EP3052262A1

EP3052262A1 - Rupture-separating device

Info

Publication number: EP3052262A1
Application number: EP14777265.1A
Authority: EP
Inventors: Armin Bellan
Original assignee: Alfing Kessler Sondermaschinen GmbH
Current assignee: Alfing Kessler Sondermaschinen GmbH
Priority date: 2013-10-01
Filing date: 2014-09-26
Publication date: 2016-08-10
Also published as: DE102013016352A1; WO2015049039A1; JP2016539018A; DE102013016352B4

Abstract

The invention relates to a rupture-separating device with a spreading element arrangement (45), which comprises a first and at least one second spreading element (41, 42), which are formed such that they can be moved by means of an actuating body (43) between a positioning position for insertion into a bearing opening (89) of a motor component (80) and a spreading position for the abutment of abutting surfaces (52-55) of the outer circumference (46) thereof against an inner circumference (94) of the bearing opening (89), in order to form on the motor component (80) rupture-separating surfaces (90) that are made to extend away from the bearing opening (89) in the radial direction. According to the invention, the abutting surfaces (52 to 55) of the spreading element arrangement (45) comprise abutting surfaces (52 to 55) that can be arranged on both sides of a predetermined breaking location (95) of the motor component (80), wherein these abutting surfaces (52 to 55) extend around the predetermined breaking location (95) in the range of abutting angles (57) of altogether 35° to 120° and respectively abut with surface-area contact on the inner circumference (94) of the bearing opening (89), and wherein there are altogether at least four raised abutting surfaces (52 to 55) of the spreading element arrangement (45) for abutment on the bearing opening (89).

Description

Fracture splitting device

The invention relates to a fracture separation device for fracture separation of a motor component, in particular a connecting rod, with a Spreizelementanordnung with a first expansion element and at least a second expansion element, and an actuating body for actuating the Spreizelementanordnung from a positioning position into a spread position for separating a first component of the engine component, in particular one Pleueldeckels, from a second component of the engine component, in particular a connecting rod, wherein the Spreizele ^¬ elements are inserted in the positioning along a longitudinal axis in a bearing opening of the engine component and press in the spread position with contact surfaces on its outer periphery against an inner circumference of the bearing opening, so that the first component of the second component of the engine component breaks away to form fracture separation surfaces, wherein the fracture separation surfaces extend radially away from the bearing opening.

Such a fracture separation device is e.g. in

EP 0 999 912 B1. In this patent is proposed to introduce the compressive force during spreading over a partial area or line area in the bearing opening. For this purpose, the expanding mandrel, for example, a spherical shape or conical shape and at least does not exert the compressive force over the entire surface in the bearing opening or hole. The result

CONFIRMATION COPY However, such a fracture separation is not satisfactory in all cases.

It is therefore the object of the present invention to provide an improved fracture separation device.

To solve the problem in a fracture separation device of the type mentioned above provided that the contact surfaces of the expansion element for abutment on the bearing opening on both sides of a predetermined breaking point each comprise a contact surface, said contact surfaces in a contact angle range of a total of 35 ° to 120 ° to the predetermined breaking point extend the respective break separation surface around and each lie flat against the inner circumference of the bearing opening, and wherein a total of at least four contact surfaces of the Spreizelementanordnung are present for bearing against the bearing opening.

It is a basic idea that the fracture separation device does not act on the entire surface in the bearing opening, but rather exerts a compressive force in the area of the fracture separation surfaces, ie in the region of the predetermined breaking point of the two engine component components, thus initiating fracture separation. However, it has in practice and attempts herausge ^¬ provides that a force via a narrow, li- nienförmigen area or even punctual area, as in a conical or spherical expanding mandrel, not always achieve an optimal fracture pattern. Here, the fracture separation device according to the invention takes a different approach and ensures a planar contact of the Spreizelementanordnung in the region of the predetermined breaking point, namely over an angular range of for example 35 ° to 120 ° or more preferably 40 ° to 110 °. It is possible that the contact surfaces are formed by a support member which is placed on a base body of a respective expansion element. For example, a kind of half-shell may be arranged on a cracking mandrel element or Crackdorn basic body and provide the contact surfaces positioned according to the invention. In the embodiment according to the drawing, however, a "one-piece" expanding mandrel is shown, ie an expanding mandrel in which the abutment surfaces are arranged directly on the basic expanding mandrel, and no half-shells or the like are placed on this expanding mandrel.

