DE20023809U1 - Thermal clamping and release of tools involves heating chuck in one workstation of shrinkage device, inserting/removing tool, cooling, heating chuck in separates second workstation - Google Patents

Abstract

The method involves heating the tool holding section of a first chuck in a first workstation (5-7) of a shrinkage device, inserting the tool shaft into the tool holder opening and/or removing a tool from it, actively cooling the tool holder section and heating the tool holder section of a second chuck in a second workstation of the shrinkage device separate from the first workstation. The method involves using a shrinkage chuck with a thermally expanding tool opening and a clamp section for clamping the chuck to the machine spindle. It involves heating the tool holding section of a first chuck in a first workstation (5-7) of a shrinkage device, inserting the tool shaft into the tool holder opening and/or removing a tool from it, actively cooling the tool holder section and heating the tool holder section of a second chuck in a second workstation of the shrinkage device separate from the first workstation. Independent claims are also included for the following: An arrangement for thermal clamping and release of tools in shrinkage chucks.

Description

The The invention relates to a device for thermal tensioning and Relaxing tools in shrink chucks.

The Shrinking technology is a known process for producing high speed Tools for the material-removing workpiece machining. In this case, so-called shrink chucks are used, which have a tool receiving section with an at least partially thermally expandable tool receiving opening for Recording a tool shank of a tool and a for Receiving the shrink chuck provided in a machine spindle Have clamping portion, for example, the manner of a hollow shaft cone or a steep cone can be formed. Typical diameter the shrunk, for example, as a drilling, milling or grinding tool trained tools can in the range of about 3 mm to 6 mm to about 30 mm to 40 mm. For the production of a tool at least a portion of the tool receiving portion warmed up so much that by thermal expansion, the tool receiving opening so greatly expands that the tool shank of a tool to be inserted is insertable. After insertion of the tool shank, the section is cooled in such a way that the tool is frictionally held in the tool receiving opening shrunk by the cooling. This creates tools almost as if in one piece, with the connection between the shrink chuck and the inserted tool at any time by shrinking is releasable again by the tool receiving portion warmed up so much is that the tool used from the thermally expanding Tool receiving opening is removable again. In this application is usually both the tool part to be used, e.g. a router, as well as by assembling of tool part and shrinkage chuck combination as Tool called.

It are shrinking machines known in which the warming the tool receiving section during shrinking and shrinking by means of hot air carried out becomes. By a fan equipped, separate Cooling unit can the cooling on one for the manual handling of the shrink fit suitable temperature be reduced to about 10 minutes. Such devices are economical available and especially for applications suitable in which only small numbers of shrink chucks to be handled per unit of time.

While that Shrinking and in particular the shrinking of carbide tools by means of Hot air devices due the different thermal expansion coefficients of tool material and shrinkage chuck material, as a rule is unproblematic, can For tools with HSS and steel shanks, especially when shrinking Problems occur because in this case the thermal expansion behavior of Tool material and lining material is similar and slower warming the tool shank in the expanding tool receiving opening also can zoom in so far that the tool continues through the expanding receiving opening is held and not removed or only by force can.

to Avoiding these problems it has already been suggested that Shrink chuck for thermal clamping and relaxation inductive too heat. The process of energy input by means of a shrink chuck surrounding induction coil can run so fast that a temperature increase Shrunken tools by heat conduction only in small Scope can take place. This allows in addition to the shrinking of carbide tools reliable also the shrinking out of tools that are essentially the same Thermal expansion behavior, like the material of the typical made of steel shrinkage lining.

One known, inductive shrinking device is designed as a desktop device and has a table-mounted, box-shaped housing, the top side the work surface of the device forms. About the working surface a pillar rises with vertical guides for one Coil holder on which an induction coil above the workstation attachable to the device is. An integrated pneumatic cylinder moves the column-guided air-cooled coil in working position downwards or back to the upper basic position. The predominantly interesting clamping range of 6 mm to 32 mm tool diameter is covered with three different coils, over one Quick-release interchangeable can be attached to the coil holder. The through the top of the housing formed work surface of the device is designed as a perforated plate through which one by means of a in the case arranged fan blown air stream from below through the work surface can be. On the work surface are in addition to the arranged below the coil workstation several circular, Bottom-blowing cooling stations educated.

To shrink a shrink chuck is inserted into a transportable chuck receiving sleeve, which is provided with radial cooling fins and when installed in the workstation from below can be flowed through with air. Then, the previously suitable selected induction coil for heating the Shrink chucks lowered to this and the inductive heating for shrinking or shrinking is performed. After insertion or removal of the tool, the coil is moved up again. Then the feed intake sleeve carrying the still hot shrink chuck is placed on one of the cooling stations. To accelerate the cooling, a separate cooling sleeve enclosing the tool receiving section can be fitted with cooling ribs. The vacated workstation below the induction coil can then be used to shrink the next feed.

