DE10348880A1 - Method for inductive heating of shrink fit tool holder has the end of the tool sleeve fitted with a non magnetic insulating disc to limit thermal losses - Google Patents

Abstract

A method for inductive heating of a tool holder sleeve (5) to grip and release tool shafts (11) via a shrink fit process has the induction coil (19) radially spaced from the sleeve and with an outer cladding (23) of magnetic non conducting material to form a concentrator for the induced fields. A concentrator ring is also positioned around the tool shaft and is separated from the end of the sleeve by a disc (33) of non magnetic insulating material. The disc can be of ceramic or of any suitable material and prevents thermal losses from the sleeve to the concentrator.

Description

The The invention relates to a device for inductive heating of a a centric receiving opening for one Shaft of a rotary tool, such as a drill or Cutter or Frictional tool containing sleeve portion of a Tool holder, which fits the seated in the receiving shaft of the Tool holds in a press fit and when heated releases.

Especially for with high speed rotating tools it is known whose shaft in a sleeve section Shrink a tool holder. The sleeve portion is for this purpose, for example by means of a surrounding him Induction coil heated, so that the tool shank can penetrate into the heat-expanding, i.e. enlarged receiving opening of sleeve section can be inserted. The outer diameter of the tool shank is slightly larger than the nominal diameter of the receiving opening, so that the tool after cooling of the sleeve portion in a press fit rotatably held in the tool holder.

For this purpose, suitable inductive heating devices are, for example DE 101 02 710 A1 and DE 101 57 432 A1 known. These devices have an insertable on the sleeve portion of the tool holder and in this case at a radial distance annularly enclosing induction coil, which is fed from a generator with alternating electrical current. The magnetic field of the induction coil induced in the electrically conductive, usually also magnetizable material of the tool holder induction currents that heat the sleeve portion directly. The induction coil extends axially at least over the engagement length, with which the tool shank dips into the receiving opening and closes with its winding approximately in the region of the tool-side end face of the sleeve portion axially with this. In the radial direction, the inner circumference of the induction coil extends at a distance from the sleeve section in order to be able to use one and the same induction coil in tool holders with different outer diameters of the sleeve section.

At its end faces and at its outer circumference, the winding of the induction coil is encased with a flux concentrator arrangement of a magnetizable, ie ferromagnetic or ferrimagnetic material whose high magnetic conductivity, based on air, substantially concentrates the magnetic flux on this cladding. The magnetizable material of the flux concentrator assembly is electrically non-conductive to prevent the flux concentrator jacket from being inductively heated. The region of the flux concentrator jacket adjacent to the tool-side end of the sleeve section is designed as a ring element which rests axially directly on the tool-side front end of the sleeve section. The ring element may be, for example, a shield collar, as it is in DE 101 02 710 A1 or around an annular disc extending radially over the end face of the winding of the induction coil in the manner of a pole piece to the outer periphery of the induction coil out, as for example in DE 101 57 432 A1 is described.

at usual Induction devices is made of magnetizable material existing flux concentrator jacket to avoid air gaps, which increase the magnetic resistance of the magnetic flux circuit, directly at the front end of the sleeve section the tool holder on. Since the sleeve section at Ein- and Shrinking the tool holder heated to several 100 ° C, can it is more conventional in continuous operation Devices to damage on the relatively sensitive magnetizable material of the flux concentrator shell come.

Especially to easily unclamp the rotary tool from the tool holder to be able to it is important that the sleeve section over his axial length is heated sufficiently. It has been shown that in conventional induction devices directly resting on the front end of the sleeve portion Flux concentrator coat heat derives and accordingly the thermal expansion of the front end insufficient can be. The result is that the shaft of the rotary tool to be set clamped in the tool holder and the clamping is difficult.

at usual Induction devices will be the induction coil relative to the Tool holder by means of the at the front end of the sleeve portion axially positioned flux concentrator overlying. The flux concentrator jacket usually exists from brittle Ferrite material, the careless putting on the front end of the sleeve section splinter or break.

It The object of the invention is a device for inductive heating of a To create tool holder that better than before for continuous operation suitable is.