The predetermined breaking point expediently forms the bisecting line, so to speak. that this angular range in which the contact surfaces act on the bearing opening extends approximately symmetrically around the respective predetermined breaking point.

So there is unlike the prior art, a two-dimensional pressure introduction, this pressure introduction takes place on a region around the fracture separation surfaces or the predetermined breaking points around.

A preferred embodiment of the invention provides that the contact angle range of the contact surfaces has a total circumference of about 60 ° to 90 °. It is further preferred if the contact angle range is still narrower, i. that he has only 50 ° to 80 °, for example. In any case, narrow, limited to a narrow angular range investment angle ranges of the contact surfaces are preferred.

In the sense of a surface contact of the contact surfaces on the inner circumference of the bearing opening, the following measures are advantageous: The outer radius of one or all of the abutment surfaces preferably corresponds essentially to an inner radius at a respective section of the inner circumference of the bearing opening on which the respective abutment surface comes to rest. Of course, it is advantageous if the radii correspond exactly.

A further advantageous measure provides that one or all contact surfaces are cylindrical. This measure is related to the also expediently cylindrical shape of the bearing opening, where then due to the cylindrical contact surfaces of the expansion element optimal pressure introduction is possible.

In this sense, it is also to be understood that a curvature of the inner circumference of the bearing opening with respect to the longitudinal axis is generally not present, that is, e.g. is cylindrical. Even if a curvature is present, the following advantageous measure takes effect:

It is preferred if one or all contact surfaces do not have a curvature with respect to the longitudinal axis, which is related to the inner peripheral surface of the bearing opening which is not curved in the longitudinal axis direction, or such a curvature which corresponds to the curvature of the inner circumference of the bearing opening in the direction of the longitudinal axis.

In all of the above-mentioned three measures it is achieved that the respective contact surface rests flat on the respective inner peripheral portion.

However, one must also take into account that neither the expansion element arrangement nor the workpieces to be machined have an exact dimension, but in practice always have dimensional tolerances. sanzen occur. In particular, in engine components, such as connecting rods, relatively large dimensional tolerances are present in practice, so that although perhaps the Spreizelementanordnung exact dimensions, ie an exact outer radius according to the above measure, but the associated engine component just just not accurate, but in a wider tolerance range fluctuates. In other words, this also means that the surface contact of the contact surfaces at the bearing opening offers a particular advantage. In any case, in the area of the contact surfaces, there are generally several contact areas in which the expansion element arrangement exerts pressure on the components of the engine component.

Between the contact surfaces of the Spreizelementanordnung, which are assigned to one of the components of the engine component, ie the first component or the second component, an angular distance is advantageously present such that the Spreizelementanordnung in a crest region of the bearing opening between the fracture separation surfaces not or not in the sense of Pressing on the inner circumference of the bearing opening is applied and the pressure is introduced during the fracture separation in the contact angle range and thus in the region of the fracture separation surfaces. Thus, therefore, the apex region of the bearing opening between the fracture separation surfaces is depressurized or is subjected to low pressure, while the main pressure is exerted in the region of the fracture separation surfaces during the expansion process.

At least one contact surface or all contact surfaces preferably have a fracture separation surface angular distance from the respective fracture separation surface. As a result, at least one contact surface or all contact surfaces directly at the fracture separation surface or the predetermined breaking point does not directly initiate pressure in the tensioning position. So it will be not applied directly to the plane of the fracture separation surfaces, but at an angular distance therefrom. The contact surfaces are therefore arranged at a distance next to the predetermined breaking point, which contributes to optimal cracking.

The aforementioned break separation surface angular distance is expediently in a range of about 1 ° to 15 °, but preferably in an even smaller range, namely for example between 2 ° and 13 °. It is further preferred that in a range between 5 ° and 12 ° no contact surface is directly in contact, at least in contact for a pressure introduction, with the inner periphery of the bearing opening in the region of the predetermined breaking point or fracture separation surface.