The in the manner of a "Hütchenspiels" expiring handling of the device is already awkward been felt. In addition, it has been shown that the device for a faster throughput higher numbers is only partially suitable, because a slow warming of Complete system sets. It is already disadvantageous by operators felt that some still hot chucks are moved have to, to a higher one To be able to achieve throughput.

Of the Invention is based on the object, a device for thermal To create tension and relaxation of tools in shrinking chucks, a relaxed and fatigue-free working when shrinking, especially when processing larger quantities in continuous operation.

to solution this task strikes the invention a device with the features of claim 1 in front. Preferred developments are specified in the dependent claims. The wording of all claims is incorporated by reference into the content of the description.

at the possible with the device thermal clamping or relaxing of tools in shrink chucks takes place first a warming the tool receiving portion of a in a first workstation a shrinking device recorded first shrinkage food. Thereafter, when shrinking the tool shank a shrinkable tool inserted into the tool receiving opening or Shrinking will remove a shrunk tool. Also a tool part change, i. the removal of a tool part and immediately following the introduction another tool part, is possible with extended tool receiving opening. After that an active cooling takes place the heated tool receiving portion of the first shrinkage chuck in the first workstation. Farther will be a warming the tool receiving portion of a second shrinking chuck performed in a separate from the first workstation second workstation is included.

It So are several, i. provided at least two workstations, where both a heating of the tool receiving portion, as well as an active cooling be carried out the same can, with the cooling appropriate for so long takes a while for the tool receiving portion to manually handle the Shrinking suitable, harmless Temperature of e.g. has reached less than 40 ° C or 30 ° C. The provision of several, for example, two, three or four workstations allows one opposite known solutions significantly improved tool logistics as well as an improved, for one Operator much more pleasant handling, as it is synonymous with a desired, high tool throughput is no longer required, a still warm and therefore poorly manageable tool to take away from a workstation.

It is a largely parallel or only slightly time-delayed work with several shrink chucks possible, because the warming of the received in the second workstation shrinking chuck at least partially already during the cooling carried out in the first station recorded first shrinkage chuck can. As a result, particularly high throughput rates are possible. It can several shrinking cycles (heating, introduction and / or removal of a tool, cooling down to handling temperature) largely parallel or only slightly offset from each other and temporally overlapping each other carried out become.

in the Considering that usually the duration of a shrinking cycle much of the cooling time is determined, the cooling can accelerated by means of liquid cooling Be the most effective heat can dissipate from the tool receiving section. Anyone can do this Workstation on with coolant flow-through cooling adapter be assigned, after the end of the heating on the tool receiving portion with large-area touch contact aufstülpbar is and therefore the heat fast, e.g. within about a minute from the heated Pull off the tool holder section. Also useful is one of the workstation associated shrink chuck, in which the shrink chuck used for the clamping operation becomes, liquid-cooled, to a warming of the not for the clamping used parts of the shrink chuck and a heating of the to prevent the entire shrinking device in the workstation area.

Although any suitable manner of shrinkage lining heating is possible, for example by means of hot air, in preferred embodiments a provided inductive heating, which allows a particularly rapid heating of the tool receiving portion from the outside, thus facilitating in particular the shrinking of tools whose thermal expansion behavior substantially corresponds to that of the shrink chuck. Although a plurality of induction coils may be provided, preferably only a single induction coil is provided for operating all workstations, and for switching between workstations, the induction coil and the workstations may be moved relative to each other. In a preferred embodiment, three work stations are fixedly mounted on a circular arc and the induction coil is pivotally mounted about a vertical pivot axis in the center of the circular arc, so that they can be arranged by rotation above a workstation and lowered vertically to a shrink chuck in a working position to perform the shrinking process or after completion can be moved back to a basic position.

to Acceleration of individual shrinking cycles and to ensure that for any type of shrink chuck (large chuck diameter or smaller Clamping diameter) one for the heating suitable power can be transmitted inductively is in preferred embodiments by means of an automatic feed detection device of the type the heat-shrinkable chuck is automatically detected and the performance the induction coil is dependent adapted or controlled by the recognized type. For this purpose, the Operating voltage applied to the induction coil in each case from the lowest preset voltage gradually as long elevated, it can be seen from the current drawn by the generator that a sufficient heating power is provided.

Farther can be used to optimize the inductive heat input by means of a preferably mechanical, automatic positioning a automatic axial positioning of the induction coil during lowering be carried out on the respective shrinkage chuck. It is useful means an adjustable stop ensures that the lowering Induction coil at a height level continues, in which the electromagnetic alternating field generated by the induction coil optimally in the used for tool clamping portion of the tool receiving opening or of the shrinkage chuck.