The invention is based on a device for inductive heating of a central receiving opening for a shaft of a rotary movement containing tube portion of a tool holder which holds the seated in the receiving shaft of the tool in a press fit and releases when heated. Such an apparatus comprises an induction coil arrangement with at least one induction coil which can be fed with electrical current of periodically changing intensity for heating the sleeve section and with a flux concentrator arrangement comprising a magnetizable, electrically substantially non-conductive material which concentrates the magnetic flux of the induction coil on the region of the tool-side end of the sleeve section wherein the flux concentrator arrangement has a bearing surface, with which it can be applied in a defined axial position relative to the tool holder on this in the region of the tool-side end of the sleeve portion.

The The above object is achieved by the fact that the flux concentrator arrangement a contact element forming the contact surface made of an electrically non-conductive, non-magnetizable material includes.

at such a device runs the contour of the flux concentrator arrangement in the region of the and shrinking the tool from the toolholder relevant, Tool-side front end of the sleeve section Completely at a distance from this tool-side front end and is through the preferably acting as a thermal insulation contact element against heat conduction or / and heat radiation protected. In this way, the Flußkonzentratoranordnung can also thermally less resilient and thus more cost-effective material getting produced. Also, clamping problems when relaxing the Tool shank avoided because the abutment element heat dissipation in Area of the tool-side end of the sleeve portion obstructed. There the contact element not from the magnetizable material of the Flußkonzentratoranordnung There may be targeted material with better mechanical properties be used. The contact element thus acts as a mechanical Protection buffer for the magnetizable material of the flux concentrator assembly. Surprisingly has been shown that the magnetic flux despite the by the contact element conditional distance between the tool-side end of the sleeve portion on the one hand and the flux concentrator arrangement on the other hand sufficient be selectively supplied to the tool-side end of the sleeve portion can.

The Investment element is preferably made of ceramic, but is more temperature resistant Plastic also suitable. The thermal conductivity of the material of the contact element is preferred less than that of the magnetizable material of the flux concentrator assembly.

From Another advantage is that the contact element for the axial positioning the Flußkonzentratoranordnung used relative to the tool holder can be, what for the reproducibility of the shrinking process is important. Conveniently, in this case comprises the Flußkonzentratoranordnung a with the induction coil to a unit connected ring element of the magnetizable Material and is over the abutment element on the tool-side end of the sleeve portion of the Tool holder can be supported. The contact element can in this case at the frontal peripheral edge or also optionally on the mostly conical peripheral shell of the sleeve portion supported the tool holder be. However, the contact surface of the contact element is preferably at one tool-side, axial end face of the sleeve portion of the tool holder applied.

Of the Magnetic flux of the flux concentrator arrangement may be in the range of Forehead of the sleeve section the tool holder are introduced both axially and radially. Thus, the Flußkonzentratoranordnung with an end face on the axial overlap radially on the tool-side end of the sleeve section, wherein the abutment element in the overlap region between the Flußkonzentratoranordnung and the end face extends into and with its contact surface abuts the end face. Alternatively, the contour of the flux concentrator arrangement in the area the tool-side end of the sleeve portion extend also with a radial distance from the peripheral surface of the sleeve portion, wherein Here too, the contact element with its contact surface on an end face on the axial, tool-side end of the sleeve section is applied. In the latter embodiment, the contact element is radially inward over the inner periphery of the Flußkonzentratoranordnung ago. In both embodiments can be used as an investment element a simple annular disc.

The flux concentrator arrangement expediently comprises the tool-side end of the sleeve section adjacent a ring element of the magnetizable material, which is connected to the contact element to form a unit. This facilitates the placement of the induction coil forming a structural unit together with the flux concentrator arrangement on the tool holder. The ring element including the contact element are preferably operatively interchangeable connected to the induction coil in order to adapt the induction coil assembly in a simple manner to different sized tool holder can. The unit of ring element and contact element can be screwed; However, easier to handle are bar connections, such as bayonet connections or the like. In a variant, however, it can also be provided that the contact element with the In production coil is connected to a unit, while the magnetizable material existing ring element in turn is operatively interchangeable attached to the unit, such as the contact element.

