ASSEMBLY COMPRISING TWO CONSTRUCTIONALLY CONNECTED COMPONENTS

专利摘要:
The invention relates to an assembly (1) comprising at least a first metallic component (2) having a first surface region (5) and a second metallic component (3) having a second surface region (7), the two surface regions (5, 7) facing each other are facing, and the first and the second component (2, 3) at least in a partial region of the two surface regions (5, 7) are integrally connected to each other, and wherein at least one of the two metallic components (2, 3) is a sintered component, wherein the surface region (7) of the sintered component having cohesive connection has a higher density than the subsequent further surface regions of the sintered component.
公开号:AT510985A4
申请号:T1075/2011
申请日:2011-07-22
公开日:2012-08-15
发明作者:
申请人:Miba Sinter Austria Gmbh；
IPC主号:

专利说明:

-'Ί
The invention relates to an assembly comprising at least a first metallic component having a first surface region and a second metallic component having a second surface region, wherein the two surface regions facing each other, and the first and the second component at least in a portion of the two surface regions integrally connected and wherein at least one of the two metallic components is a sintered component, and a method for materially connecting a first metallic component having a first surface region with a second metallic component having a second surface region, wherein the two surface regions facing each other, and wherein at least one the two components is a sintered component.
For the connection of a gear with a coupling body are already known from the prior art a variety of methods.
For example, EP 0 563 949 A1 discloses a method for producing a two-part component, namely a toothed wheel with a coupling body on a seat of the toothed wheel, in particular for synchronous transmission, in which the toothed wheel and the coupling body are manufactured individually and then firmly connected to each other, including one the two parts heated and then connected to the other part by shrink fit. It is thus made a gear with coupling body, bet the gear and the coupling body are connected to each other not only by frictional engagement but also by positive engagement. N2011 / 16200
'* -Ί-
DE 10 2006 028 286 A1 describes gearwheels consisting of a gearwheel and a clutch body, which, when fitted together in their common connection fitting, have a profile deviating from an exact circle diameter, e.g. any polygon shape. In order to prevent the two parts from slipping apart, an adhesive is provided in the joint fit, the two parts being displaced relative to each other until a " seizure " the desired connection strength is achieved. Then the area is caulked.
GB 2 320 032 A describes a method for producing a sintered component of different diameter along the main axis by connecting two partial bodies and then sintering together.
From US 3,678,557 A a method is known, according to which a cast gear is connected to a coupling body made of sintered metal by welding.
The WO 2011/038790 A1 describes an arrangement comprising a gear and a coupling body, which is positively connected to the gear for transmitting a rotational movement, wherein the gear and the coupling body on facing end faces each have a geometry which in conjunction with the geometry of each other component forms a positive connection, wherein the gear and the coupling body is formed in each case as a sintered component and wherein in the gear and the coupling body, the respective end-side geometry is pressed through which the gear and the coupling body are mutually positionable. The gear and the coupling body may additionally be connected to one another in a material-locking manner.
The object of the present invention is to improve the weldability of a Sin-termetalibauteils with another metallic component.
This object is achieved independently by the aforementioned assembly and the aforementioned method, wherein in the assembly of the, the material connection having surface portion of the sintered component N2011 / 16200 .. .3 has a higher density than the adjoining these further surface areas of the Sintered component, and provided by the method is that before the formation of the material connection of the two components together in the Oberflächenberetch of the sintered component, the density is increased.
The advantage here is that by compacting the surface region of the sintered component, in which the welding night is attached, before the welding of the two components together a reduction in the porosity of the sintered material is achieved. It is thus prevented that washing liquids - usually the sintered components are cleaned before welding at least in the area of the later weld - evaporate out of the pores during welding, as a result of which the voids formation in the weld is avoided or at least reduced. The bond strength of the component can thus be increased. Compared to the solution according to WO 2011/038790 A1, according to which a positive connection between the components is produced, the assembly of the invention also avoids an axial thrust when transmitting torques. Another advantage is that the only partial compaction, the porosity is maintained in other areas of the sintered component, a properties that is desired in itself with sintered components, especially when it comes to so-called wet-running sintered components, ie sintered components during the Operation are supplied with a lubricant to reduce friction and cooling, since the pores are known to act as lubricant pockets.
Preferably, the surface area of the sintered component has a density of at least 95% of the full density of the material, whereby the above-mentioned effects of improved weldability can be further improved. It also makes it possible to use welding methods more efficiently, which are problematic in the field of sintered components, in particular laser welding or electron beam welding.
Due to the increased friction at the end faces, the deformation is at least largely prevented by the compression of the surface area. Un- N2011 / 16200 «» »I · ν ·« »» I · ν ·