Thereby becomes a largely automated process of shrinking possible, after over a control panel some parameters characterizing the shrinkage mating, For example, the diameter or diameter range and the material of the shrinking tool are entered. A microprocessor controlled Cycle can then be a motor lowering of the induction coil, from a home position in the direction of shrink chuck, a subsequent automatic Positioning to determine the correct axial position with respect to the shrink chuck, an automatic detection of the shrinkage chuck type over the from the shrink chuck withdrawn power, a corresponding preprogrammed Values for Heating time and performance performed automatic warming of the Shrink chucks and if necessary after insertion and / or removal of a Tool an automatic startup of the induction coil back to the basic position include. While In this automatic process, an operator can already have the next workstation for one Prepare shrinking process.

These and other features go out the claims also from the description and the drawings, wherein the individual features each for alone or in the form of subcombinations an embodiment of the Invention and other fields be realized and advantageous versions can represent.

One embodiment The invention is illustrated in the drawings and will be explained in more detail below. It demonstrate:

1 a diagonal perspective, schematic view of an embodiment of an inductive shrinking device with three workstations,

2 a perspective view of parts of a water-cooled shrink chuck receptacle for a workstation of 1 shown device together with a recordable therein shrink chuck,

3 a perspective view of parts of a workstation associated, water-cooled cooling adapter together with a cooled by the cooling adapter shrinkage chuck,

4 a vertical section through the induction coil unit of in 1 in a configuration suitable for heating shrinkage chucks for large diameter tools, and

5 a vertical section through the induction coil unit of in 1 shown device in a configuration that is suitable for the heating of shrink chucks for tools with small diameter.

In 1 is in oblique perspective, sche matic view of a device also referred to as shrinking device 1 shown for thermal clamping and relaxing tools in shrink chucks, which makes it possible to stretch in continuous operation, a large number of high-speed machining tools in a short sequence by means of shrink technology or relax, for example, to create a full-fledged workstation with high tool throughput. The embodiment shown comprises a closed base cabinet 2 , are housed in the later-described supply units for the shrinking device, such as a high-frequency generator for supplying an induction coil, a cooling unit of a water cooling device and equipped with a microprocessor electronic control unit for the shrinking device. On the approximately waist-high top of the cabinet is a substantially pie-shaped, closed base part 3 secured with a housing made of cast aluminum. The base has a control panel on its bevelled front 4 with a number of pushbuttons and an optical display for setting and displaying operating parameters that can be specified for the operation of the shrinking device. On the upper side of the base part are three working stations arranged side by side on a circular arc 5 . 6 . 7 provided, each for both an inductive heating of absorbed therein shrink chucks 8th . 9 , as well as for an active cooling of the heated shrink chuck are designed by means of a water cooling. For this purpose, each of the workstations has a liquid-cooled shrink-fit receptacle 10 . 11 . 12 on, whose construction is related to 2 will be explained in more detail. Each workstation is also a manually convenient, on a shrink chuck from above attachable cooling adapter 13 . 14 . 15 assigned, the belonging to the individual workstations cooling adapter are each parked from the operator's point of view in front of the associated workstation in a circular exit opening on the base part top. Structure and function of the cooling adapter are related to 3 explained in more detail.

From the operator's point behind the workstations, a pillar which is covered on all sides rises above the base part 16 , from the operator-facing front of an induction coil unit 17 with a water-cooled induction coil 18 ( 4 . 5 ) horizontally so protrudes that the vertical central axis 19 the coil with the circular arc 20 coincides with the vertical central axes of the workstations 5 . 6 . 7 combines. The pillar 16 is about a vertical column pivot axis 21 pivotally mounted and can by means of an outstanding on the front of the base part operating lever 22 be pivoted so that the induction coil 18 can be arranged either directly above or concentric with one of the workstations, with the help of a detent centered position after releasing the operating lever 22 self-adjusting.

The induction coil unit serving as a heating unit 17 is by means of a controllable by the control of the shrinking device, housed within the column housing electric motor 23 between the shown, upper basic position and one related later 4 and 5 explained in detail lower working position vertically (arrow 24 ) movable. This is one of the electric motor 23 driven, not shown spindle drive provided on the on a vertical guide rod 25 guided induction coil unit acts. The flexible liquid lines for water cooling of the induction coil and the electrical lines for connecting the coil with the bottom cabinet 2 housed generator are in a flexible cable tow 26 protected from the inside of the column through the base part to the base unit 2 leads.

In addition to the base part is on the upper working surface of the base cabinet within reach of the operator 2 a tilted about a vertical axis, tilted magazine ( 27 ) with sixteen receiving devices for receiving different sized interchangeable inserts 28 provided for the cooling adapter, its construction and function in connection with 3 is explained in more detail. A side drawer 30 can be used, for example, in connection with 2 explained in more detail interchangeable inserts 30 for the shrink chucks of the workstations 5 . 6 . 7 and / or other parts that may be required during shrinking, such as tools or the like.

