AT4934U1 - CALIBER PLATE WITH AN INSERT FOR A MOLDING DEVICE - Google Patents

Abstract

The invention relates to a caliber plate (17) for a shaping device, with end faces (30, 31) spaced apart from one another, between which at least one opening (24) with shaped surfaces (25) extends for the passage of an extruded object. A recessed receiving opening (27) is arranged in the caliber plate (17), in which at least one wear-resistant insert part (28) with a holding part (33) is inserted. Boundary surfaces (29) of the receiving opening (27) and outer surfaces (35) of the holding part (33) form a guide arrangement (36) at least in some areas. Over a large part of a circumferential area, limiting stops (37, 38) with stop faces (39, 40) for the guide arrangement (36) interacting both in the area of the receiving opening (27) and on the holding part (33).

Description

       

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  The invention relates to a caliber plate with an insert part held therein for a shaping device, as described in claim 1.



  From DE 19806202 CI and EP 0 936 053 AI, short calibers for a cooling and calibration device have become known which comprise a caliber plate and at least one profile cross-section recess arranged therein and at least one calibration body which partially protrudes into the profile cross-section recess. The object to be calibrated, in particular the hollow plastic profile, is pulled through the cross-sectional recess. At least one locking recess is made in the caliber plate from the profile cross-section recess, into which the calibration body with its locking body can be inserted.

   The locking body in turn comprises the locking foot body and a calibration body connected to it, a bolt receiving recess being made in the locking foot body. Furthermore, a slot recess is provided in the locking body. To hold the locking body, it is to be inserted into the locking recess of the caliber plate and to be fixed on the caliber plate by means of a conical locking bolt element by introducing it into the bolt receiving recess. The disadvantage here is that the individual parts have to be manufactured with high manufacturing accuracy in order to achieve a perfect position fixation on the caliber plate, whereby an independent loosening of the connection could not be reliably prevented in all applications.



  Another caliber plate for the tank of an extrusion die is from AT 003 321 U 1
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 which essentially corresponds in shape to the profile of the profile strand, is introduced in order to guide the profile strand as it passes through the strand and to keep it in shape. Wear-resistant inserts are provided on the circumference of the through-hole in the caliber plate at points along which the profile strand slides, which are made by means of a press fit

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 Adhesive or soldered connections or screw connections are held in the caliber plate. The disadvantage here is that the individual inserts can only be attached to the caliber plate with a great deal of work and, if they are worn out, can be exchanged for new inserts with a lot of work.



  A caliber plate composed of several individual parts has become known from US Pat. No. 5,626,807 A, in which individual parts of the caliber plate, in particular those for forming groove-shaped sections of the plastic profile, are held and fixed between the individual plate segments.



  The present invention has for its object to provide a secure and positionally accurate mounting of an insert in a caliber plate, which is simple and inexpensive to manufacture and can be replaced quickly.



  This object of the invention is achieved by the features of claim 1.



  The surprising advantage resulting from the features of the characterizing part of claim 1 is that both the insert part, in particular its holding part and the receiving opening associated with the holding part, are delimited with enveloping surfaces which are preferably oriented perpendicularly to the end faces or parallel to the direction of extrusion or extending are which are simple and inexpensive to manufacture. At the same time, this also creates an exact guide arrangement for the insert part in the caliber plate, which ensures an exact alignment of the insert part in its insert position with respect to the caliber plate and thus also to the object to be passed through.

   A limitation of the displacement movement is achieved by means of the limiting stops with stop faces for the guide arrangement, which are arranged and interacting over a large part of the circumferential area both in the area of the receiving opening and on the holding part, and in addition also a support and, associated therewith, a transmission of force from that applied to the insert part Object applied force is achieved on the caliber plate. The interacting stop surfaces are easy to manufacture and can ensure sufficient power transmission.



  Another embodiment according to claim 2 is also advantageous, since the almost right-angled alignment of the stop surfaces to the guide arrangement for the insertion

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 a precisely predefined position of the insert in relation to the caliber plate can be achieved.



  Furthermore, an embodiment according to claim 3 is advantageous since, depending on the choice of the angle of inclination of the interacting stop surfaces, simple releasability up to self-locking of the insert part in its working position in the caliber plate can be achieved.



  Due to the design according to claim 4, it is possible, on the one hand, to define the limit stop and thus the exact position of the insert part with respect to the caliber plate, and on the other hand to dispense with further additional limit stops, due to the conical configuration of the boundary surfaces and the outer surfaces.



  According to another embodiment variant, the exact stop position and a sufficient and safe power transmission between the insert part and the caliber plate are achieved.



  A further development according to claim 6 is also advantageous because the manufacturing outlay for the formation of the receiving opening can thereby be kept low and, in the case of an insert part formed from sintered metal, the limit stop can be produced simply and inexpensively in terms of shape.



  In the embodiment according to claim 7, it is advantageous that the wear-resistant insert also has sufficient strength in this area to be able to transmit the forces transmitted from the object to the insert onto the caliber plate.



  The development according to claim 8 ensures that limit stops which can be produced simply and inexpensively can be formed both in the region of the receiving opening and in the region of the insert.



  Due to the design according to claim 9, in addition to the support in the area of the shaped surface of the opening, a support acting transversely to the direction of extrusion on the object and associated alignment of the profile geometry of the object can also take place.



  An embodiment according to claim 10 is also advantageous, since in the area of the gap transversely to the extrusion direction, supporting forces acting on the insert part, in particular on the guide part, can be safely transmitted.

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  According to an embodiment as described in claim 11, inexpensive manufacture for the through hole is achieved.



  In this case, an embodiment according to claim 12 proves to be advantageous, since a force acting from the receiving opening in the direction of the breakthrough and thus a tilting moment can also be supported on the caliber plate.



  According to an advantageous further development according to claim 13, an exact parallel guidance and associated exact positioning of the insert part transverse to the extrusion direction is achieved.



  However, an embodiment according to claim 14 is also advantageous, since in this way supporting forces of the guide part can also be transmitted to the caliber plate in the vertical direction to the shaped surfaces.



  According to claim 15, a uniform power transmission from the insert part is achieved in the caliber plate.



  In the embodiment according to claim 16, an additional possibility of supporting the insert part against lifting off from the receiving opening in the direction of the opening is created.



  An embodiment according to claim 17 is also possible, since this ensures a simple possibility of replacement and, associated therewith, a high repeatability of the positioning of the insert in the receiving opening.



  The embodiment according to claim 18 enables an additional form fit to be achieved during the insertion movement up to the final positioning between the insert part and the receiving opening.



  An embodiment according to claim 19 or 20 is also advantageous, since the positioning accuracy and the height or the extent of the supporting forces to be transmitted can be easily determined by the number of selected ribs.