At least one contact surface expediently has a longitudinal distance to at least one longitudinal end of the bearing opening at one during the fracture separation with respect to the longitudinal axis

Front side of the engine component on. Thus, therefore, the pressure is not introduced to the front side of the engine component or over the entire longitudinal direction of the bearing opening, but so to speak in the inner region of the bearing opening with respect to the longitudinal axis. It is preferred if in each case such a longitudinal distance is present at both longitudinal ends.

In Längsachsrichtung it is also advantageous if the respective contact surface or the area which acts on the bearing opening of several contact surfaces, is made in the Spreizelementanordnung so that the contact surfaces in total only about three quarters, preferably only about two thirds and more preferably only about Half or one third of the height or length of the bearing opening in Längsachsrichtung during fracture separation pressurize. An advantageous embodiment of the invention provides that at least one contact surface is strip-shaped. It is also possible that the contact surfaces have a circular or elliptical shape. In any case, a possible large-scale investment of the respective contact surface on the inner circumference of the bearing opening is always desirable and advantageous. It is understood that a combination of several extending transversely to the longitudinal axis strip-shaped contact surfaces is possible, which are, for example, in the direction of the longitudinal axis over each other. In the embodiment according to the drawing, only a single such contact surface strip is shown.

The first expansion element and / or the at least one second expansion element expediently has a semicircular outer circumference. The respective contact surfaces of this expansion element are provided in the region of the respective longitudinal ends of the semicircle. As mentioned, however, a distance, the aforementioned break separation surface angular distance, can be provided. It is preferred that in this semicircular expansion elements in the region of the apex of the outer circumference of the respective expansion element no contact surface is present.

The first expansion element and the at least one second

Expander expediently each have an outer circumference corresponding to a semicircle of about 180 °. The fracture separation surfaces extend, for example, diametrically away from each other in the bearing opening, so that this semicircular configuration of expansion elements is particularly preferred.

Of course, it is conceivable that three spreading elements are available. In this configuration, For example, the first expansion element have an angular extent of about 180 ° (corresponding to a semicircle), while the other two expansion elements each have an angular extent of, for example, only a maximum of 60 °.

Another configuration may provide that a plurality of expansion elements are present, for example four spreading elements, of which two spreading elements are responsible for the contact surface angle range on both sides of the respective predetermined breaking point or fracture separation surface, so there have the contact surfaces according to the invention. Especially in the apex area between see this contact surfaces can, but not a spreading - element or a portion of a spreader must be present. The pressurization of the bearing opening is namely only in the region of the predetermined breaking points over a defined angular distance.

The expansion element arrangement is expediently provided on an expanding mandrel. The expanding mandrel thus has expediently end-side insertion bevels, so that the expansion element arrangement can be easily introduced into the bearing opening.

The first expansion element is preferably the first component that associates at least one second expansion element with the second component of the engine component. In the area between de: components, ie the predetermined breaking point or Bruchtrennflä surface, so expediently no expansion element is provided. The spreading elements are expediently designed so that they exert pressure in the expanded position to the respective component of the engine component.

Is between the actuator body and the first expansion element and / or the at least one second expansion element expediently provided a wedge surface arrangement, via which the actuating body actuates the first and / or second expansion element. The actuating body is expediently drivable by a spreading drive, for example an electromotive, fluidic or combined electro-fluidic spreading drive. It is possible that, for example, the first expansion element is stationary, while the second expansion element can be actuated by the arrangement of expansion drive operating body between the positioning position and the spreading position. But it is also possible that both or all of the spreading elements can be actuated or driven by the spreading drive or the actuating body.

Appropriately, it is provided that the actuating body is arranged on a driven head of the spreading drive and the spreading a movable relative to the driven head, a hammer mass having impactor for generating shocks on the output head, and that the spreading a pulse drive for driving the impactor to the output head in the context of a shock pulse operation of the fracture separation device.

The fracture separation device is expediently designed for arrangement in a bearing opening of the engine component, for example an eye of a connecting rod

Preferably, the fracture separation device forms part of a machine tool or a machining center or both.

