An apparatus including a controller, and at least two cutting head assemblies. The controller typically includes a computer processor, and a computer memory, having a computer program stored therein. The controller automatically controls the current load of a cutting motor of each of the at least two cutting head assemblies via current sensors, in response to monitoring real time current loads. The controller may also control feed mechanism speed. The feed mechanism may include a conveyor belt. The controller may also be programmed to control a position or height of each of the at least two cutting head assemblies with respect to the feed mechanism. The two or more cutting head assemblies may be attached to a frame, and the controller may control the movement of the frame perpendicular to the direction of movement of feeding mechanism. Cutting head pads may be monitored for wear and replaced if necessary.

A method for smoothing and/or polishing slabs of stone or stone-like material suitable for being implemented with a machine comprising: a support bench (16) for a slab to be machined; and at least one machining station (14). The machining station comprises two bridge support structures (20, 22) arranged transversely astride the support bench (16). A spindle-carrying beam (24), in suitable for being moved above the bridge structures in a transverse direction, is provided on the bridge support structures (20, 22). At least one spindle-carrying structure (34), suitable for being rotated about its own vertical axis (32), is provided on the spindle-carrying beam (24). Each spindle-carrying structure (34) is provided with two motorized spindles (38A, 38B), the ends of which are provided with machining heads (42A, 42B) arranged spaced apart and opposite each other with respect to the vertical axis (32) of the spindle-carrying structure (34) and comprising machining tools (44A, 44B). The machine comprises a programmable computerized unit for controlling the position, movement and speed of the moving members. The method is characterized in that: the beam and the spindle-carrying structures move coordinated and synchronized with each other; for each stroke of the beam (24) in the transverse direction, each spindle-carrying structure performs a rotation of 180 about its axis of rotation (32); when the beam (24) is located at the center line of the bench (16), the axis (60) connecting the rotation axes of the spindles (38A, 38B) is perpendicular to the longitudinal direction of the machine; and when the beam (24) is located at the maximum distance from the center line of the bench (16), the axis (60) is parallel to the longitudinal axis of the machine.

A method for smoothing and/or polishing slabs of stone or stone-like material suitable for being implemented with a machine comprising: a support bench (16) for a slab to be machined; and at least one machining station (14). The machining station comprises two bridge support structures (20, 22) arranged transversely astride the support bench (16). A spindle-carrying beam (24), in suitable for being moved above the bridge structures in a transverse direction, is provided on the bridge support structures (20, 22). At least one spindle-carrying structure (34), suitable for being rotated about its own vertical axis (32), is provided on the spindle-carrying beam (24). Each spindle-carrying structure (34) is provided with two motorized spindles (38A, 38B), the ends of which are provided with machining heads (42A, 42B) arranged spaced apart and opposite each other with respect to the vertical axis (32) of the spindle-carrying structure (34) and comprising machining tools (44A, 44B). The machine comprises a programmable computerized unit for controlling the position, movement and speed of the moving members. The method is characterized in that: the beam and the spindle-carrying structures move coordinated and synchronized with each other; for each stroke of the beam (24) in the transverse direction, each spindle-carrying structure performs a rotation of 180 about its axis of rotation (32); when the beam (24) is located at the center line of the bench (16), the axis (60) connecting the rotation axes of the spindles (38A, 38B) is perpendicular to the longitudinal direction of the machine; and when the beam (24) is located at the maximum distance from the center line of the bench (16), the axis (60) is parallel to the longitudinal axis of the machine.

A device for recognising a sheet metal processing means in a sheet metal processing machine includes: an RFID unit for receiving a read signal of an RFID reader with information on an RFID transponder affixed on a sheet metal processing means at a sheet metal processing station in the sheet metal processing machine; an evaluation unit for determining sheet metal processing means data with information on the sheet metal processing means based on the read signal; and a machine interface for controlling a machine system of the sheet metal processing machine based on the sheet metal processing means data.

A machine for processing a screen printing frame includes an upstream end and an opposed downstream end, a grinding assembly located between the upstream and downstream locations, wherein the grinding assembly includes a first grinder configured to grind a first pattern into the screen printing frame and a second grinder configured to grind a second pattern into the screen printing frame different from the first grinding pattern.