  However, designs according to claims 21 to 23 are also advantageous, since as the insertion movement progresses, the material of the caliber plate or the ribs are deformed into the material of the caliber plate, and so on

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 additional counter surfaces for supporting and fixing the insert part in relation to the caliber plate are created.



  Another embodiment according to claim 24 or 25 is also advantageous, since as a result a supporting force or contact force acting on the boundary surface of the receiving opening is applied by the insert part to the caliber plate during the insertion process.



  Furthermore, an embodiment according to claim 26 is also advantageous, since the material of the caliber plate that is displaced during the deformation process can be displaced into the region of the recess of the insert part, thereby avoiding an early termination of the insertion process. Likewise, the counter surfaces provided for contact with the rib surfaces are enlarged.



  The configuration according to claim 27 makes it possible to compensate for tolerances in the region of the gap between the guide part and the caliber plate.



  According to another embodiment variant, the limit stop is achieved by the cooperating rib surfaces with the depressions molded into the receiving opening, as a result of which additional projections or projections can be avoided.



  In the embodiment according to claim 29, it is advantageous that an exact guide arrangement can be created between the holding part or insert part and the caliber plate.



  The further development according to claim 30 creates simple handling and interchangeability of the insert.



  However, an embodiment according to claims 31 to 33 is also advantageous, since a protrusion of the insert part over one of the two end faces of the caliber plate is avoided and, if the individual caliber plates lie on top of one another or are stacked, on the one hand an unwanted loosening of the insert part and on the other hand a destruction of the Surface of the end faces is avoided.



  In the embodiment according to claim 34, it is advantageous that certain tolerances in the design of the insert part and the receiving opening in the caliber plate can be worked with, since the permanent plastic deformation ensures the tight fit and, if necessary, the positive connection associated therewith in all cases.

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  Finally, however, a training as described in claim 35 is also possible, since an exact alignment and simple manufacturing possibility of both the insert part and the receiving opening in the caliber plate can be created.



  The invention is explained in more detail below with reference to the exemplary embodiments shown in the drawings.



  1 shows an extrusion system with a caliber plate according to the invention in the region of the
Shaping device in side view and much more simplified, schematic
Presentation ; 2 shows a possible design of the caliber plate with insert parts in a simplified, perspective and enlarged representation; 3 shows the insert part and the caliber plate before assembly in a side view, partly in section and enlarged, schematically simplified representation; 4 shows the insert part in a view according to arrow IV in FIG. 3; 5 shows the receiving opening in the caliber plate in a view according to arrow V in FIG. 3; 6 shows another embodiment of an insert part in a view according to arrow VI in FIG. 7 and in a simplified, schematic representation; 7 shows the insert part according to FIG. 6 in a side view;

   Fig. 8, the associated receiving opening in the caliber plate in a view according to arrow VIII in
Fig. 9; 9 shows the caliber plate in a side view, cut along lines IX-IX in FIG. 8; 10 shows a further embodiment of an insert part in a view according to arrow X in FIG. 11; 11 shows the insert part according to FIG. 10 in a side view;

   12 shows the corresponding receiving opening for the insert part according to FIGS. 10 and 11 in
View according to arrow XII in Fig. 13;

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 Fig. 13, the receiving opening in the caliber plate in side view, cut according to the
Lines XIII-XIII in Fig. 12; 14 shows another embodiment of an insert part in a view according to arrow XIV in FIG. 15; 15 shows the insert part according to FIG. 14 in a side view; 16 shows a further embodiment of an insert part in a view according to arrow XVI in FIG. 17; 17 shows the insert part according to FIG. 16 in a side view; 18 shows a further embodiment of an insert part in a top view and a simplified representation; 19 shows the insert part according to FIG. 18 in a side view;

   20 shows the insert part according to FIGS. 18 and 19 in a state inserted into the receiving opening in the caliber plate, partially in section; Fig. 21 shows a portion of the caliber plate with an insert and part of the
Object with different versions of the guide part in a view and a simplified, schematic representation.



  In the introduction, it should be noted that in the differently described embodiments, the same parts are provided with the same reference numerals or the same component names, and the disclosures contained in the entire description can be applied analogously to the same parts with the same reference numerals or the same component names.



  The location information selected in the description, such as. B. top, bottom, side, etc. related to the figure immediately described and shown and are to be transferred to the new position in case of a change of position. Furthermore, individual features or combinations of features from the different exemplary embodiments shown and described can also represent independent, inventive or inventive solutions.



  1 shows an extrusion system 1 which consists of an extruder 2, a
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 for example, a profile, in particular a hollow profile made of plastic for window and / or door construction, in the extrusion direction 6, starting from the extruder 2, through the entire shaping device 3. In this exemplary embodiment, the shaping device 3 consists of an extrusion tool 7 assigned to the extruder 2, a calibration device 8 of at least one, but preferably a plurality of calibration tools 9 to 13 and at least one, but preferably a plurality of vacuum tanks 14 to 16, in which a plurality of caliber plates 17 are arranged.

   However, individual ones of the caliber plates 17 can also be designed only for the support function as support panels for the object 5.



  In the area of the extruder 2 there is a receptacle 18 in which a material, such as a mixture or a granulate for forming a plastic, is stored, which is fed to the extrusion tool 7 with at least one screw conveyor in the extruder 2. Furthermore, the extruder 2 also comprises a plasticizing unit, by means of which the material is heated and plasticized according to the properties inherent therein under pressure and, if appropriate, supply of heat, and is conveyed and conveyed in the direction of the extrusion die 7 as the material passes through it by means of the screw conveyor and, if appropriate, additional heating devices , Before entering the extrusion die 7, the mass flow from the plasticized material is led in transition zones to the desired profile cross section.



  The extrusion tool 7, the plasticizing unit and the receptacle 18 are supported or held on a machine bed 19, the machine bed 19 being set up on a flat contact surface 20, such as a flat hall floor.



  In this exemplary embodiment, the entire calibration device 8 is arranged or held on a calibration table 21, the calibration table 21 being supported on rollers 22 on a running rail 23 fastened on the contact surface 20. This mounting of the calibration table 21 on the rollers 22 on the rails 23 serves to be able to move the entire calibration table 21 with the devices or devices arranged thereon in the direction of extrusion 6 from or towards the extrusion tool 7 according to the arrow entered.

   In order to be able to carry out this adjustment movement more easily and more precisely, the calibration table 21 is assigned, for example, a traversing drive (not shown in any more detail) which enables a targeted and controlled longitudinal movement of the calibration table 21 towards the extruder 2 or away from the extruder 2

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 allows. Any solutions and units known from the prior art can be used to drive and control this traversing drive.