Hereinafter, an embodiment of the invention will be explained with reference to the drawing. Show it: FIG. 1 shows a side view of a machine tool which has a fracture separation device according to the invention,

Figure 2 is a frontal plan view of a lower part of

Machine tool according to Figure 1 and a fracture separation device and a workpiece holding device, of the in

FIG. 3 shows a detail D1 from FIG. 2,

FIG. 4 shows a perspective oblique view of a spreading element arrangement of the fracture separation device,

Figure 5 is a perspective oblique view of a

Connecting rod, wherein contact surfaces are marked with the spreading element arrangement,

FIG. 6 shows a sectional view (without hatching) of the spreading element arrangement according to FIG. 4 along a

Cutting line A-A,

FIG. 7 shows a partial view of a connecting rod cover of the connecting rod according to FIG. 5 approximately corresponding to a cutout D2 in FIG. 5 (viewing direction B) with a fracture profile schematically represented by arrows in a fracture separation process according to the invention;

8 shows the connecting rod cover according to Figure 7, but with a

Breakage course in a conventional and non-inventive fracture separation process.

A machine tool 10 shown schematically in the drawing, which may also be a machining center or a component of a machining center, has a breakaway separating device 40 for fracture separation of engine components 80 on. The machine tool 10 could also be referred to as a cracking machine.

The machine tool 10 is intended to process, for example, connecting rods 81 as motor components 80, e.g. an alternative field of application of the invention is, for example, the cracking of bearing caps of an engine block. Other workpieces can be broken in principle according to this type.

The connecting rods 81 comprise a connecting rod shaft 82, which at one end region has a so-called small eye 84, ie a bearing opening, bearing bore or bearing recess, and a large eye 83, likewise a bearing opening 89, bearing bore or bearing recess. The two bearing openings or eyes 83 and 84 are provided, for example, for rotatable connection to a crankshaft and a piston (not shown).

In the area of the large eye 83 or the bearing opening 89, the following processing is carried out with the machine tool 10:

From a connecting rod root 85, a second component 92 of the engine component 80, a first component 91 of the engine component 80, namely a connecting rod cover 86, separated by means of the fracture separation device 40, so that on the side legs 93 of the large end 85 and the side legs of the

Connecting rod cover 86, each defining the large eye 83 laterally, fracture separation surfaces 90 form. These fracture separation surfaces 90 fit one another positively, since the surface topography is ideally identical for both fracture separation surfaces. The machine tool 10 and / or the machining center can have a scoring tool, for example for laser scoring, which is not shown in the drawing. In any case, a notch 88 facilitating the fracture separation is advantageously provided in the area of the later fracture separation surfaces or lines. However, the notches 88 may be provided from the outset on the connecting rod 81 also · on, for example, if it is produced as a casting ^"or sintered part.

The machine tool 10 comprises a machine base 11, for example a machine bed, on which a workpiece holding device 12 is arranged. With the workpiece holding device workpieces, namely the motor component 80 or the connecting rod 81, are held, while the further processing takes place by the fracture separation device 40. The workpiece holder 12 may form part of the fracture separation device 40.

From below, the connecting rod 81 or motor component 80 is supported by a workpiece support device 13. The Stützein ^¬ device 13 may directly engage the motor member 80, thus supporting this directly, or for example, a cassette 23 in which the engine component 80 / connecting rod is arranged 81st

During the processing by the fracture separation device 40, the connecting rod 81 is supported by laterally acting support devices 14, 15, 16, 17, whose support heads 18, 19, for example, from the side of the connecting rod cover 86 ago supporting, while the support body 20 and 21 of the support means 16, 17 supported from the other side, namely the big end of the ball 85. Thus, in any case, the connecting rod 81 is securely held during the fracture separation processing. The machine tool 10 further comprises a rotary table 22 or another workpiece conveyor, with the workpieces, namely motor components 80 or connecting rods 81 of the fracture separation device 40 can be supplied or can also be led away again by the fracture separation device 40. On the rotary table 22, for example, cassettes 23 are arranged.

In front of the machine base 11 is a stand 25 upwardly, which is designed for example in the manner of a tower, a support frame or the like. The stand 25 carries a guide assembly 26 or forms such. The guide assembly 26 includes a linear guide 27 on which the fracture separation device 40 is linearly guided. With help of a

Positionierantriebs 28, for example, an electric drive or pneumatic drive or fluidic drive, the fracture separation device 40 between a lower working position, in which it is ready for machining of the engine component 80 or connecting rod 81 and an upper position, in the fracture separation device 40 of the engine component

80 / connecting rod 81 is removed and a workpiece change is possible by, for example, the rotary table 22 further switches and feeds an unprocessed workpiece for further processing by the fracture separation device 40, are adjusted. The fracture separation device 40 is e.g. arranged on a linearly guided on the linear guides 27 or 26 of the guide carriage 29.