Based on 2 now becomes a typical construction of a shrink chuck 8th explained in the shrinking device 1 is processable. A shrink chuck is usually made of a suitable steel material and has a frusto-conical tool receiving portion in the example 35 in which centrally a tool receiving opening or tool receiving bore 36 is introduced, which for receiving a tool shank of an insertable into the receiving bore tool (for example, tools 37 or 38 in 4 respectively. 5 ) is insertable. The clamping diameter of the tool receiving opening is expediently designed for a shank tolerance h6, in order to ensure trouble-free shrinking and shrinking of receiving shanks, which should also have a tolerance of h6 (center tolerance). The diameter of the tool receiving opening is dimensioned so that it is slightly smaller than the outer diameter of the clamped tool shank in the cold state of the shrink chuck, but upon warming the Werkzeugaufnah meabschnittes to temperatures of for example 200 ° to 300 ° so much expanded by thermal expansion that insertion of a (cold or cooler) tool shank is possible. The outer contour of the tool receiving portion is in the front mouth 40 The tapered portion of the tool receiving opening subsequent portion tapered with a cone angle of 4.5 °, however, wherein the diameter of the truncated cone portion may vary depending on the diameter of the male tool. Typical tool shank diameters range between about 6 mm and about 25 to 30 mm.

At the opposite end is a trained for receiving the shrinkage chuck in a machine spindle of a machining tool clamping section 39 provided, which is formed in the example as a hollow shaft cone, in other embodiments, but also as a steep taper or section with other, for example, cylindrical shapes and dimensions may be formed.

The shrinking device 1 is designed for a particularly effective cooling of such, possibly differently dimensioned shrink chuck. The integrated cooling device works with liquid coolant, usually water with additives, and serves both to cool the shrink chuck receptacles 10 to 12 , as well as the cooling adapter 13 to 15 and also the induction coil 18 in that these parts can be connected to an optionally closed coolant circuit. A liquid cooled shrink chuck ( 2 ) comprises a sleeve-shaped cooling outer part equipped with circulating coolant passages 45 placed in a circular receiving opening of the base part 3 can be used so that a circumferential collar 46 on top of the base section. The circulating in the sleeve wall coolant channels are over in 1 Dashed lines indicated coolant lines 47 For example, in the form of flexible hoses, to an in 1 schematically indicated water supply 48 connected. Made of good heat conducting metal, such as aluminum, cooling outer part 45 has at its top a downwardly funnel-shaped tapered, frusto-conical receiving opening 49 , in the interchangeable, also made of aluminum interchangeable inserts 30 can be used accurately.

A change insert 30 has a frusto-conical section 50 , the under-surface fit in the receiving opening 49 is insertable, as well as an outwardly projecting collar portion 51 with the insert inserted on top of the outer cooling part 45 rests and possibly fastened by screws on this. In exchange 30 is a downwardly tapered shrink chuck receiving opening 52 provided, the inner dimensions of the outer dimensions of the clamping section 39 are adapted so that these fit into the receiving opening 52 is insertable. Due to the large-area touch contact of the telescoping parts in the region of the conical seat surfaces is a good heat conduction between the actively cooled outer cooling part 45 and the chucking section 39 of the shrinkage lining possible. If shrink chucks are to be processed with another clamping section, for example, steep taper, then it is only necessary to change the insert 30 to replace it with another replacement insert whose shrinkage chuck receiving opening is adapted to the outer contours of the steep taper.

The cooling device also serves for the active water cooling of the cooling adapter provided for cooling the tool receiving portions of shrinking chucks ( 3 ). A cooling adapter has a substantially sleeve-shaped outer cooling part 55 , in the wall of which coolant channels extend, which extend over into 1 Dashed lines indicated coolant lines 56 in the form of flexible plastic hoses to the water supply 48 are connected. A downwardly conically widening receiving opening 57 inside the cooling outer part of the receptacle serves interchangeable interchangeable inserts 28 , which are insertable from below into the outer cooling part and have a generally conical outer surface, the surface with the two-dimensional contact against the inside of the receiving opening 57 can be pressed. At the upper end of the formed in the form of a slotted truncated cone exchange insert is a circumferential annular groove 58 provided in the case of inserted in the cooling outer part exchange insert on a cooling outer part 55 provided locking member engages, which by actuation of a provided on the outer circumference of the outer cooling part slide 59 for releasing the exchange insert from the outer cooling part is actuated.

In exchange 28 is a flared, conical receiving opening 60 formed, the cone angle of approximately 4.5 ° substantially corresponds to the cone angle of the tool receiving portion of the shrink chuck, to which the cooling adapter and the removable insert can be placed from above. Through the longitudinal slots arise at the interchangeable insert between the longitudinal slots six spring-elastic tongues 61 , which are firmly connected to each other in the region of the annular groove and have downwardly directed free ends, so that the enclosed by the spring tongues or limited receiving opening 60 slightly elastically expandable.