  The calibration tools 9 to 13 of the calibration device 8 are supported on a mounting plate and are designed, for example, as a vacuum calibration, the calibration of the extruded object 5 taking place within the individual shaping or calibration tools 9 to 13. In addition, the arrangement of the vacuum slots, the cooling sections and the flow channels or cooling bores as well as their connections and supply can take place according to the known prior art.



  This calibration can include, for example, a combination of dry and wet calibration or only a complete dry calibration. Furthermore, access to ambient air can be completely prevented at least between the extrusion tool 7 and the first calibration tool 9 and / or at least between the first calibration tool 9 and further calibration tools 10 to 13. Of course, it is also possible, at least in regions, to allow access of ambient air to the object 5 between the individual calibration tools 9 to 13 or to arrange water baths.



  The vacuum tank 14 to 16 has at least one cooling chamber for the object 5 emerging from the calibration tools 9 to 13, which is formed by a simplified housing and is divided into immediately successive areas by the caliber plates 17 arranged and shown in the interior in a simplified manner. However, it is also possible to lower the interior of the cooling chamber to a lower pressure than the atmospheric air pressure.



  After leaving the extrusion tool 7, the object 5 has a cross-sectional shape predetermined by this, which is sufficiently calibrated and / or cooled in the adjoining calibration tools 9 to 13 until the viscous object 5 has cooled on the surface or edge areas thereof to such an extent that its outer shape is stable and its dimensions are designed accordingly. Subsequent to the calibration tools 9 to 13, the object 5 passes through the vacuum tanks 14 to 16 in order to achieve further cooling and, if necessary, calibration and support and thus to dissipate the residual heat still contained in the object 5.

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  For the operation of the extrusion system 1, in particular the inlet or outlet element arranged or held on the calibration table 21. Devices can be connected to a supply device (not shown in more detail) with which the most diverse units can be acted upon, for example with a liquid cooling medium, with electrical energy, with compressed air and with a vacuum. A wide variety of energy sources can be freely selected and used as required.



  In order to lead the object 5 through the individual caliber plates 17, these have at least one opening 24, with individual shaped surfaces 25 of the opening 24 delimiting or delimiting an outer profile cross section 26 of the object 5 to be passed through, at least in regions. As already described above, the object 5 is cooled as it passes through the individual calibration tools 9 to 13 in the area of its outer walls and the softened plastic material is solidified to such an extent that the outer profile sections of the hollow profile already have a certain inherent rigidity or strength.

   In order to be able to completely remove the residual heat still present in the profile interior, in particular in the area of the hollow chambers and the webs arranged therein, the vacuum tanks 14 to 16 with the caliber plates 17 arranged therein are provided in this exemplary embodiment. During this further cooling and solidification process, due to the different heat dissipation seen across the cross section, internal stresses build up in the area of the profile cross section, as a result of which the object 5 is to be guided at predeterminable locations in its cross section in such a way that the required dimensional accuracy, in particular in the area of connection masses, sealing grooves, etc. can be achieved with sufficient accuracy. Here occur in the area of such leadership or

   Contact points starting from the object 5 on the caliber plate 17 to high pressure and frictional forces, as a result of which increased wear occurs at these predeterminable points and, as a result, an increasingly greater dimensional deviation occurs.



  2 shows a perspective, simplified and enlarged illustration of the caliber plate 17 with the opening 24 and the shaping surfaces 25 bordering it, for the sake of simplicity the cross-sectional shape of the opening 24 has been chosen only as an example for a large number of possible profile cross sections. This profile cross section shown here is approximately T-shaped, recessed openings 27 being arranged in the caliber plate 17 in the region of the profile web lying transversely here, in which at least one

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 wear-resistant insert 28 inserted therein is inserted. This wear-resistant insert part 28 serves to guide the object 5 over a longer period of time in the area of highly stressed places with corresponding accuracy.

   For this purpose, the wear-resistant insert parts 28 are selected from a material different from the caliber plates 17, such as, for example, high-strength tool steels, sintered metals, ceramics, sintered ceramics, high-strength plastics or other high-strength materials with a high resistance to abrasion. It is essential here that the material of the insert parts 28 over a longer period of time counteracts the high loads during the cooling and calibration process with a sufficiently high resistance to abrasion, absorption of the pressure load, and permanent retention in the reception openings 27 of the caliber plate 17.



  In this simplified representation, in the area of the opening 24 shown on the right, the insert part 28 is shown in a position before insertion into the receiving opening 27, wherein it can be seen here that the receiving opening 27 is arranged in the caliber plate 17 in a recessed manner relative to the shaping surface 25 and thus extending from the molding surface 25 in the direction facing away from the opening 24. The receiving opening 27 is delimited by a plurality of boundary surfaces 29 which extend between the end faces 30, 31 delimiting the caliber plate 17 in the direction perpendicular thereto. Some of these boundary surfaces 29 can also run parallel to one another.

   The receiving opening 27 preferably extends between the two end faces 30, 31 over a thickness 32 of the caliber plate 17. This makes it possible to precisely measure the boundary surfaces 29 of the receiving opening 27 in a simple and inexpensive manufacturing process, such as for example by drilling, milling or an eroding process form the caliber plate 17. In this exemplary embodiment, the insert part 28, shown here in simplified form, comprises a holding part 33 to be inserted into the receiving opening 27 and at least one guide part 34 projecting into the opening 24, it being advantageous to form the insert part 28 in one piece.



  The holding part 33 also has at least one outer surface 35 facing the boundary surface 29, the boundary surface 29 of the receiving opening 27 forming a guide arrangement 36 with the outer surface 35 of the holding part 33 at least in regions. Is preferred
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 Longitudinal displacement and thus a relative movement between the insert 28 and the caliber plate 17 is possible. This longitudinal movement serves to be able to insert the insert part 28, in particular the holding part 33, into the receiving opening 27.

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  In the left part of the opening 24, the insert part 28 is shown in a position inserted into the receiving opening 27, the position fixing or positioning and holding of the insert part in the receiving opening 27 being explained in detail in the following figures in the most varied of exemplary embodiments.



  It is essential in all of these exemplary embodiments that over a large part of a circumferential area, in the area of the receiving opening 27 as well as on the holding part 33 of the insert part 28, interacting limit stops 37, 38 with stop surfaces 39, 40 for fixing the position and thus limiting the displaceability of the guide arrangement 36 are provided. The individual insert parts 28, in particular the holding part 33, are pushed into the receiving opening 27 and, starting from the first end face 30 along the boundary face 29, are pushed in in the direction of the further end face 31 of the caliber plate 17.