The fracture separation device 40 comprises a first expansion element 41 and a second expansion element 42 of a expansion element arrangement 45.

The spreading 41 and / or 42 can be displaced radially outward by an actuator body 43, wherein they disconnect the connecting rod cap 86 from the connecting rod 85 of the connecting rod 81. Then arises in the region of the notches 88 a fracture separation surface, as already explained above. In the exemplary embodiment, a wedge surface arrangement, not shown, acts between the actuating body 43 and the second expansion element 42, so that the second expansion element 42 is pressed in the direction of the big end 85, ie second component 92 of the engine component 80 and on the connecting rod foot 85, wherein the first component 91, the connecting rod cover 86 is blown off, so to speak.

The separate components 91 and 92 are in a later step, for example when the machine tool 10 forms part of a machining center, joined together again and screwed together, for example. For screws, e.g. the two side legs 93 passing through mounting channels 87 or holes provided.

The spreading elements 41, 42 define a guide receptacle 44 for receiving and guiding the actuating body 43. The actuating body 43 comprises, for example, a so-called expanding wedge.

The two spreading elements 41, 42 have on their coming into pressure contact with the bearing opening 89 outer periphery 46 an outer peripheral contour, which corresponds to an inner peripheral contour on an inner circumference 94 of the bearing opening 89, the eye 83. Thus, therefore, the spreading 41, 42 fit substantially form-fitting fit on the inner circumference 94 of the eye 83. The spreading elements 41, 42 form, for example, expanding jaws.

The actuating body 43 can be driven by a spreading drive 50, for example, a pneumatic cylinder, a hydraulic drive or the like has other fluidic drive. Alternatively, for example, a Li would nearantrieb, for example, electric linear drive, possible. The spreading drive 50 may also include a pulse drive and / or an impact mass.

The two spreading elements 41, 42 each have an insertion bevel 47 in the region of their front face, which facilitate insertion into the bearing opening 89. When the actuating body 43 or expanding wedge of the spreading elements 41 and 42 is away ver, they assume a positioning position, in which the Spreizelementanordnung 45, the total one

Expansion mandrel 48 forms, in the bearing opening 89 along a longitudinal axis 35 can be inserted. Then, by the Spreizan drive 50 of the actuating body 43 to the spreader elements 41 and 42 out, causing them radially outward, transversely to the longitudinal axis 35 are adjusted relative to each other (arrow <61) and occupy an expansion position, in which the spreading in the 41st and 42 exert a compressive force in the bearing opening 89 radially outward on the components 91 and 92 of the motor component 80.

The spreading elements 41 and 42 are provided with holding portions 49 e.g. on the carriage 29 mounted transversely to the longitudinal axis 35 movable.

The two spreading elements 41 and 42 form the expanding mandrel 48

The introduction of force or the compressive force during fracture separation he follows in the bearing opening 89 in the region of Bruchtrennfläche] 90, ie in the region of opposing predetermined breaking points 95, where the notches 88 are already mounted in one embodiment of the invention. The outer peripheries 46 of the two spreading elements 41, 42 are substantially cylindrical. This corresponds to the cylindrical inner contour of the inner circumference 94 of the engine component 80 in the region of the bearing opening 89. In this respect, the overall outer contour of the two outer peripheries 46 would fit exactly into the bearing opening 89, so that a uniform pressure would result there , According to the invention, however, this is not what is desired, but the introduction of force should occur in the region of the two predetermined breaking points 95.

An outer circumference surface 51, which defines an outer circumference 46 of the spreading elements 41, 42, projects abutment surfaces 52, 53, 54 and 55 radially outwards, i. that the

Spreading elements 41, 42 with the contact surfaces 52-55 come into contact with the inner circumference 94 of the bearing opening 89 during fracture separation, the contact surfaces 52-55 acting on contact areas 96-99 of the inner circumference 94 of the bearing opening 89. The contact areas 96-99 are also planar, corresponding to the contact surfaces 52-55.