The induction coil surrounds the sleeve portion of the tool holder preferably concentrically, wherein the magnetic flux of the induction coil on the region of the tool-side end of the sleeve portion concentrating region of Flußkonzentratoranordnung is designed as a ring member, in particular annular disc or ring sleeve which with the tool-side end of the sleeve portion radially and / or axially overlaps. Arrangements of this type are relatively easy to manufacture. It is understood, however, that other induction coil types can also be used, for example arrangements with a plurality of partial coils arranged around the sleeve section of the tool holder, the magnetic flux of which is guided by means of the flux concentrator arrangement to the tool holder, as described, for example, in US Pat DE 202 03 784 U1 are described. It is further understood that the ring elements, insofar as they have been explained above, need not necessarily be formed as closed rings, segmented rings are also suitable.

in the The invention will be explained in more detail with reference to a drawing. Hereby shows:

1 a Axiallängsschnitt by an inventive device for inductive heating of a tool holder with a disc-shaped pole piece on the tool-side end of the tool holder;

2 a Axiallängsschnitt by a variant of the device according to 1 ;

3 a Axiallängsschnitt by another device according to the invention for inductive heating of a tool holder with a Abschirmkragen on the tool-side end of the tool holder and

4 a Axiallängsschnitt by a variant of the device according to 3 ,

1 shows a one-piece here, but possibly also multi-part tool holder 1 from an at least electrically conductive, but also magnetizable material, such as steel, at its one axial end a standard connector, such as a steep taper 3 , and at its axially other end a sleeve portion 5 having. The sleeve section 5 contains centric to the axis of rotation 7 of the tool holder 1 a receiving opening 9 for one with his shaft 11 in the receiving opening 9 in the manner explained in more detail below, not otherwise shown rotary tool, such as a drill, a milling cutter or a reaming tool. The outer diameter of the shaft 11 is slightly larger than the free nominal diameter of the receiving opening 9 so that the shaft 11 inserted into the sleeve section 5 held for the transmission of the working torque in a press fit.

To the tool shank 11 in the tool holder 1 insert or remove from this, the sleeve approach 5 widened by heating. The heating takes place by means of a sleeve approach 5 patch and this with a radial distance of its inner diameter from the outer circumference of the sleeve portion 5 concentrically enclosing induction coil 13 , which by means of a 15 indicated holder of an induction shrinking device axially parallel to the axis of rotation 7 slidably held and from a power generator 17 is supplied with alternating current or pulsed direct current of a frequency of, for example, 10 to 50 kHz. The one of an approximately cylindrical winding 19 generated magnetic flux induced in the sleeve portion 5 Eddy currents that the sleeve section 5 warm up in a relatively short time and thus the receiving opening 9 for insertion or withdrawal of the tool shank 11 sufficiently widening.

The induction coil 13 has inside a made of temperature-resistant plastic or ceramic bobbin 21 on which the four-ply winding 19 is applied. The outer circumference and the tool axially facing away from the end face of the winding 19 is with a multipart yoke shell 23 covered by a magnetizable, electrically non-conductive material, which serves as a flux concentrator and the magnetic flux in the surrounding area of the winding 19 on the yoke cup 23 concentrated. The yoke cup 23 may be made of ferromagnetic material or magnetic composites based on ceramics or plastics, such as ferrite.

The with the yoke cup 23 provided winding 19 extends substantially over the entire for receiving the tool shank 11 certain length of the receiving opening 9 or the sleeve section 5 , With its the tool-side end face 25 of the sleeve section 5 adjacent winding extends the winding 19 axially up to about the height of the front side 25 of the sleeve section 5 ,

The yoke cup 23 includes the outer jacket of the winding 19 with a sleeve-shaped man telabschnitt 27 on the ring-shaped pole shoes 29 respectively. 31 connect the axial faces of the winding 19 radially overlap. The tool-side end face 25 of the sleeve approach 5 adjacent pole piece 29 extends to the sleeve section 5 zoom in and overlap with its face 25 radial. Axial between the face 25 and the pole piece 29 is in the overlap area an annular disc-shaped contact element 33 arranged, which on the pole piece 29 is attached and with his the pole piece 29 axially facing surface 35 at the frontal area 25 of the sleeve section 5 rests. The investment element 33 is made of ceramic or a temperature-resistant plastic and has poorer heat-conducting properties than the material of the pole piece 29 , The investment element 33 isolated with the pole piece 29 thermally opposite to the sleeve section heated during operation to temperatures of several 100 ° C 5 ,

The pole piece 29 conducts the magnetic flux of the winding 19 in the area of the face 25 in the sleeve section 5 , To be with one and the same winding 19 toolholder 1 to heat with different radial dimensions, is the pole piece 29 including the thermally insulating support member held thereon 33 operationally replaceable on the induction coil 13 attached. After loosening the screws 37 can the pole piece 29 change. It is understood that other fastening organs can be used. For example, the pole piece 29 be attached to the unit with a bayonet lock.