   This longitudinal movement continues until the cooperating limit stops 37, 38 with their stop surfaces 39, 40 come to bear against one another and the longitudinal movement in the extrusion direction 6 is thereby prevented.



  The interacting limit stops 37, 38 serve to absorb the forces acting on the insert part 28 from the object 5 to be passed through and to prevent the insert part 28 from coming out of the receiving opening 27 during the intended operation. These forces are transmitted from the object 5 by its movement in the extrusion direction 6 in the same direction to the insert part 28. If one of these insert parts 28 is damaged or worn, it is to be removed from the receiving opening 27 against the extrusion direction 6 by means of a compressive force in cooperation with the guide arrangement 36 and a new, unused insert part 28 is to be inserted into the receiving opening 27 as described above.



  To fix the position, it can also be advantageous if a slight to strong press fit is selected between the boundary surfaces 29 of the receiving opening 27 and the outer surfaces 35 of the insert part 28, since in cooperation with the limit stops 37, 38 for low forces in the extrusion direction 6 sufficient position fixing or positioning of the insert part 28 against displacement in a direction transverse to the extrusion direction 6 relative to the caliber plate 17 can take place.
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 Opening 27 and the holding part 33 are shown schematically simplified on an enlarged scale, the same reference numerals being used for the same parts as in the previous FIGS. 1 and 2.



  In this exemplary embodiment shown here, the two stop surfaces 39, 40 of the limit stops 37, 38 are inclined to the end surfaces 30, 31, in particular in the direction of the second end surface 31, tapering. The stop surface 39 is arranged on the caliber plate 17 of the first end surface 30 in the extrusion direction 6 and z. B. in the form of a countersink.



  In this exemplary embodiment, the receiving opening 27 is formed by a through hole 42 arranged at a distance from the shaped surface 25 of the opening 24 and a gap 43 connecting the through hole 42 to the shaped surface 25. The through hole 42 is preferably formed by a bore which can be produced using a wide variety of manufacturing methods. Of course, the through-hole 42 can have any cross-sectional shape, this being freely selectable depending on the application and geometric conditions. The cross section of the through hole 42 can be in the form of an ellipse, a polygon or polygon, and can be formed by any combination of different surface shapes.

   For reasons of production technology, it can be advantageous to design the through hole 42 in a cylindrical shape, as a result of which it can be produced simply and inexpensively in this case. When shaping by means of a wire EDM process, however, any other desired spatial shape is of course possible, it being essential that the boundary surfaces 29 run in the same longitudinal extension or longitudinal direction and parallel to the extrusion direction 6. When the insert part 28 is in the inserted position, the stop surfaces 39 and 40 are arranged in the receiving opening 27 in a transition region between the first end face 30 and the boundary surface 29 of the receiving opening 27.



  5, a width 44 of the gap 43 in a direction perpendicular to its longitudinal extent is smaller than a dimension 45 of the through hole 42 in the same direction. As a result of this difference in size, in the transition region between the holding part 33 and the guide part 34, the outer surface 35 is supported on the boundary surface 29 in the region of the first end surface 30, as is the case by a force - arrow F - in acting on the guide part 34 in its first end region 46 the Fig.



  3 is indicated. The dimensional difference between the width 44 of the gap 43 and the inner

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 Measurement 45 of the through hole 42 is strength-related to the insert part 28, in particular the transition region between the holding part 33 and the guide part 34, and the supporting force, which from the outer surface 35 onto the boundary surface 29 in the region of the first end surface 30 into the caliber plate 17 through the object to be passed through 5 is introduced to vote.



  As already described above, the caliber plate 17 has the thickness 32 between the two end faces 30, 31, the insert part 28 having a shorter length 48 in the same spatial direction between the first end region 46 and a further end region 47. Thus, the thickness 32 of the caliber plate 17 is greater than the length 48 of the insert part 28 in the direction of the guide arrangement 36. It is advantageous if, in the inserted position of the insert part 28 in the caliber plate 17, one of the two end regions 46, 47 is flat or recessed into one of the two end faces 30, 31 of the caliber plate 17 is aligned.

   In order to avoid a protrusion of one of the end regions 46, 47 of the insert part 28 relative to the caliber plate 17 in the event of a slight relative displacement of the insert part 28 relative to the caliber plate 17, it is advantageous to select the length 48 of the insert part 28 in such a way that when it is in the inserted position the two end regions 46, 47 are each aligned to the two end faces 30, 31.



  If the through hole 42 has a cylindrical three-dimensional shape, the holding part 33 of the insert part 28 must also be cylindrical in its longitudinal extent. Furthermore, it is also shown here that the gap 43 has gap walls 49, 50 aligned parallel to one another, against which the guide part 34 connected to the holding part 33 comes into contact at least in regions.



  The counterpart to the limit stop 37 of the caliber plate 17 forms on the insert part 28, in particular on the holding part 33, the limit stop 38 by means of a projection 51 on its first end area 30 facing the first end face 30, which protrudes beyond the outer surface 35 to form the stop surface 40. This extension 51 with the Stop surface 40 can be formed opposite to the stop surface 39 of the caliber plate 17, which means over a large part
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 Neten stop surfaces 39.40 come to rest against each other and thereby the end of the displacement movement is reached. With a simple adjustment process in the opposite direction

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 the insert part 28 can be removed from the caliber plate 17 without great effort and a new insert part 28 can be inserted into the receiving opening 27.



  In addition, in this exemplary embodiment it is also shown that on the holding part 33 of the insert part 28 at least two ribs 52, 53 projecting beyond the outer surface 35 are provided with these delimiting rib surfaces 54, 55, which at least in regions lie between the first and the further end region 46, 47 of the insert part 28 extend over the length 48. The two ribs 52, 53 are arranged in the near area or transition area between the holding part 33 and the guide part 34 on the insert part 28. Of course it is also possible, as will be shown in detail later, that several of these ribs 52, 53 can be arranged distributed over the circumference of the holding part 33.



  As can also be seen from the illustration in FIG. 4, an overhang 56 of the rib 52, 53 projecting beyond the outer surface 35 of the insert part 28 or holding part 33 decreases over its longitudinal course or longitudinal extent from the first end region 46 to the further end region 47 , especially steadily decreasing, trained. The protrusion 56 of the ribs 52, 53 is selected such that, during the insertion process of the insert part 28 into the receiving opening 27 of the caliber plate 17, the ribs 52, 53 plastically deform the material of the caliber plate 17, thereby making the receiving surface 27 opposite in the boundary surfaces 29 indentations permanently formed in the ribs are formed. These depressions are in turn delimited or shaped by the rib surfaces 54, 55 directly adjacent or adjacent surfaces facing them.