When inserting a replacement insert 28 in the cooling outer part engages the locking device and holds the changeover insert in the cooling exterior part, but a slight movement play is possible. If the cooling adapter is now placed on a shrinking chuck, then the still slightly movable sleeve initially slips over the tool receiving section until the insides of the tongues 61 over a large area on the outer cone surface of the tool receiving portion sit. Upon further lowering of the outer cooling part relative to the exchange insert the tongues 61 pressed in the manner of a chuck through the outer cooling part in firm contact with the shrink chuck, so that the cooling adapter is firmly seated on the shrink chuck and good heat conduction between the tool receiving portion and the actively cooled outer cooling part 45 by the existing good heat-conducting metal, such as aluminum exchangeable sleeve 28 consists. After cooling, the cooling adapter is lifted from the shrink chuck, initially the cooling outer part lifts slightly upwards from the replacement insert and thereby the spring tongues 61 Relieved from the external pressure, so that the receiving opening 60 can expand and a problem-free lifting of the cooling adapter from the shrink chuck is possible. Without this expedient expansion of the receiving opening 60 Due to self-locking, it could happen with the tapered tool receiving sections that a cooling adapter fitted with a flat fitting contact can not be pulled off the shrinkage chuck or only with the aid of larger tensile forces.

Based on 4 and 5 now becomes the induction coil unit 17 explained in more detail. This is in an existing electrically non-conductive material housing 65 housed a heater section designed to heat a single shrinkage chuck with a maximum outer diameter of about 53 mm. It essentially comprises the induction coil or the inductor 18 and a resonant circuit capacitor, which is over by the cable drag 26 Guided lines are connected to the accommodated in the cabinet high-frequency generator or to the water supply and together form a parallel resonant circuit. The inductor consists of a water-cooled coil 17 made of copper tube, which is coated with Trafolack for electrical insulation, has a clear inside diameter of about 65 mm and an axial coil length of about 50 mm. The inductor is screwed together with the water-cooled resonant circuit capacitor to form a unit, which is provided with a cooling water supply and return.

The sink 18 sits in a downwardly open interior of the housing 65 , which upwards by means of a removable cover plate 66 is completed, which is coaxial with the central axis 19 the coil is an upwardly conically widening tool opening 67 having. Below the upper housing cover 66 a flat slide protrudes 68 in the area above the induction coil 18 , The slider, which can be displaced perpendicularly to the coil axis, is made of electrically non-conductive material and has in the region of the coil axis 19 a stepped cylindrical receiving opening 69 , in the interchangeable discs 70 can be inserted. An insert disc 70 has a cylinder tube section 71 with an inner diameter which is slightly larger than the outer diameter of the largest tool to be clamped in and out and an outwardly projecting annular collar portion 72 with which the disc in the stepped cylindrical receiving opening 69 so rests that the top of the disc at the bottom of the top cover 66 is applied.

The flat slide 68 and the interchangeable disc carried by him 70 are essential elements of an automatic positioning, is ensured by fully mechanical means that regardless of the shrinkage chuck diameter Einspannabschnitt of the shrink chuck when lowering the induction unit in the direction of working position in an optimal axial position with respect to the induction coil, wherein in the optimal working position a mündungsnaher portion of the tool receiving portion is at the height of the axial coil center or the mouth end side 73 of the shrink chuck is slightly above the coil center. This is achieved by mechanical stop of the muzzle end of a shrink chuck to serving as a stop disc 70 guaranteed. This is done by means of the slider 68 for large diameter tools ( 4 ) placed in a central position, so that the tool receiving opening surrounding the end face of the shrink chuck ring to the underside of the cylinder portion 71 the stopper disc 70 meets. If, on the other hand, the shrinkage chuck diameter is in the region of the mouth end face 73 smaller than the inside diameter of the stopper disc 70 , so in the centric position of the stop plate, the shrink chuck would partially penetrate from below into the stop plate and thus are higher in relation to the induction coil than in the optimal working position. Therefore, with smaller diameter shrink chucks, the stopper disk becomes 70 by means of the slider 68 in the in 5 shown eccentric position shifted so that only a part of the ring section of the disc 70 serves as an axial stop for the shrink chuck.

The stop disc 70 is suitably made of an electrically non-conductive, heat-resistant and shock-absorbing material, for example, an asbestos-free, bonded by rubber and special resin friction material without Metallbeimischung, as it is also suitable for brake and clutch linings. The metal-free material also does not affect the field profile of the alternating electromagnetic field generated by the coil enced.

In cases where it is desired to influence the induction field profile, for example, shrinkage of HSS or steel tools having a shank diameter of less than 16 mm, instead of the non-conductive disk 70 Also, an induction field influencing, consisting of electrically conductive and / or magnetizable material element, for example, ferrite, are used, which performs the function of a field concentrator to concentrate the inductively introduced heating power to the tool receiving portion of the shrink chuck.

