thereby the machining device utilizes parallelism between the channel and a cutting blade of the table saw.

A method for mechanically producing a wood structure with a decorative pattern is disclosed, wherein partial patterns are processed onto a working face of a wood structure by moving at least one milling cutter of a processing head of a device for patterning transversely to the wood structure with the axis of rotation of the milling cutter at an inclined angle relative to the place of the working face in such a way that grooves that form the partial pattern are formed on the working face, each of the grooves having two planes set at an angle relative to each other while the depth of the groove changes in the transverse direction of the groove. In the method, the wood structure is formed of at least two or more adjacently placed pieces of wood each having two edges, wherein several successive grooves are formed onto the working face of at least two pieces of wood with a single milling movement, each single milling movement beginning or ending at an edge of the piece of wood so that the partial patterns form together the pattern of the wood structure. A corresponding device for patterning and a decorative wood structure are also disclosed.

A dust and debris collection system for use with woodworking routers, including a baffle, a dust collection hood, and a brush. The baffle includes a top surface, where the top surface is configured to deflect cooling air generated by a woodworking router out and away from the woodworking router in order to allow the woodworking router adequate cooling and efficient dust collection. The dust collection hood is located adjacent to the baffle and includes a sloped wall that is aerodynamically shaped to remove dust and debris and includes a central bit hole configured to accept a bit. The brush has a series of bristles extending from the dust collection hood. The brush and its bristles contain dust and debris.

A dust and debris collection system for use with woodworking routers, including a baffle, a dust collection hood, and a brush. The baffle includes a top surface, where the top surface is configured to deflect cooling air generated by a woodworking router out and away from the woodworking router in order to allow the woodworking router adequate cooling and efficient dust collection. The dust collection hood is located adjacent to the baffle and includes a sloped wall that is aerodynamically shaped to remove dust and debris and includes a central bit hole configured to accept a bit. The brush has a series of bristles extending from the dust collection hood. The brush and its bristles contain dust and debris.

A device and a method for machining a workpiece are provided, wherein said workpiece includes segments of wood, wood-based materials, synthetic material or the like, having a first milling tool for contour machining an edge attached to said workpiece, a second milling tool for contour machining the edge attached to said workpiece, which is adjustable in relation to said first milling tool between a resting position, in which said first milling tool is engageable with the workpiece, and a machining position, in which said second milling tool is engageable with a workpiece. The device is characterized by a third milling tool for flush milling a narrow side of the edge attached to said workpiece, the three milling tools being arranged coaxially to each other and all are jointly drivable by one device.