   These recesses are partially formed in the receiving opening 27 during the insertion process, as is shown with dashed lines in FIG. 5. The height of the projection 56 over the outer surface 35 depends on the number of ribs 52, 53 on the holding part 33 and can be between 0.05 mm and 1.5 mm, preferably between 0.1 mm and 0.5 mm.



  As a result of the reduction in the protrusion and the preferably conical arrangement and alignment of the rib surfaces 54, 55, starting from the rib surface 54 facing the molding surface 25, a pressing force - according to arrow 57 - through the holding part 33 to the boundary surface most distant from the molding surface 25 29 exercised, whereby an exact fit of the insert 28 is achieved in the receiving opening 27. This plastic deformation in the area of the ribs 52, 53 results in additional position fixation and a firm fit of the insert part 28 relative to the caliber plate 17.

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  To facilitate the deformation process of the material of the caliber plate 17, it is advantageous if the ribs 52, 53 have a preferably wedge-shaped cross section in a plane oriented perpendicular to their longitudinal extension, which is tapered in the direction facing away from the outer surface 35. The wedge angle between the rib surfaces 54, 55 can be acute-angled, right-angled, and optionally obtuse-angled, this being freely selectable depending on the choice of material for the insert part 28 in connection with the material of the caliber plate 17.



  Due to the tapering over the longitudinal course of the ribs 52, 53, the first rib surface 54 of the ribs 52, 53, which faces the shaped surface 25 assigned to the receiving opening 27, is oriented inclined to the latter. As a result, the rib is wedge-shaped both in its cross-section and in its longitudinal extent, as a result of which, as the insertion movement progresses in conjunction with the projection 56, an ever increasing plastic deformation or reshaping of the material of the caliber plate 17 in the region of the receiving opening 27 is achieved. In order to achieve a uniform insertion process, it is advantageous if the two first rib surfaces 54 of the ribs 52, 53 closer to the opening 24 are aligned parallel to one another and, if appropriate, are arranged in the same plane.



  To receive the material displaced by the ribs 52, 53 in the region of the receiving opening 27, it is advantageous if a recess is arranged in the insert part 28 at least in a transition region between the first rib surface 54 and the outer surface 35 of the insert part 28. If, for example, only these two ribs 52, 53 are provided in this transition region, it is advantageous to also provide a further recess 58 in the transition region between the further rib surface 55 and the outer surface 35 in order to also accommodate the displaced material of the caliber plate 17 in this region can. As a result, a mechanical form fit can be prevented during the insertion process between the insert part 28 and the caliber plate 17.



  Irrespective of this, it is also possible for the abutment surfaces 39, 40 to be formed at least in regions by the facing surfaces 29 and outer surfaces 35. However, it is also possible for the stop surfaces 39, 40 to be formed, at least in regions, by the rib surfaces 54, 55 and the depressions formed in the receiving opening 27 by the ribs 52, 53 with the counter surfaces.

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  3 and 4, in particular for the insert part 28, it can be seen that at least two further ribs 59, 60 projecting beyond the outer surfaces 35 are arranged on the part assigned or facing the gap 43 of the receiving opening 27, which in turn have a decreasing or tapering cross-sectional dimension starting from the first end region 46 to the further end region 47 and the protrusion beyond the outer surface 35 as well as the two ribs 52, 53 from the tolerances between the insert part 28 and the receiving opening 27, and the tight fit to be achieved in the inserted position in the caliber plate 17 is dependent.

   The greater the projection 56, the greater the plastic deformation and displacement of the material of the caliber plate 17 that can be achieved during the insertion process, and the greater the depression 58 on both sides of the rib surfaces 54, 55 of the ribs 52, 53 and of the rib surfaces 61, 62 to be performed on the ribs 59.60. Likewise, the wedge-shaped cross-sectional shape described above and the formation of the wedge angle in the case of the two ribs 59, 60 can take place analogously to the ribs 52, 53 already described above.



  As can best be seen from the illustration in FIG. 4, the ribs 52, 53 and 59, 60 have a wedge-shaped cross-sectional shape over their longitudinal course in the region between the two end regions 46, 47, as a result of which the rib surfaces 54, 55 and 61.62, the ribs 52.53 and 59.60 are aligned towards one another over the longitudinal extent of the insert part.



  As a result of this wedge-shaped design over the longitudinal course, the material of the caliber plate 17 becomes more and more permanently deformed as the insertion movement progresses, as a result of which an ever greater tight fit of the insert part 28 in the receiving opening 27 can be achieved.



  In the region of the guide part 34, which is assigned to the gap walls 49, 50 of the gap 43, the insert part 28 has support surfaces 63, 64 which are oriented opposite to these and which, in this exemplary embodiment, likewise run parallel to one another and parallel to the two gap walls 49, 50 are aligned.



  Furthermore, in FIG. 4 in the region of the guide part 34, one of many possibilities for forming the guide part 34 engaging or resting on the object 5 is shown in dashed lines. In this embodiment, the entire guide part 34 is approximately L-shaped.

  <Desc / Clms Page number 18>

 



  Irrespective of this, it is also possible, as is indicated in dashed lines in FIG. 5, that the gap walls 49, 50 delimiting the gap 43, in a plane oriented perpendicular to its longitudinal extent, proceeding from the through hole 42 to that assigned to the receiving opening 27 Shaped surface 25 of the opening 24 are tapered.



  6 to 9 show a further possible and possibly independent design of the insert part 28 and its holder or receptacle in the caliber plate 17, the same reference numerals being used for the same parts as in the previous FIGS. 1 to 5. Likewise, in order to avoid unnecessary repetition, reference is made to the description of the preceding FIGS. 1 to 5.



  The insert part 28 has the limit stop 38 with the stop surface 40 not in the first end region 46, but in the further end region 47, compared to the configuration as has been described in FIGS. 3 to 5. This limit stop 38 with its stop surface 40 is formed in the region of the holding part 33 by a taper or a shoulder 65 arranged opposite the outer surface 35, which in the present case extends over the entire cross-sectional area of the holding part 33 up to the guide part 34.



  As a result, the holding part 33 has a shorter longitudinal extension in the longitudinal extent of the insert part 28 than the guide part 34. The counterpart to this limit stop 38 is shown in the illustration of FIGS. 8 and 9 in the area of the caliber plate 17, the receiving opening 27 with its delimitation surface 29 not penetrating the caliber plate 17 over its entire thickness 32 in its entire cross section. In the area of the further end face 31 there is a projection 66 projecting into the receiving opening 27, which projects with a height 67 above the boundary surface 29 of the receiving opening 27. The stop surface 39 of the limit stop 37 is arranged at a distance 68 from the further end surface 31 in the direction of the first end surface 30.