The in the cabinet 2 housed, designed for a fixed power of 8 kW at working frequencies up to about 60 kHz, water-cooled high-frequency generator has input side a line filter and works in the power section with a rectifier and a subsequent inverter, both of which are water cooled, the cooling water flow through a flow funnel and the Temperature of the parts to be monitored with a temperature monitor. Between the power unit and the generator output, a fan-cooled ferrite core transformer is provided. The electronic control of the generator connected to the control panel elements comprises a microprocessor which also takes over all the control functions of the shrinking device. Operation is via control buttons on the control panel 4 , whereby the functions set with the keys are shown on the display. The control unit stores various preset program sequences which include the optimum device settings for shrinking or shrinking at various tool and chuck diameters. A post-heating function which can be initiated, for example, by pressing a key briefly twice can be used, if required, to reheat again for a period of, for example, 2 to 4 seconds, in order, for example, to expand a chuck for the removal of a tool.

The Generator control allows automatic detection of the type a reaching into the effective range of the induction coil shrink chuck and one dependent on it automatic adjustment of the generator operation such that a optimal coupling of the inductive heating energy into the shrink chuck given is. For this purpose, it is provided that the generator electronics with several, for example, two or three different, fixed preset Output voltages can work. This will make it possible for that for all in the intended diameter range occurring feed diameter or tool diameter worked with a single induction coil can be. An inductor change is dispensable. The Electronic recognizes in response to a corresponding coupling between inductor and shrink chuck, whether a chuck diameter below a given diameter in the inductor and causes possibly a fully automatic switching to a higher output voltage, with which the power can be raised again to the rated power. This automatic adjustment makes shrinking and shrinking of smaller feed diameters considerably faster and is special advantageous for the shrinking of steel tools with smaller diameters.

With the aid of the described multi-station shrinking apparatus, large numbers of tools can be clamped or unclamped in continuous operation, with typical cycle times of between about one-half and one minute being achievable per shrinking operation. This can be done as follows. First, a shrink chuck, such as shrink chuck 8th , in one with a suitably adapted exchange insert 30 provided shrink lining intake 10 a workstation 5 used from above. Before or after the coil-carrying column 16 with the help of the operating lever 22 pivoted and locked so that the induction coil sits in top home position on the shrink chuck. Subsequently, over appropriate keys of the control panel 4 the type of material to be clamped tool (eg HSS or carbide) and the associated tool diameter or diameter range (eg less than a diameter limit or greater than a diameter limit) entered. Depending on this input, the slider 68 the positioning automatically adjusted so that the stop disc 70 either centric to the coil axis (for large diameters, 4 ) or eccentric to the spool axis (for small tool or shrinkage chuck diameters, 5 ) is arranged.

After pressing a start button, the induction unit lowers 17 , via the electric motor 23 driven, on the shrinking lining to be heated, until the stop disk 70 on the muzzle front 73 the shrink chuck is seated, whereby the lowering drive is automatically switched off. Then automatically starts the heating operation, in which the induction coil is first supplied with electricity at the lowest of the preset voltage levels and fixed frequency. The power absorbed by the shrink chuck is monitored by the generator current. If the tapped power is below a threshold, then automatically switched to the next higher voltage until an output voltage is reached, which ensures optimum power reduction. The heating process is in this way typically three to six Seconds so far advanced that through the tool opening 67 and the stop ring 70 a tool is insertable into the thermally extended tool receiving aperture of the shrink chuck. As soon as the tool is inserted, the heating process is automatically stopped and the induction coil automatically returns to the upper home position.

Throughout the heating process, the shrink-fit chuck firmly seated in the water-cooled shrink-fit chuck remains essentially at the shrink-chuck temperature typically between 15 ° C and 20 ° C. For rapid cooling of the conical tool receiving portion of the flexible hose lines at the end 56 attached and thus limited freely movable cooling adapter 13 placed by hand on the shrink chuck, wherein the slotted inner sleeve is pressed by the relative to this movable outer cooling part to improve the heat transfer between the cooling adapter and shrink chuck firmly on the tool receiving portion.

Now while the finished tool in the first workstation 5 cools down to a temperature suitable for manual handling of the shrink-fit temperature water-cooled, can already in the adjacent second workstation 6 a corresponding shrinking process is initiated and carried out. If differently dimensioned shrink chucks and / or cooling adapters are required, these parts can be adapted to the shape of the shrink chuck to be processed by appropriately replacing the interchangeable inserts. Since the inductive heating of the shrink chuck accommodated in the second work station is feasible while the chuck received in the first work station cools down, shrinking cycles (heating, tool insertion, cooling) can be performed overlapping each other in this shrinking device, but in no case hot shrink chuck must be moved by the operator. It is thus created a very user-friendly and ergonomically designed shrinking workstation, the parts of which do not heat up in continuous operation at high tool throughput, since all coming in heat conduction contact with the shrink chucks parts are water cooled. It is only a single induction coil 18 for all shrinkage diameters in the range of, for example, between 6 mm and 25 mm to about 32 mm diameter necessary, this coil can be brought by pivoting of the induction tower in each case to the next workstation, so that a movement of hot shrink chuck is not required.

