Shrink-fitting device for clamping and unclamping tools that have a tool shank, having a tool receptacle which has a sleeve part that is open at its free end and is made of electrically conductive material, for receiving the tool shank in a frictional manner, and having an induction coil that encloses the sleeve part of the tool receptacle, is able to be subjected to a high-frequency alternating current and is configured as a ring coil or a cylindrical coil, for heating the sleeve part, wherein the induction coil bears, on its outer circumference, a first casing made of magnetically conductive and electrically non-conductive material, and the device comprises power semiconductor components for producing an alternating current feeding the induction coil, and an induction coil housing that preferably consists of insulating material, wherein the induction coil and its first casing are surrounded at the outer circumference by a second casing which consists of magnetically non-conductive material and electrically conductive material and is designed such that a stray field that occurs in the vicinity thereof generates eddy currents in the second casing and as a result the stray field is weakened, and in that at least the power semiconductor components are accommodated together with the induction coil in an induction coil housing which encloses the induction coil, the first and second casing thereof, and the power semiconductor components, at least around the circumference of the induction coil.

Shrink-fitting device for clamping and unclamping tools that have a tool shank, having a tool receptacle which has a sleeve part that is open at its free end and is made of electrically conductive material, for receiving the tool shank in a frictional manner, and having an induction coil that encloses the sleeve part of the tool receptacle, is able to be subjected to a high-frequency alternating current and is configured as a ring coil or a cylindrical coil, for heating the sleeve part, wherein the induction coil bears, on its outer circumference, a first casing made of magnetically conductive and electrically non-conductive material, and the device comprises power semiconductor components for producing an alternating current feeding the induction coil, and an induction coil housing that preferably consists of insulating material, wherein the induction coil and its first casing are surrounded at the outer circumference by a second casing which consists of magnetically non-conductive material and electrically conductive material and is designed such that a stray field that occurs in the vicinity thereof generates eddy currents in the second casing and as a result the stray field is weakened, and in that at least the power semiconductor components are accommodated together with the induction coil in an induction coil housing which encloses the induction coil, the first and second casing thereof, and the power semiconductor components, at least around the circumference of the induction coil.

A blank for a conduit arrangement includes an annular conduit having a first end and a second end, which is formed by a channel surrounded by a wall. The conduit arrangement has an axis of rotation and the conduit extends in a circumferential direction over an angle of more than 360 degrees about the axis of rotation and forms at least one wind turn. The axis of rotation is arranged perpendicularly to a base surface, the wall having first surfaces which are arranged at a first angle of at least 30 degrees relative to the base surface or in which a surface normal forms at least one second angle of 0 to 60 degrees with respect to the base surface. First partial surfaces of the walls, which face one another in an axial direction, of adjacent turns are arranged spaced apart from one another. The blank is produced by an additive manufacturing process.

An induction heating device for a shrink-clamping and/or unshrink-unclamping of tools into and/or out of a tool holder, includes: an induction heating unit comprising one induction coil configured, in a shrink-clamping and/or unshrink-unclamping process, to heat-expand a portion of a tool holder arranged in a receiving region of the induction heating unit; magnetic flux conducting unit comprising one magnetic flux conducting element for conduction of magnetic flux generated by the induction coil; and a bearing unit configured for a movable support of the magnetic flux conducting element, wherein a large portion of all points of the magnetic flux conducting element each have a respective movement path predetermined partially by the bearing unit, wherein each of the movement paths has an essential movement component oriented perpendicularly to a radial direction of the receiving region and at the same time perpendicularly to an axial direction of the receiving region.

An induction heating device for a shrink-clamping and/or unshrink-unclamping of tools into and/or out of a tool holder, includes: an induction heating unit comprising one induction coil configured, in a shrink-clamping and/or unshrink-unclamping process, to heat-expand a portion of a tool holder arranged in a receiving region of the induction heating unit; magnetic flux conducting unit comprising one magnetic flux conducting element for conduction of magnetic flux generated by the induction coil; and a bearing unit configured for a movable support of the magnetic flux conducting element, wherein a large portion of all points of the magnetic flux conducting element each have a respective movement path predetermined partially by the bearing unit, wherein each of the movement paths has an essential movement component oriented perpendicularly to a radial direction of the receiving region and at the same time perpendicularly to an axial direction of the receiving region.

An induction heating system for molding a thermoplastic article includes a first mold and a second mold defining a mold cavity therebetween for molding the thermoplastic article, a first metallic susceptor as part of or adjacent to the first mold, a first armature-supported induction coil array in proximity to the first metallic susceptor, and a first induction generator electrically coupled with the first armature-supported induction coil array.

An induction heating system for molding a thermoplastic article includes a first mold and a second mold defining a mold cavity therebetween for molding the thermoplastic article, a first metallic susceptor as part of or adjacent to the first mold, a first armature-supported induction coil array in proximity to the first metallic susceptor, and a first induction generator electrically coupled with the first armature-supported induction coil array.

An induction coil assembly includes an annular member extending from a first end to a second end, and extending about a longitudinal axis; a first leg extending from the first end of the annular member, and including a first electrical connection portion and a first axial portion; and a second leg extending from the second end of the annular member, and including a second electrical connection portion and a second axial portion. An internal surface of the annular member defines a first fluid passage through the annular member. An internal surface of the first leg defines a second fluid passage through the first leg. An internal surface of the second leg defines a third fluid passage through the second leg. The second fluid passage is in fluid communication with the third fluid passage via the first fluid passage.

An induction coil assembly includes an annular member extending from a first end to a second end, and extending about a longitudinal axis; a first leg extending from the first end of the annular member, and including a first electrical connection portion and a first axial portion; and a second leg extending from the second end of the annular member, and including a second electrical connection portion and a second axial portion. An internal surface of the annular member defines a first fluid passage through the annular member. An internal surface of the first leg defines a second fluid passage through the first leg. An internal surface of the second leg defines a third fluid passage through the second leg. The second fluid passage is in fluid communication with the third fluid passage via the first fluid passage.

An induction heater is proposed for melting paraffin deposits formed in borehole columns filled with borehole liquid. The heater includes an inductor joined essentially with a control module enclosing electronic components. The inductor includes a non-metallic protective cover enclosing particularly an induction coil heating up a heating rod with a tip that melts paraffin deposits. The protective cover provides free propagation of HF-magnetic field created by the coil, which also heats up the column's walls melting paraffin thereon. An internal cavity is formed particularly by surfaces of the protective cover, tip, induction coil, etc., and communicates with an elastic compensator. The cavity is filled with liquid filler allowing the inductor to withstand high pressure of the borehole liquid. Surplus of the filler formed in the cavity due to volumetric temperature expansion flows essentially into the compensator. Embodiments envisage regulating the heater's temperature, and operating the inductor at a resonance frequency.