The contact surfaces 52-55 protrude in front of the outer circumferential surface 51. The contact surfaces 52-55 have an outer contour which corresponds to the outer peripheral surface 51 substantially, that is approximately cylindrical. As a result, the abutment surfaces 52-55 lie flat against the abutment region 96-99, thus exerting even pressure.

The abutment surfaces 52-55 each have a fracture separation surface angular distance 56 from the predetermined breaking point 95 or the fracture separation surfaces 90. Thus, the expansion element arrangement 45 does not press directly onto the predetermined breaking point 95, but acts somewhat laterally on the bearing opening 89. The contact surfaces 52-55 are present strip-shaped. They extend overall over a contact angle range 57 of, for example, 60-90 °, wherein in the present case 90 ° is selected.

Furthermore, the contact surfaces 52-55 do not extend over the entire height 100 of the bearing opening 89 (with respect to the longitudinal axis 35), but only over part of it. In the present case, the abutment surfaces 52-55 are made so that they each have a longitudinal distance 58 both to the upper end face 101 of the engine component 80 and to the opposite, not visible in the drawing end face of the engine component 80. Overall, therefore, the contact surfaces 52-55 are approximately at the center or the center of the longitudinal direction with respect to the height 100 or the longitudinal axis 35 in the bearing opening 89 during fracture separation.

It then turns out advantageously a fracture profile shown schematically in Figure 7, that is, the main pressure force 59 acts, so to speak, in the center of the longitudinal axis 35 in the abutment areas 96-99 on the bearing opening 89, so that centered on the longitudinal axis 35 in the bearing opening 89, so that one shown by arrows Break course or course of the separation of the two components 91 and 92 from each other. It can be seen that, in the region of the fracture separation surface 90 opposite the force arrow of the pressure force 59, ie in a section 103 of the engine component 80, no "separation arrows" run directly towards each other, so that the fracture separation surface 90 is uniform and substantially without a step just in this section 103 represents.

This is a difference to the prior art, that is, a quasi-conventional fracture separation, in which the introduction of force is not approximately centrally in the region of the mounting channel 87, but as a rule over the entire height 100 of the load. The opening is over. However, the main contact pressure 60 is particularly effective next to the mounting channel 87 because the wall 102 to the mounting channel 87 of the pressing force 60 can make less resistance, so something evades.

It is understood that instead of the substantially rectangular contact surfaces 52-55, for example, circular or elliptical contact surfaces are possible. Furthermore, for example, each of the contact surfaces 52 in the circumferential direction of the spreading 41, 42 may be provided with an interruption, so that, for example, two or three or more strip-shaped contact surfaces are formed, which extend beyond the outer periphery 46 and extend transversely to the longitudinal axis 35.

Larger or smaller fracture separation surface angular distances than the fracture separation surface angular distance 56 may also be provided.

Also, the attachment -Winkelbere ^' ich 57 can be larger or smaller. The contact angle range 57 need not be symmetrical with respect to the predetermined breaking points 95. For example, the contact surfaces 52 and 53 may extend over a larger angular range of the outer circumference 46 than the two other contact surfaces 54 and 55.

It is also possible that instead of an outer peripheral portion continuously extending contact surfaces, as in the contact surfaces 52-55 of the case, also be provided contact surfaces, which have a peripheral portion to each other. For example, it can be imagined that the abutment surfaces 52 and / or 53 are subdivided with respect to the outer periphery 46, i. each having two peripheral portions 53a, 53b.

Claims

claims

1. fracture separation device for fracture separation of an engine component (80), in particular a connecting rod (81), with a

Expansion element arrangement (45) with a first expansion element (41) and at least one second expansion element (42), and an actuating body (43) for actuating the expansion element arrangement (45) from a positioning position into an expanded position for separating a first component (91) of the engine component (45). 80), in particular a connecting rod cover (86), of a second component (92) of the engine component (80), in particular a connecting rod (85), wherein the spreading elements (41, 42) in the positioning position along a longitudinal axis (35) in a bearing opening (89) of the engine component (80) are insertable and in the spread position with abutment surfaces (52-55) on its outer periphery (46) against an inner circumference (94) of the bearing opening (89) press, so that the first component (91) of the second component (92) of the engine component (80) breaks away to form fracture separation surfaces (90), wherein the fracture separation surfaces (90) extend radially away from the bearing opening (89), characterized gekennz eichnet that the contact surfaces (52-55) of the Spreizelementanordnung (45) for abutment on the bearing opening (89) on both sides of a predetermined breaking point (95) for the respective break separation surface (90) each comprise a contact surface (52-55), wherein these contact surfaces (52-55) in a contact angle range (57) of a total of 35 ° to 120 ° around the predetermined breaking point (95) around and each lie flat against the inner circumference (94) of the bearing opening (89), and wherein a total of at least four contact surfaces (57 52-55) of the spreading Element arrangement (45) for abutment with the bearing opening (89) are present.