   In this embodiment, the two stop surfaces 39, 40 are aligned parallel to the two end surfaces 30, 31 of the caliber plate 17. However, it would of course also be possible, as indicated in dashed lines in FIG. 9 in the region of the shoulder 66, to design the stop surface 39 inclined, preferably tapering in the direction of the further end face 31.



  The adjustment of the length 48 of the insert part 28 in relation to the thickness 32 of the caliber plate 17 is, as already described above, taking into account the arrangement and configuration

  <Desc / Clms Page number 19>

 to select the direction of the interacting limit stops 37, 38, so that in any case a protrusion of one of the end regions 46, 47 over one of the end faces 30, 31 of the caliber plate 17 is prevented in the inserted position. If several caliber plates 17 were lying one on top of the other, the choice of the high-strength materials of the insert part 28 would damage the caliber plates 17 and possibly cause the tight fit of the insert part 28 in the receiving opening 27.



  FIG. 6 also shows that a plurality of ribs 52, 53 are arranged on the holding part 33 over the circumference thereof. The design of the same can correspond to the embodiments described in the previous figures.



  In this exemplary embodiment, the gap 43 connecting the through hole 42 to the shaped surface 25 is designed such that gap walls 49, 50 in a plane oriented perpendicular to the longitudinal extent of the gap 43 starting from the through hole 42 or the boundary surface 29 to the shaped surface assigned to the receiving opening 27 25 of the opening 24 are designed to expand. These widening gap walls 49, 50 can be flat and curved, but can run in a vertical direction between the two end faces 30, 31. In this exemplary embodiment shown here in FIG. 8, the gap walls 49, 50 are formed by sections of a cylindrical surface.



  Furthermore, it is shown in FIG. 6 that on the guide part 34 to the two gap walls 49, 50 of the gap 43 there are opposing support surfaces 63, 64 which protrude beyond the guide part 34 transversely to its longitudinal extent and preferably over the length 48 of the guide part 34 are formed continuously. The shape and design of the guide part and its protrusion over the molding surface 25 in the direction of the opening 24 depend on the shape of the object 5 to be calibrated and can be freely selected according to the particular circumstances.



  10 to 13 a further possible and possibly independent design of the insert part 28 and the receiving opening 27 in the caliber plate 17 is shown, the same reference numerals being used for the same parts as in the previous FIGS. I to 9.

   Likewise, in order to avoid unnecessary repetitions, the design
 EMI19.1
 

  <Desc / Clms Page number 20>

 This embodiment of the insert part 28 shown here is similar to the embodiment as has already been described and illustrated in FIGS. 6 and 7, wherein, in contrast to this embodiment, the gap 43 with the gap walls 49, 50 delimiting it is designed to be continuously parallel to one another , and likewise the support surfaces 63, 64 in that section of the guide part 34 which faces the gap 43 are likewise designed in parallel and without any projection.



  The design of the limit stops 37, 38 as well as the stop surfaces 39, 40 arranged thereon and the design and arrangement of the individual ribs 52, 53, with the depressions 58 which may be arranged between them, can correspond to the designs described in detail in FIGS. 6 to 9.



  14 and 15 show a further possible and possibly independent design of the insert part 28 for insertion into a receiving opening 27 (not shown here) in the caliber plate 17, the same reference numerals for the same parts as in the previous FIG. 1 to 13 are used. Since this design of the insert part 28 is similar to the design as has already been shown in FIGS. 6 and 7 and 10 and 11, reference is made to the detailed description of these figures.



  The holding part 33 with its outer surface 35 in turn has a plurality of ribs 52, 53 arranged distributed over the circumference, between which the depressions 58 can optionally be arranged in the outer surface 35. Likewise, the support surfaces 63, 64, as has already been described in FIGS. 10 to 13, are oriented parallel to one another in the region facing the gap 43.



  The limit stop 38 is here in turn provided in the further end region 47 of the insert part 28, the stop surface 40 being designed in the form of a circular ring section through the arrangement of the shoulder 65. This stop surface 40 is the stop surface 39 not shown here in the region of the limit stop 37, which can be formed by the extension 66, on the caliber plate 17.



  In the embodiments of the holding part 33 shown and described in FIGS. 3 and 4, 6 and 7, as well as 10 and 11, the cross-sectional shape of the holding part 33 is perpendicular to it
 EMI20.1
 

  <Desc / Clms Page number 21>

 33 is cylindrical in the direction of its longitudinal extent over a large part of its circumference.



  16 and 17 show a further, possibly independent design of the insert part 28, again using the same reference numerals for the same parts as in the previous FIGS. 1 to 15. Likewise, in order to avoid unnecessary
 EMI21.1
 referred or referred.



  The insert part 28 is configured in the region of its guide part 34 in a manner similar to that which has already been described in FIGS. 6 to 9. In this case, projections 69 protrude from the holding part 33 on both sides of its longitudinal extent, the support surfaces 63, 64 being arranged on these projections 69 opposite the gap 43 with the gap walls 49, 50 which widens in the caliber plate 17. In the area of the holding part 33, the ribs 52, 53 are in turn arranged on both sides of a plane of symmetry 70, and their spatial shape is defined by the rib surfaces 54, 55 assigned to them. In this case, the first rib surfaces 54 facing the guide part 34 or the shaped surfaces 25 of the opening 24 are arranged parallel to one another and in a plane 71, which is oriented perpendicularly to the plane of symmetry 70 and is shown in simplified form.



  The two rib surfaces 54, 55 delimiting the ribs 52, 53 are again oriented at an acute angle to one another in the direction perpendicular to the longitudinal extension thereof. Of course, it is also possible to align the rib surfaces at right angles or obtuse angles to one another. 16 and 17, it can also be seen here that the rib surfaces 54, starting from the first end region 46, are oriented inclined by an angle 72 in the direction of the further end region 47, a distance 73 in the first end region 46 starting from an apex of the outer surface 35 between the latter and the rib surface 54 is greater than a distance 74 in the same direction in the further end region 47. This apex is arranged in the region of the imaginary intersection of the plane of symmetry 70 with the outer surface 35.

   Due to this inclined arrangement, which in the present illustration can also be described as falling from the first end region 46 to the further end region 47, a constantly increasing pressing force is emitted from the outer surface 35 of the holding part 33 onto the boundary surface 29 associated therewith during the insertion process the receiving opening 27 achieved. This makes it more precise

  <Desc / Clms Page number 22>

 Projection of the guide part 34 on the shaped surface 25 in the direction of the opening 24 can be achieved. Likewise, the holding force of the insert part 28 in the receiving opening 27 is also determined thereby. The size of the angle 72 is preferably selected such that it ensures a self-locking of the insert part 28 in the receiving opening 27.