A machine for processing a screen printing frame includes an upstream end and an opposed downstream end, a grinding assembly located between the upstream and downstream locations, wherein the grinding assembly includes a first grinder configured to grind a first pattern into the screen printing frame and a second grinder configured to grind a second pattern into the screen printing frame different from the first grinding pattern.

The present disclosure relates to a contiguous compression wire sprang polishing apparatus that continuously polishes end surfaces of compression wise springs (10) by upper and lower chain conveyers 100 and 200 and grinding units 300. The apparatus includes: two gaming units (300) each having a grindstone (350) to which rotational force of a motor (240) is transmitted through a gear box (260), the motor (240) having a rotary shaft being located above a central axis of the grindstone (350), and the two grinding units (300) being installed to be parallel and opposite to each other at opposite sides of a compression wire spring (10) fixed to the continuous compression wire spring polishing apparatus so as to polish opposite end surfaces of the compression wire spring (10); two hinge shafts (140), which are fixed at positions, which are spaced apart from grindstones in the lowest surface of the grinding units (300) by a predetermined distance, and which are inserted into and coupled to bearings, which are fixed to a body of the polishing apparatus; an upper guide (225) configured to prevent the compression wire spring (10) from springing out and a rod end fixing shaft (150) fixed to an end of the cylinder rod (170) of the pneumatic cylinder (180) inserted into and coupled to a bearing fixed at a position between the grindstone rotation shaft and the hinge shaft (140) in each of the grinding units (300). The grindstone rotation shaft of each of the grinding units (300) is turned into the vertical state or the horizontal state according to the forward and backward movements of the pneumatic cylinder (180), so that the two grindstones (350) of the grinding units (300), which are mounted to be parallel and opposite to each other, can be easily replaced.

The present disclosure relates to a contiguous compression wire sprang polishing apparatus that continuously polishes end surfaces of compression wise springs (10) by upper and lower chain conveyers 100 and 200 and grinding units 300. The apparatus includes: two gaming units (300) each having a grindstone (350) to which rotational force of a motor (240) is transmitted through a gear box (260), the motor (240) having a rotary shaft being located above a central axis of the grindstone (350), and the two grinding units (300) being installed to be parallel and opposite to each other at opposite sides of a compression wire spring (10) fixed to the continuous compression wire spring polishing apparatus so as to polish opposite end surfaces of the compression wire spring (10); two hinge shafts (140), which are fixed at positions, which are spaced apart from grindstones in the lowest surface of the grinding units (300) by a predetermined distance, and which are inserted into and coupled to bearings, which are fixed to a body of the polishing apparatus; an upper guide (225) configured to prevent the compression wire spring (10) from springing out and a rod end fixing shaft (150) fixed to an end of the cylinder rod (170) of the pneumatic cylinder (180) inserted into and coupled to a bearing fixed at a position between the grindstone rotation shaft and the hinge shaft (140) in each of the grinding units (300). The grindstone rotation shaft of each of the grinding units (300) is turned into the vertical state or the horizontal state according to the forward and backward movements of the pneumatic cylinder (180), so that the two grindstones (350) of the grinding units (300), which are mounted to be parallel and opposite to each other, can be easily replaced.

The invention relates to a grinding machine for grinding a surface of an object, the grinding machine having a. a plurality of grinding brushes (2), i. which are rotatably mounted about a brush axis of rotation, b. at least one brush carrier (4), i. on which at least one of the grinding brushes (2) is mounted and which ii. is rotatably mounted about a carrier axis of rotation (6), and c. a conveying device for conveying the object at a feed speed through the grinding machine, wherein the grinding machine has an input device and an output device, wherein a brush rotational speed about the brush axis of rotation and/or a carrier rotational speed about the carrier axis of rotation (6) and/or the feed speed is/are adjustable by the input device, and an expected grinding result can be output by the output device.

A machine for processing a screen printing frame includes an upstream end and an opposed downstream end, a grinding assembly located between the upstream and downstream locations, wherein the grinding assembly includes a first grinder configured to grind a first pattern into the screen printing frame and a second grinder configured to grind a second pattern into the screen printing frame different from the first grinding pattern.