An unrepresented shrinking device with a simpler structure dispenses with the motorized vertical displacement of the induction coil unit. Instead, a forwardly projecting handle connected to the induction coil unit is provided on which there is a pushbutton acting on a holding device with which the induction coil unit can be mounted at any desired height of the vertical guide 25 can be clamped. When pressing the button, the coil unit is released for vertical displacement and stops when the button is released in the set height position. By a coupled to the induction coil unit via a roller-guided rope counterweight a slight vertical displacement without special effort is possible. It is also possible to provide, instead of the three work stations shown, more than three or less than three, for example two or even one workstation. For simple devices, it may also be possible to dispense with water cooling of the shrinkage chuck of a workstation. If fast cooling down times are not required, it may be possible to apply the entire cooling unit associated with the workstations, including the cooling adapters 13 . 14 . 15 be waived.

It is also possible, instead of the described integrated cooling device to provide a separate cooling device, in which, for example, possibly equipped with a cooling unit water supply 48 is housed in a separate housing, wherein one or more cooling adapters of the type described by means of flexible hose lines o. The like. Are connected to the water supply. Such a separate cooling device can be placed next to a shrinking device without cooling device to cool quickly and effectively using the easily manageable, liquid-cooled cooling adapter by means of the shrinking device inductively or otherwise, for example by means of hot air, heated shrink chuck. To the separate cooling device may optionally be attachable to any shrinking device, water-cooled shrink chuck receptacles, as they are based on the 1 and 2 described here by way of example.

Claims (35)

