An automated crosscut saw system utilizing a wood scanning unit to optimize the cuts in a particular piece of wood to remove defects or flaws and a method of use therefor is provided. The automated saw system has the ability to scan and cut a piece of wood simultaneously or in rapid succession without the need for scanning the entire length of the wood prior to cutting. Further, the automated saw system may eliminate the need for a secondary feeder and secondary queue.

A mobile machine tool (10), namely a manually-operated machine tool (10) or semi-stationary machine tool (10), for machining a workpiece (W), wherein the machine tool (10) a plate-like guide element (30) with a guide surface (32) for guiding the machine tool (10) on the workpiece (W) or the workpiece (W) on the machine tool (10), wherein the machine tool (10) has a drive unit (11) with a drive motor (13) for driving a tool holder (14) arranged on the drive unit (11) in order to hold a work tool (15), wherein the machine tool (10) has a tool sensor the detection range (EB1, EB2) of which is at least partially affected by particles which are produced during the machining of a workpiece (W) by means of the work tool (15). The machine tool is provided with at least one optimisation means (OPT) to reduce the effect of the particles present within the detection range (EB1, EB2) on a tool sensor signal of the tool sensor (61, 62).

An automated saw wherein: the automated saw comprises one or more visual sensors, a positioning system. The automated saw is configured to analyze an uncut meat and calculate a one or more cutting depths for a one or more cut portions from the uncut meat. The uncut meat comprises a first end and a second end. The first end of the uncut meat can be analyzed by the automated saw by: capturing a first slice image of the first end, locating a first bone configuration and a configuration of a one or more meat portions in relation to the first bone configuration, and measuring portions of the one or more meat portions to categorize which among a one or more cuts of meat is presented at the first end of the uncut meat. The automated saw calculates a first cutting depth for a first meat portion.

An example pipe cutting tool includes a plurality of actuators and a plurality of cutters. Each of the plurality of cutters is connected to at least one separate actuator of the plurality of actuators. The at least one separate actuator is configured to move the cutter between a pre-deployed and deployed position. The deployed position is beyond the pre-deployed position. The plurality of cutters may include a first and second cutter, with the at least one separate actuator connected to the second cutter moving based, at least in part, on one or more cutting conditions. An example method of cutting a pipe includes extending a first cutter to contact the pipe, cutting at least a portion of the pipe using the first cutter, detecting a cutting condition, extending a second cutter based, at least in part, on the cutting condition, and resuming the cutting using the second cutter.

An edger feed apparatus and method of feeding flitches into an edger are disclosed. The flitches are positioned with minimal spacing between successive flitches and with flitches positioned and the edger adjusted so as to yield a maximum value of lumber from each flitch. The edger feed apparatus may include a fetcher assembly to hold a second flitch in an edger ready position while a portion of the first flitch is directed below on an edger infeed mechanism being transported to the edger. The fetcher assembly releases the second flitch on to the edger infeed mechanism when the first flitch has moved clear from beneath the edger ready position. The edger feed apparatus additionally includes a scanner system for creating and storing a digital three-dimensional model of each flitch for determining a sawing solution to be implemented by the edger.

A method for controlling a device system (10) during the cutting of a workpiece (18) along a cutting line (43) up to a first end point (E.sub.1) using a saw head (12) that can be moved on a guide rail (11) along an advancing direction (26), whereby the saw head (12) is arranged on the guide rail (11) in a starting position (X.sub.0), and a first partial length (L.sub.1) extending from the starting position (X.sub.0) to the first end point (E.sub.1) of the cutting line (43) is entered.

The present disclosure describes methods and systems for virtually calibrating geometric sensors with overlapping fields of view. In some embodiments, a geometric sensor may be virtually calibrated by applying a correction value to profile data obtained by the geometric sensor to generate adjusted profile data. The correction factor may be determined based at least in part on X-Y offsets and/or rotational offsets of prior profile data obtained by the geometric sensor relative to corresponding profile data obtained by a reference geometric sensor, and may be recalculated or updated as new sets of profile data are obtained. The adjusted profile data may be used in place of the original profile data in various data processing operations to functionally offset a positional error of the geometric sensor.

A table saw includes a saw control unit and a wireless communication module dock defining a docking position. A wireless communication module is configured to be removably received in the docking position, the wireless communication module being operably connected to the saw control unit when received in the docking position. The wireless communication module includes an antenna and a wireless transceiver, the antenna and the wireless transceiver being configured to implement a first wireless communication protocol.

The present disclosure describes methods and systems for virtually calibrating geometric sensors with overlapping fields of view. In some embodiments, a geometric sensor may be virtually calibrated by applying a correction value to profile data obtained by the geometric sensor to generate adjusted profile data. The correction factor may be determined based at least in part on X-Y offsets and/or rotational offsets of prior profile data obtained by the geometric sensor relative to corresponding profile data obtained by a reference geometric sensor, and may be recalculated or updated as new sets of profile data are obtained. The adjusted profile data may be used in place of the original profile data in various data processing operations to functionally offset a positional error of the geometric sensor.

A material processing system includes: an offsetter configured to receive a stack of material and including a lifting bar configured to lift a portion of the stack of material; and a processing station operably connected to the offsetter. A method of processing a material includes: loading a stack of material on an offsetter, the stack of material including a first portion and a second portion, the first portion positioned above the second portion and separated from the second portion by at least one cross tie, the stack of material including a first end and a second end distal from the first end; lifting the second portion away from the first portion by a lifting bar of the offsetter pushing upward on the second end; and removing the cross tie.