There is provided a magnet separator that removes a magnetic body from a liquid to be treated, the magnet separator including a rotary drum in which a plurality of magnets are disposed, and a sprocket that is fixed to the rotary drum and transmits a driving force, in which the sprocket is formed by a plurality of sprocket split bodies having sprocket teeth.

The invention relates to a dental machine tool, in particular a dental milling machine (10), having a tool (12) that is changeable in particular via a tool bank (16), and a workpiece holder (14) for receiving a workpiece such as a dental blank made of ceramic, composite or plastics material such as PMMA, and having a housing (24) which is closable during machining by the machine tool, and having a negative-pressure connection to the housing (24). At least one air nozzle (30) that is fitted on or in the housing (24) is directed towards the workpiece and/or the workpiece holder (14) and/or the tool (12) and/or the tool bank (16) and/or a pane of a front flap of the machine tool. Said air nozzle (30) is equipped with at least one electrode for generating an electric field in the region of the nozzle or in front of the latter, and at least one nozzle comprising at least one electrode is directed towards that side of the workpiece or of the workpiece holder (14) on which the tool (12) machines the workpiece. At least two electrodes of an ionizer extend in a spaced-apart manner over a substantial part of the housing (24), and as a result of the application of an in particular pulsating AC voltage provides spatial deionization of the air flowing through the housing (24) and/or deionization of the surfaces of the workpiece, workpiece holder (14), tool (12) and/or window (28) and of the chips produced by the machining operation.

The invention relates to a dental machine tool, in particular a dental milling machine (10), having a tool (12) that is changeable in particular via a tool bank (16), and a workpiece holder (14) for receiving a workpiece such as a dental blank made of ceramic, composite or plastics material such as PMMA, and having a housing (24) which is closable during machining by the machine tool, and having a negative-pressure connection to the housing (24). At least one air nozzle (30) that is fitted on or in the housing (24) is directed towards the workpiece and/or the workpiece holder (14) and/or the tool (12) and/or the tool bank (16) and/or a pane of a front flap of the machine tool. Said air nozzle (30) is equipped with at least one electrode for generating an electric field in the region of the nozzle or in front of the latter, and at least one nozzle comprising at least one electrode is directed towards that side of the workpiece or of the workpiece holder (14) on which the tool (12) machines the workpiece. At least two electrodes of an ionizer extend in a spaced-apart manner over a substantial part of the housing (24), and as a result of the application of an in particular pulsating AC voltage provides spatial deionization of the air flowing through the housing (24) and/or deionization of the surfaces of the workpiece, workpiece holder (14), tool (12) and/or window (28) and of the chips produced by the machining operation.

An improved machining system for use in a CNC mill for the production of thin, hardened metal implement such as bed knifes includes a laminate mounting substrate with holes for receiving a pair of locator pins therein, at least one of the locator pins configured to displace longitudinally relative to the mounting substrate but not laterally which allows the system to accommodate a wide variety of metal implements. The system also includes magnetic cladding to protect the metal implement from metal chips being attracted by a magnetic element positioned beneath the mounting substrate to the finished product, allowing for higher quality cutting heads in the mill and a more efficient production of finished implements. A method of forming such implements is also provided.

The present invention relates to a transport device (100) for receiving one or more module units having machine tool accessory devices and for transporting the one or more received module units to a machine tool (1000) set up on a base surface for use of the machine tool accessory devices of the one or more received module units on the machine tool (1000), wherein the transport device (100) is freely movable on the base surface for positioning the one or more received module units relative to the machine tool (1000), in particular within a region in front and/or next to the machine tool (1000) and/or in front and/or next to a working space of the machine tool (1000).

A machine tool includes: an exterior cover covering a machining area where a workpiece on a worktable is machined by a machining tool; an articulated robot arranged inside the exterior cover and configured to replace the workpiece on the worktable; a controller configured to control a posture of the articulated robot and a coordinate point at which a hand of the articulated robot is positioned; and an air nozzle arranged inside the exterior cover and configured to remove scattered matter that has been generated during machining of the workpiece and has adhered at least to the hand when the articulated robot is set at a predetermined posture or when the hand is moved to a predetermined coordinate point.

A container assembly for retaining a drill byproduct produced when drilling into a wall, the container assembly includes a container disposed on an internal side of the wall having an internal surface and an external surface. The container assembly also includes a sleeve that is disposed about the external surface of the container, the sleeve includes one or more magnets that couple the sleeve and container to the wall and retain the drill byproduct along the internal surface.

A machine tool including a machining device configured to perform machining on a workpiece in a machining chamber, a chip conveyor including a reservoir tank into which machining chips generated by workpiece machining in the machining device flow, together with a coolant, the chip conveyor being configured to discharge the machining chips to an outside of the machine tool, a coolant tank in which the chip conveyor is incorporated, the coolant tank being configured to accumulate the coolant flowing out of the reservoir tank, a sub-tank provided to surround an outer side of a discharge window for the coolant, the discharge window being formed on a side surface of the reservoir tank, and a machining chip removal section in which a magnetic separator made of a magnet is accommodated in the sub-tank and an opening portion configured to filter the coolant is provided around the magnetic separator.

A magnet separator includes a separator body, a magnet drum and a driving portion. The magnet drum includes a first shaft, a cylinder provided inside the separator body, rotatably supported in the first shaft, an inner cylinder secured to the first shaft inside the cylinder, a magnet provided in the inner cylinder, and a second shaft rotating together with the cylinder. The separator body includes a pair of side walls. The driving portion includes an output portion provided on the outside the separator body. The second shaft penetrates one of the side walls toward outside of the separator body. The output portion is connected to the second shaft.

A device for welding profiled elements in plastic material includes: a base frame supporting retaining members of respective profiled elements, to engage the profiled elements with corresponding zones to be welded facing one another; a heater for heating the weld zones of the profiled elements; a unit to move the retaining members, to shift the profiled elements between a first reciprocal away direction and a second reciprocal closer direction wherein the zones to be welded are coupled together; and a removal unit utilizing milling The removal unit includes: a supporting frame positioned in correspondence to the retaining members; at least one machining tool; a motor part associated with the tool; and a movement member of the tool, to move it between a first idle condition and a second working condition wherein it is placed between the profiled elements.