Apparatus for thermally tensioning and relaxing tools in shrink chucks, wherein a shrink chuck has a tool receiving portion with a at least partially thermally expandable tool receiving opening for receiving a tool shank and a provided for receiving the shrink chuck in a machine spindle clamping section, wherein the device at least one heating device for heating at least one Part of the tool receiving section and a cooling comprising means for actively cooling the heated part of the tool receiving section, characterized in that a first workstation ( 5 ) and at least one second workstation ( 6 . 7 ) is provided for heating and active cooling of shrink chucks, that the workstations and the heating device for changing between workstations are movable relative to each other, and that each workstation ( 5 . 6 . 7 ) a cooling adapter ( 13 . 14 . 15 ) for active cooling of the tool receiving section of a in the workstation ( 5 . 6 . 7 ) is associated with absorbed shrinkage chuck. Apparatus according to claim 1, characterized in that the cooling adapter ( 13 . 14 . 15 ) are coolable by means of a cooling liquid. Apparatus according to claim 1 or 2, characterized in that the cooling adapter ( 13 . 14 . 15 ) by means of flexible lines ( 56 ) are connected to a coolant circuit. Device according to one of claims 1 to 3, characterized in that each workstation ( 5 . 6 . 7 ) a cooled by a coolant shrinkage feed intake ( 10 . 11 . 12 ) with a shrink-receiving opening ( 52 ) for the positionally secure reception of a shrinkage chuck. Device according to one of the preceding claims, characterized in that a cooling adapter and / or a shrink chuck receptacle by replacement interchangeable inserts ( 28 . 30 ) are adaptable to shrink chucks of different dimensions. Device according to one of the preceding claims, characterized in that a cooling adapter ( 13 . 14 . 15 ) a, preferably conical, receiving opening ( 60 ), which is adapted to the, preferably conical, outer contour of the tool receiving portion such that the cooling adapter can be applied to the tool receiving portion with large-area contact contact, in particular on the shrink chuck ( 8th ) is axially mounted. Apparatus according to claim 6, characterized in that the receiving opening ( 60 ) is expandable to relax the contact between the shrinkage chuck and the cooling adapter, wherein preferably a plurality of circumferentially spaced around the circumference of the receiving opening, resilient elements ( 61 ) are provided, which the receiving opening ( 60 ) limit. Device according to one of the preceding claims, characterized in that a cooling adapter ( 13 . 14 . 15 ) several interchangeable inserts ( 28 ) with differently dimensioned receiving openings ( 60 ) attached to a coolable part ( 55 ) of the cooling adapter are preferably attachable without tools, preferably a removable insert ( 58 ) is formed in the manner of a slotted sleeve, the at least two with circumferential spacing around the circumference of the receiving opening ( 60 ) distributed resilient tongues ( 61 ) having the receiving opening ( 60 ) limit. Device according to one of the preceding claims, characterized in that a cooling adapter ( 13 . 14 . 15 ) one with an expandable receiving opening ( 60 ) ( 28 ) which is opposite to a coolable cooling adapter body ( 55 ) is limited movable between a contact position and a release position, wherein pressed in the contact position of the insert with surface contact pressure on the shrink chuck and in the release position, the shrink chuck can be released under extension of the receiving opening from the cooling adapter. Device according to one of the preceding claims, characterized characterized in that the cooling device a cooling unit for cooling the cooling liquid having. Device according to one of the preceding claims, characterized characterized in that the cooling device having a closed coolant circuit. Device according to one of the preceding claims, characterized characterized in that the cooling device as a separate cooling device in a separate housing is housed Device according to one of the preceding claims, characterized in that the heating device as an induction device with at least one induction coil ( 18 ) for inductive heating of the tool receiving portion ( 35 ) is trained. Device according to one of the preceding claims, characterized in that the heating device only one induction coil ( 18 ) having. Device according to one of the preceding claims, characterized in that the workstations ( 5 . 6 . 7 ) stationary and the induction coil ( 18 ) is movable between workstations. Device according to claim 15, characterized in that the induction coil ( 18 ) about a preferably vertical pivot axis ( 21 ) is pivotable. Device according to one of the preceding claims, characterized in that more than two and preferably less than five, in particular three workstations ( 5 . 6 . 7 ) are provided. Device according to one of the preceding claims, characterized in that the heating device comprises a liquid-cooled induction coil ( 18 ), wherein the induction coil is preferably formed substantially by a flow-through with coolant tube, in particular of copper. Device according to one of the preceding claims, characterized in that it comprises an automatic positioning device for positionally correct positioning of the heating device, in particular the induction coil ( 18 ), with respect to differently dimensioned shrink chucks, wherein the positioning device preferably at least one of the heating device associated, depending on the dimensions of the shrink chuck adjustable stop element ( 70 ) for limiting movement of the heating device in the working position. Device according to claim 19, characterized in that the positioning device comprises a lock slider ( 68 ), which transversely, in particular perpendicular to a running between the basic position and working position of the heating device movement direction ( 24 ) of the heating device is movable, wherein the locking slide is preferably for supporting interchangeable stop elements ( 70 ) is trained. Device according to claim 19 or 20, characterized in that the positioning device is dependent on at least one the shrinkage chuck and / or the tool characterizing, preferably manually inputable parameter is controllable, in particular depending on Diameter of the tool to be clamped. Device according to one of the preceding claims, characterized by a feed recognition device for the automatic recognition of the type of shrinkage chuck to be heated, wherein preferably a power control for the heating device ( 18 ) is controllable in response to a feed detection signal of the forage detection device characteristic of the shrinkage chuck. Device according to one of the preceding claims, characterized by a field concentration device for the targeted concentration of the induction coil ( 18 ) are applied to a region of a shrinkage chuck, wherein the field concentration device is preferably interchangeable and can be used depending on the type of shrinkage chuck to be heated. Device according to claim 23, characterized in that the field concentration device comprises at least one exchangeable element of magnetisable material, in particular ferrite, the element preferably comprising a stop element ( 70 ) has corresponding shape. Apparatus for thermally tensioning and relaxing tools in shrink chucks, wherein a shrink chuck has a tool receiving portion with a at least partially thermally expandable tool receiving opening for receiving a tool shank and a provided for receiving the shrink chuck in a machine spindle clamping section, wherein the device at least one heating device for heating at least one Part of the tool receiving portion and a cooling device for actively cooling the heated portion of the tool receiving portion, characterized in that a first workstation ( 5 ) and at least one second workstation ( 6 . 7 ) is provided for heating and active cooling of shrink chucks, that the workstations and the heating device for changing between workstations are movable relative to each other, and that the cooling means is designed for active cooling of the heated part of the tool receiving portion by means of a cooling liquid. Device according to claim 25, characterized in that each work station ( 5 . 6 . 7 ) a cooling adapter ( 13 . 14 . 15 ) for active cooling of the tool receiving section of a in the workstation ( 5 . 6 . 7 ) is associated with absorbed shrinkage chuck, wherein the cooling adapter ( 13 . 14 . 15 ) are coolable by means of the cooling liquid. Device according to claim 25 or 26, characterized in that the cooling adapters ( 13 . 14 . 15 ) by means of flexible lines ( 56 ) are connected to a coolant circuit. Device according to one of claims 25 to 27, characterized in that each work station ( 5 . 6 . 7 ) a coolable by means of the cooling liquid shrinkage feed intake ( 10 . 11 . 12 ) with a shrink chuck receiving opening ( 52 ) for the positionally secure reception of a shrinkage chuck. Device according to one of claims 25 to 28, characterized in that a cooling adapter and / or a shrink chuck receptacle by replacement interchangeable removable inserts ( 28 . 30 ) on shrinkage chucks of different dimensions are customizable. Device according to one of claims 25 to 29, characterized that the cooling device a cooling unit for cooling the cooling liquid having. Device according to one of claims 25 to 30, characterized that the cooling device a closed coolant circuit having. Device according to one of claims 25 to 31, characterized that the cooling device as a separate cooling device in a separate housing is housed Device according to one of claims 25 to 32, characterized in that the heating device as an induction device with at least one induction coil ( 18 ) for inductive heating of the tool receiving portion ( 35 ) is trained. Apparatus according to claim 33, characterized in that the heating device only one induction coil ( 18 ) having. Apparatus according to claim 34, characterized in that the workstations ( 5 . 6 . 7 ) stationary and the induction coil ( 18 ) is movable between workstations.