   The limit stop 38 in the region of the holding part 33 is in turn formed by the shoulder 65 with the stop surface 40.



  Likewise, it is also possible to combine the two different embodiments of the limit stops 37 and 38, as has been described in FIGS. 3 to 5 and 6 to 17, as desired and to provide them on one of the holding parts 28 at the same time. This can be the case, for example, when high supporting forces are applied to the insert part 28 starting from the object 5, in order to ensure an adequate and safe power transmission with a secure hold.



  18 to 20 a further insert part 28 in a receiving opening 27 of the caliber plate 17 is shown in simplified form, the same reference numerals being used for the same parts as in the previous FIGS. 1 to 17. Likewise, reference is made to the previous FIGS. 1 to 17 for the formation of the limit stops 38, 39 for limiting the longitudinal movement of the guide arrangement 36.



  This insert part 28 shown here is designed such that a contact surface 75 facing the opening 24 is aligned approximately flat with the shaped surface 25 of the opening. This insert part 28 shown here is used to be deepened in the area of heavily loaded molding surfaces 25 in order to avoid wear and an associated inaccuracy in the length of the object 5 during the manufacturing process and to be able to quickly carry out an exchange.



  In the first end region 46 of the insert part 28, the extension 51, which forms the limit stop 38 with the stop surface 40, is in turn arranged at least in regions over the circumference of the holding part 33. In contrast, the limit stop 37 with the stop surface 39 is provided in the region of the first end face 30 of the caliber plate 17, as has been simplified in the left part of FIG. 20.



  Approximately parallel to the contact surface 75, the holding part 33 has the outer surface 35, which is the
 EMI22.1
 

  <Desc / Clms Page number 23>

 at least one, but preferably a plurality of, ribs 52, 53 are arranged between the approximately parallel surfaces, namely the contact surface 75 and the outer surface 35, which in turn additionally hold or fix the insert part 28 in order to limit the longitudinal movement Ensure the receiving opening 17 in order to ensure a precisely defined alignment of the contact surface 75 in relation to the object 5 to be aligned.



  It is essential in all of the different embodiments described above that the limit stop 37, 38 is formed at least in regions between the holding part 33 and the receiving opening 27 by a positive fit between these parts. This can be realized in that the stop surfaces 39, 40 are formed at least in regions by the facing surfaces 29 and outer surfaces 35. In addition or independently of this, this form fit can also be achieved by the ribs 52, 53, 59 and 60 arranged on the insert part in connection with the depressions formed in the receiving opening 27. However, a double-conical design of the receiving opening 27 and the holding part 33 would also be possible.



  21 shows a partial area of the caliber plate 17 with the insert part 28 held therein and the object 5 guided with the insert part 28, the same reference numerals being used for the same parts as in the previous FIGS. 1 to 20.



  It is shown here in a simplified manner that, in the area of the holding part 33, the shape of the shape is almost identical, a simple exchange can be made for another insert part 28 if the guide part 34 is displaced with respect to the receiving opening 27, in particular transversely to the extrusion direction 6, and / or a substantial one other training, such as B. an increase or decrease in width transverse to the extrusion direction 6, is desired. By a one-sided shift, for.

   B. a directional compressive force can be exerted on a portion of the object 5, so as to achieve the desired orientation of the object 5 in this section during the cooling process, so that the required dimensional accuracy of the object 5 without high work and straightening effort in the area of the caliber plates 17 only can be achieved by simply replacing the insert parts 28.
 EMI23.1
 

  <Desc / Clms Page number 24>

 



  For the sake of order, it should finally be pointed out that, for a better understanding of the structure of the caliber plate with the insert part and its holder, these or their components have been shown partially to scale and / or enlarged and / or reduced.



  The object on which the independent inventive solutions are based can be found in the description.



  Above all, the individual in FIGS. 1; 2; 3 to 5; 6 to 9; 10 to 13; 14, 15; 16, 17; 18 to 20; 21 shown form the subject of independent, inventive solutions. The relevant tasks and solutions according to the invention can be found in the detailed descriptions of these figures.

  <Desc / Clms Page number 25>

 



  REFERENCE NUMBERS
1 extrusion line
2 extruders
3 shaping device
4 caterpillar take-off
5 subject
6 extrusion direction
7 extrusion tool
8 calibration device
9 Calibration tool 10 Calibration tool 11 Calibration tool 12 Calibration tool 13 Calibration tool 14 Vacuum tank 15 Vacuum tank 16 Vacuum tank 17 Caliber plate 18 Receptacle 19 Machine bed 20 Footprint 21 Calibration table 22 Roller 23 Travel rail 24 Cutout 25 Molding surface 26 Profile cross section 27 Receiving opening 28 Insert part 29 Limiting surface 30 End surface 31 End surface 32 Thickness 33 holding part 34 guide part 35 outer surface 36 guide arrangement 37 limit stops 38 limit stops 39 stop surface 40 stop surface 41 holder arrangement 42 through hole 43 gap 44 width 45 dimension 46 end region 47 end region 48 length 49 gap wall 50 gap wall

  51 extension 52 rib 53 rib 54 rib surface 55 rib surface 56 protrusion 57 arrow 58 depression 59 rib 60 rib 61 rib surface 62 rib surface 63 support surface 64 support surface 65 heel 66 shoulder 67 height 68 distance 69 projection 70 plane of symmetry

  <Desc / Clms Page number 26>

 71 level 72 angle 73 distance 74 distance 75 contact surface


    

Claims (1)