The following are variants of the basis of the 1 described device described. Equivalent components are identified by the reference numerals of 1 and provided with a letter for distinction. For an explanation of the construction and the operation, reference is made to the preceding description.

In the embodiment of 1 overlaps the tool-side end face 25 of the sleeve section 5 adjacent pole piece 29 of the yoke mantle 23 the face 25 in the radial direction. In the variant of 2 overlaps the tool-side end face 25a adjacent pole piece 29a of the yoke mantle 23a the annular conical circumferential coat 39 of the sleeve section 5a at least over part of its axial thickness in the axial direction. In this way, that of the pole piece 29a concentrated magnetic flux wholly or at least partially on the circumference of the sleeve portion 5a initiated in these. The turn ring-shaped, thermally insulating, ceramic or temperature-resistant plastic existing investment element 33a extends the interior of the pole piece 29a radially inward and lies with its contact surface 35 again on the face 25a of the sleeve section 5a for positioning the induction coil 13a on.

In the embodiment of the 3 is the basis of the 1 and 2 explained, ring-shaped pole piece by an approximately conical shell-shaped Abschirmkragen 29b replaces the magnetic flux on this page slightly above the winding 19b axially projecting yoke shell 23b optimally to the front side 25b of the sleeve section 5b directs and at the same time over the sleeve section 5b projecting part of the tool shank 11b shields and protects against inductive heating. The shield collar 29b runs on all sides at a distance from the yoke shell 23b , which in the illustrated embodiment does not have the tool-side end face of the winding 19b extends, but only slightly protrudes beyond this end face. The tool-side end face of the winding 19b is in the illustrated embodiment with a non-magnetic material, such as temperature-resistant plastic or ceramic spacer disc 41 covered. In a variant of this, in turn, with its inner circumference at a distance to the Abschirmkragen 29b ending disc 41 also from the magnetizable material of the yoke shell 23 exist, so part of the yoke shell 23b be. Details of such a Abschirmkragens are for example in DE 101 02 710 A1 described.

The shield collar 29b overlaps the end face with its smaller diameter end 25b of the sleeve section 5b radially and lies with a on the Abschirmkragen 29b attached, annular disc-shaped contact element 33b made of ceramic or temperature-resistant plastic on the face 25b at. The contact surface of the contact element 33b is at 35b indicated.

The shield collar 29b is in turn on a temperature-resistant disc 43 made of ceramic or plastic and together with this disc 43 and the contact element 33b operationally replaceable for adaptation to different dimensions of the tool holder 1b at the induction coil 13b attached. Instead of the fixing screws 37b can in turn here be provided other locking members, for example in the form of a bayonet connection. It is also understood that the disc 43 operationally fixed with the induction coil 13b may be connected, so that only the Abschirmkragen 29b including the contact element 33b can be replaced operationally. In the embodiment of 3 is the spacer element 33b on the shield collar 29b attached, for example, glued. at 45 is indicated that the contact element 33b also with the disc 43 can be connected to a unit, for example, can be made integral with this disc, so that the attachment of the shield collar 29b facilitating, trough-shaped seat arises.

4 shows a variant of the device 3 , Similar to the variant of 2 overlaps the shield collar 29c the cone-shaped outer shell 39c of the sleeve section 5c in one to the face 25c of the sleeve section 5c immediately adjacent area in the radial direction. The shield collar 29c directs the in conjunction with the yoke jacket 23c concentrated magnetic flux radially in the end portion of the sleeve portion 5 one. Again, the shield collar overlaps 29c the tool-side end face of the winding 19c Not. On the inner circumference of the Abschirmkragens 29c is again an annular disk-shaped contact element 33c attached. The investment element 33c consists of ceramic or temperature-resistant plastic and lies with its contact surface 35c at the frontal area 25c of the sleeve section 5c at. The element 33c on the one hand positions the induction coil 13c relative to the tool holder 1c and isolates the shielding collar 29c thermally opposite the sleeve section heating during operation 5c , Again, the shield collar 29c operationally interchangeable, as indicated by the 3 was explained.

