A manually operated saddle peeling device for machining an outer surface of a tubular body, comprises a supporting unit and a guiding unit provided on an underside of the supporting unit and configured to guide the supporting unit in a peeling direction at a defined distance from the surface of the tubular body to be machined. The device further comprises a peeling unit provided on an underside of the supporting unit opposite the surface of the tubular body to be machined, comprising at least one stationary peeling blade which is configured to contact the surface of the tubular body to be machined and thereby remove material from the surface of the tubular body and a handle unit provided to the side of the supporting unit and thus generally parallel to the peeling direction and configured to enable manual guidance of the saddle peeling device over the outer surface of the tubular body at least in portions.

The invention relates to a deflecting device for separating and peeling off a second material web (4) from a multilayer material web (1), comprising a die-cut first material web (2a) with die-cutting waste (2b) and the second material web (4), wherein the deflecting device (7) has a first deflecting contour (71) over which the second material web (4) is passable for separating and peeling off the second material web (4) from the die-cut first material web (2a), wherein the deflecting device (7) has a second deflecting contour (72) over which the second material web (4) is passable for deflecting a front edge (20b) of die-cutting waste (2b), and wherein the second deflecting contour (72) is not the same as the first deflecting contour (71). The invention further relates to a device and to a method for separating and peeling off a material web from a multilayer material web.

A heat chamfering apparatus. A support unit supports a glass panel. A heat chamfering unit heat-chamfers an edge of the glass panel by applying thermal shock thereto. The support unit includes a contact support portion supporting the glass panel while in contact with the glass panel and a base portion configured to support the contact support portion. The contact support portion is formed from a first material. The base portion is formed from a second material. The first material has a smaller change in temperature due to lower thermal conductivity and a smaller change in size at high temperature due to a smaller coefficient of thermal expansion while being more ductile due to lower hardness, compared to the second material. In a heat chamfering method, a glass panel is located on a support unit, and an edge of the glass panel is heat-chamfered by applying thermal shock thereto.