2. fracture separation device according to claim 1, characterized in that the contact angle range (57) of the contact surfaces (52-55) is a total of about 60 ° to 90 °.

3. fracture separation device according to claim 1 or 2, characterized in that an outer radius of one or all of the contact surfaces (52-55) an inner radius at a respective portion of the inner circumference (94) of the bearing opening (89) substantially corresponds and / or that one or all abutment surfaces (52-55) are cylindrical and / or one or all abutment surfaces (52-55) have no curvature relative to the longitudinal axis (35) or a curvature corresponding to the curvature of the inner circumference (94) of the bearing aperture (89), such that the respective contact surface (52-55) rests flat on the respective inner peripheral portion. , Fracture separation device according to one of the preceding claims, characterized in that between the contact surfaces (52-55) of the Spreizelementanordnung (45) associated with one of the components (91, 92) of the first and second components, an angular distance is present such that the Spreizelementanordnung (45) in a crest region of the bearing opening (89) between the fracture separation surfaces (90) not or not in the sense of pressing on the inner circumference (94) of the bearing opening (89) is applied and the pressure introduction during fracture separation in the contact angle range (57 ) and thus in the region of the fracture separation surfaces (90).

5. Fracture separation device according to one of the preceding claims, characterized in that at least one abutment surface (52-55) or all abutment surfaces (52-55) has a fracture Have separating surface-angular distance (56) to the respective fracture separation surface (90), so that by the at least one contact surface (52-55) or all contact surfaces (52-55) directly to the fracture separation surface (90) no direct pressure introduction takes place in the expanded position.

6. fracture separation device according to any one of the preceding claims, characterized in that the Bruchtrennflächen- angular distance (56) in a range of about 1-15 °, more preferably between 2 and 13 ° and even more preferably in a range between 5 ° and 12 ° lies.

7. fracture separation device according to one of the preceding claims, characterized in that at least one contact surface (52-55) during the fracture separation with respect to the longitudinal axis (35) has a longitudinal spacing (58) to at least one longitudinal end of the bearing opening (89) on an end face (101). of the engine component (80).

8. fracture separation device according to one of the preceding claims, characterized in that at least one contact surface - (52-55) or all contact surfaces (52-55) are strip-shaped or circular.

9. fracture separation device according to one of the preceding claims, characterized in that the first expansion element (41) and / or the at least one second expansion element (42) has a semicircular outer periphery (46), wherein the respective contact surfaces (52-55) of this expansion element ( 41, 42) are provided in the region of the respective longitudinal ends of the semicircle and / or in the region of the vertex of the outer circumference (46) of the respective expansion element (41, 42) no contact surface (52-55) is present.

10. fracture separation device according to one of the preceding claims, characterized in that the first expansion element (41) and the at least one second expansion element (42) each have an outer periphery (46) corresponding to a semicircle of about 180 °, wherein the fracture separation surfaces (90) extending diametrically away from the bearing opening (89).

11. fracture separation device according to one of the preceding claims, characterized in that the Spreizelementanordnung (45) on an expanding mandrel (48) is provided or an expanding mandrel (48) and / or the first expansion element (41) of the first component (91) and the at least one second expansion element (42) of the second component (92) of the engine component (80) are assigned and exert pressure in the spread position on the respective associated component (91, 92) of the engine component (80).

12. fracture separation device according to one of the preceding claims, characterized in that between the actuating body (43) and the first expansion element (41) and / or the at least one second expansion element (42) is provided a wedge surface arrangement and / or the actuating body (43) a spreading drive (50) can be driven.

13. fracture separation device according to one of the preceding claims, characterized in that it forms part of a machine tool (10) and / or a machining center.