Claims (13)

Device for inductive heating of a centric receiving opening ( 9 ) for a shaft ( 11 ) of a rotary tool containing sleeve section ( 5 ) of a tool holder ( 1 ), which in the receiving opening ( 9 ) seated shaft ( 11 ) of the tool ( 1 ) and releasing on heating, comprising: an induction coil assembly ( 13 ) with at least one for the heating of the sleeve section ( 5 ) with electric current periodically changing strength feedable induction coil ( 19 ) and with a magnetic flux of the induction coil ( 19 ) on the area of the tool-side end of the sleeve section ( 5 ) concentrating flux concentrator arrangement ( 23 ) of a magnetizable, electrically substantially non-conductive material, wherein the flux concentrator arrangement ( 23 ) a contact surface ( 35 ) in which it is in a defined axial position relative to the tool holder ( 1 ) at this in the region of the tool-side end of the sleeve section ( 5 ), characterized in that the flux concentrator arrangement ( 23 ) the contact surface ( 35 ) forming investment element ( 33 ) carries an electrically non-conductive, non-magnetizable material. Apparatus according to claim 1, characterized in that the flux concentrator arrangement ( 23 ) with the induction coil ( 19 ) connected to a unit ring element ( 29 ) of the magnetizable material and via the contact element ( 33 ) at the tool-side end of the sleeve section ( 5 ) of the tool holder ( 1 ) is supportable. Apparatus according to claim 2, characterized in that the contact surface ( 35 ) of the contact element ( 33 ) to a tool-side end face ( 25 ) of the sleeve section ( 5 ) of the tool holder ( 1 ) can be applied. Apparatus according to claim 1 to 3, characterized in that the flux concentrator arrangement ( 23 ) an end face ( 25 ) at the axial tool-side end of the sleeve portion ( 5 ) of the tool holder ( 1 ) radially overlaps and the contact element ( 33 ) into the overlap region between the flux concentrator assembly ( 23 ) and the face ( 25 ) and with its contact surface ( 35 ) at the end face ( 25 ) is present. Device according to one of claims 1 to 3, characterized in that the contour of the flux concentrator arrangement ( 23a ; 23c ) in the region of the tool-side end of the sleeve section ( 5a ; 5c ) of the tool holder ( 1a ; 1c ) with a radial distance to the peripheral surface ( 39 ; 39c ) of the sleeve section ( 5a ; 5c ), and that the abutment element ( 33a ; 33c ) with its contact surface ( 35a ; 35c ) on an end face ( 25a ; 25c ) at the axial tool-side end of the sleeve portion ( 5a ; 5c ) is present. Apparatus according to claim 4 or 5, characterized in that the contact element ( 33 ) is designed as an annular disc. Device according to one of claims 4 to 6, characterized in that the flux concentrator arrangement ( 23 ) the tool-side end of the sleeve section ( 5 ) adjacent a ring element ( 29 ) comprises of the magnetizable material, which with the contact element ( 33 ) is connected to a unit. Device according to claim 7, characterized in that the ring element ( 29 ) including the contact element ( 33 ) operationally interchangeable with the induction coil ( 19 ) connected is. Apparatus according to claim 7, characterized in that the contact element ( 33 ) with the induction coil ( 19 ) is connected to a unit and the ring element ( 29 ) is operationally interchangeable with the unit. Device according to one of claims 1 to 9, characterized in that the induction coil ( 19 ) the sleeve section ( 5 ) concentrically encloses and that the magnetic flux of the induction coil ( 19 ) on the area of the tool side End of the sleeve section ( 5 ) concentrating portion of the flux concentrator assembly ( 23 ) as a ring element ( 29 ), in particular annular disc or annular sleeve, is formed, which with the tool-side end of the sleeve portion ( 5 ) radially or / and axially overlapped. Apparatus according to claim 10, characterized in that the ring element ( 29 ) is segmented in the circumferential direction. Device according to one of claims 1 to 11, characterized in that the contact element ( 33 ) made of plastic or ceramic. Device according to one of claims 1 to 12, characterized in that the contact element ( 33 ) consists of thermally insulating material, in particular a material whose thermal conductivity is lower than that of the magnetizable material of the flux concentrator arrangement ( 23 ).