 1. Caliber plate for a shaping device of an extrusion system with end faces spaced apart from one another in the extrusion direction, between which extends at least one opening with shaped surfaces for the passage of an extruded object and the shaped surfaces of the opening at least in regions delimit an outer profile cross section of the object to be passed through and with at least one in the Caliber plate recessed receiving opening, which extends from the molded surface in the direction facing away from the opening and boundary surfaces of the receiving opening extend between the two end faces and at least one wear-resistant insert part with a holding part inserted into the receiving opening,  which has outer surfaces facing the boundary surfaces of the receiving opening and end regions assigned to the two end surfaces, the boundary surfaces and the outer surfaces forming a guide arrangement at least in some areas, characterized in that over a large part of a peripheral region both in the region of the receiving opening (27) and on the holding part ( 33) interacting limit stops (37, 38) with stop surfaces (39, 40) are provided for the guide arrangement (36).  EMI27.1  (39.40) are aligned parallel to the end faces (30. 31). 3. Caliber plate according to claim I or 2, characterized in that the stop surfaces (39, 40) are inclined, in particular in the direction of the second end face (31), are tapered. 4. Caliber plate according to one or more of the preceding claims, characterized in that the stop surfaces (39, 40) are formed at least in regions by the mutually facing boundary surfaces (29) and outer surfaces (35).  <Desc / Clms Page number 28>   5. caliber plate according to one or more of the preceding claims, characterized in that the stop surface (39) from the second end face (31) in the direction of the first end face (30) by a distance (68) and at a distance into the receiving opening (27 ) projecting approach (66) is arranged. 6. Caliber plate according to one or more of the preceding claims, characterized in that the stop surfaces (39, 40) are arranged in a transition region between the first end surface (30) and the boundary surface (29) of the receiving opening (27). 7. caliber plate according to one or more of the preceding claims, characterized in that the holding part (33) of the insert part (28) on its further end face (31) facing further end region (47) for forming the stop face (40) opposite its outer surface ( 35) has a taper or a shoulder (65). 8. Caliber plate according to one or more of the preceding claims, characterized in that the holding part (33) of the insert part (28) on its first end face (30) facing the first end region (46) for forming the stop face (40) has an outer surface ( 35) has an outstanding extension (51). 9. caliber plate according to one or more of the preceding claims, characterized in that the insert part (28) in addition to the holding part (33) comprises at least one in the opening (24) projecting guide part (34). 10. caliber plate according to one or more of the preceding claims, characterized in that the receiving opening (27) from the shaped surface (25) of the opening (24) spaced through hole (42) and one of the through hole (42) with the shaped surface (25) connecting gap (43).   11. Caliber plate according to claim 10, characterized in that the through hole (42) is formed by a bore.  <Desc / Clms Page number 29>   12. Caliber plate according to claim 10 or 11, characterized in that a width (44) of the gap (43) in the vertical direction to its longitudinal extent is less than a dimension (45) of the through hole (42) in the same direction. 13. Caliber plate according to one or more of claims 10 to 12, characterized in that gap walls (49, 50) delimiting the gap (43) are aligned parallel to one another. 14. Caliber plate according to one or more of claims 10 to 13, characterized in that the gap walls (49, 50) delimiting the gap (43) in a plane oriented perpendicular to its longitudinal extent starting from the through hole (42) to that of the receiving opening ( 27) assigned to the shaped surface (25) of the opening (27). 15. Caliber plate according to one or more of claims 10 to 14, characterized in that the gap walls (49, 50) delimiting the gap (43) are formed by sections of a cylindrical surface. 16. Caliber plate according to one or more of claims 10 to 13 or 15, characterized in that the gap walls (49) delimiting the gap (43) in a plane oriented perpendicular to its longitudinal extent starting from the through hole (42) towards the Shaped opening (27) associated with the shaped surface (25) of the opening (24) are tapered. 17. Caliber plate according to one or more of the preceding claims, characterized in that on the insert part (28) in the region of the gap (43) opposite to the gap walls (49, 50) extending support surfaces (63, 64) are arranged. 18. Caliber plate according to one or more of the preceding claims, characterized in that on the holding part (33) of the insert part (28) at least two ribs (52, 53) projecting over the outer surface (35) are provided with these delimiting rib surfaces (54, 55)  <Desc / Clms Page number 30>  which extend at least in regions between the first and the further end region (46, 47). 19. Caliber plate according to claim 18, characterized in that at least two of the ribs (52, 53) are arranged in the transition region between the holding part (33) and the guide part (34) on the insert part (28). 20. Caliber plate according to claim 18 or 19, characterized in that a plurality of ribs (52, 53) are arranged distributed over the circumference of the holding part (33). 21. Caliber plate according to one or more of claims 18 to 20, characterized in that an overhang of the rib (52, 53) projecting beyond the outer surface (35) of the insert part (28) over its longitudinal course from the first to the further end region (46, 47 ) is designed to decrease. 22. Caliber plate according to one or more of claims 18 to 21, characterized in that the rib (52, 53) has a wedge-shaped cross section in a plane oriented perpendicular to the longitudinal extent of the insert part (28), the cross section being turned away from the outer surface (35) Direction is tapered. 23. Caliber plate according to one or more of claims 18 to 22, characterized in that the rib surfaces (54, 55; 61, 62) of the rib (52, 53; 59, 60) over the longitudinal extension of the insert part (28) are aligned. 24. Caliber plate according to one or more of claims 18 to 23, characterized in that the two first rib surfaces (54) of the ribs (52, 53) closer to the opening (27) are aligned parallel to one another. 25. Caliber plate according to claim 24, characterized in that the two first rib surfaces (54) are arranged in the same plane that receives them.  <Desc / Clms Page number 31>   26. Caliber plate according to one or more of claims 18 to 25, characterized in that a recess (58) is arranged in the insert part (28) at least in a transition region between the first rib surface (54) and the outer surface (35) of the insert part (28) is. 27. Caliber plate according to one or more of the preceding claims, characterized in that on the insert part (28) on the section assigned to the gap (43) of the receiving opening (27) at least two further ribs (59, 60) projecting beyond the outer surfaces (35). are arranged. 28. Caliber plate according to one or more of the preceding claims, characterized in that the stop surfaces (39, 40) at least in regions by the rib surfaces (54, 55; 61, 62) and those by the ribs (52, 53; 59, 60) formed in the receiving opening (27) recesses. 29. Caliber plate according to one or more of the preceding claims, characterized in that the holding part (33) of the insert part (28) is cylindrical in its longitudinal extent. 30. Caliber plate according to one or more of the preceding claims, characterized in that the insert part (28) is formed in one piece. 31. Caliber plate according to one or more of the preceding claims, characterized in that a thickness (32) thereof between the two end faces (30, 31) is greater than a length (48) of the insert part (28) between its end regions (46, 47 ). 32. Caliber plate according to one or more of the preceding claims, characterized in that when the insert part (28) is in the inserted position in the caliber plate (17), one of the two end regions (46, 47) thereof is flat or recessed to one of the two end faces ( 30, 31) is aligned.  <Desc / Clms Page number 32>   33. Caliber plate according to one or more of the preceding claims, characterized in that when the insert part (28) is in the inserted position in the caliber plate (17), the two end regions (46, 47) of the same are aligned with the two end faces (30, 31) , 34. Caliber plate according to one or more of the preceding claims, characterized in that the material forming this in the region of the ribs (52, 53; 59, 60) of the insert part (28) is plastically deformed at least in certain areas. 35. Caliber plate according to one or more of the preceding claims, characterized in that the boundary surfaces (29) of the receiving opening (27) between the two end faces (30, 31) extend in a direction perpendicular thereto.