Within this surface area, the so-called "blacksmith's cross" arises with high tensile stresses on the side areas and high shear stresses in the center area. In order to avoid too high stresses in the sintered component in the region of the weld, it is therefore advantageous if the surface region of the sintered component has a width which corresponds at least to the width of the weld seam and at most seven times to the weld seam width. The upper limit is chosen with regard to the desired porosity, since a wider, compacted region does not further improve the weldability of the sintered component. In this case, if the compacted area of the sintered component has a larger cross-sectional area than the cross-sectional area of the weld seam, it is preferred to observe in the same direction, since negative influences of the washing medium from areas of the sintered component adjoining the weld area can be better avoided or the welding process per se can be made simpler.
It is also advantageous if the sintered component is compacted in the surface area to a depth of at least the Schweißnahtbereite to safer during the heating of the sintered component during welding, the formation of flaws in the weld or in near-surface areas below the weld by gas emissions of the washing medium to avoid.
It is also possible that both metallic components are designed as sintered components, wherein both the first surface region of the first sintered component and the second surface region of the second sintered component are compacted. It can thus all the known advantages of sintering technology, such. the simple production of complex geometries to be realized throughout the assembly.
According to a preferred embodiment of the assembly is provided that the first component is designed as a gear and the second component as a coupling body of a transmission synchronization.
According to an alternative embodiment of the method, it is provided that, for the production of the compacted surface area, the latter is produced with an excess N2011 / 16200
• * «·» »· is being set. It is in this way the compaction of the surface area produced by simple displacement of material in the component in this area.
It is particularly advantageous if the compression of the surface area is carried out during the calibration of the sintered component. Since the calibration of the sintered component usually belongs to the process sequence for the production of the assembly to increase the component accuracy anyway, an additional process step for the production of the surface compression is saved in this way, whereby the process can be made more efficient.
It can also be provided that the two metallic components are cured only after bonding, whereby the quality of the weld and the entire assembly can be improved.
For a better understanding of the invention, this will be explained in more detail with reference to the following figures.
Each shows in a schematically simplified representation:
Fig. 1 shows an assembly cut in side view;
Fig. 2 shows a coupling body cut in side view;
Fig. 3 shows a variant of a coupling body cut in side view;
4 shows a weld seam according to the prior art;
5 shows a weld seam between two components with compressed surface areas;
6 shows a detail of a variant of a coupling body cut in side view;
Fig. 7 shows a detail of a variant of a coupling body cut in side view. N2011 / 16200 • · «» - • · T5 - *
By way of 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, wherein the disclosures contained in the entire description can be mutatis mutandis to the same parts with the same reference numerals or component names. Also, the location information chosen in the description, such as top, bottom, side, etc. related to the immediately described and illustrated figure and are to be transferred to the new situation mutatis mutandis when a change in position.
1 shows an assembly 1 comprising one or consisting of a first metallic component 2 and an independent second metallic component 3. The first component 2 has a first surface 4 which comprises a first surface region 5. The second component 3 has a second surface 6 which comprises a second surface region 7. The second component 3 is arranged on the first component 2 so that the two surfaces 4, 6, and thus also the two surface regions 5, 7, face each other. For example, the second component 3 is arranged on a hub-like projection 8 of the first component 2, which extends along a central axis 9. The two components 2, 3 are materially connected, in particular welded, to one another in at least one subregion of the surface regions 5, 7, wherein the two surface regions 5, 7 are arranged at least approximately immediately adjacent to one another - in the direction of the central axis 9.
Preferably, the first component 2 is a gear, in particular a gear, and the second component 3 is a coupling body, such as such components are used in gear synchronizers. In principle, the assembly 1, however, also differently shaped metallic components 2, 3, which are connected to each other cohesively, For example, the coupling body may also be connected to a sprocket or a hollow shaft. It is also possible that the first component 2 is a shaft, and the second component 3 is a synchronizer hub which is connected to the shaft. The latter does not have to have the usual serration in this case. N2011 / 16200 «· • · *» * * 7- * •
At least one of the two metallic components 2, 3 is a sintered component, i. produced by a sintering process. Preferably, the coupling body, so the component 3, a sintered component.
Since sintering processes are known from the prior art, reference is made to the relevant literature for details. Typically, sintering processes include the steps of optionally powder blending, powder pressing into a green compact, sintering, post-processing of the sintered component. Optionally, a two-stage sintering can be performed with a pre-sintering step.
The sintered component may for example consist of a commonly used steel powder. However, other metal powders (mixtures) within the scope of the invention for producing the sintered component are also usable. As regards the commonly used metal powders, reference should also be made to the relevant literature and the relevant standards which form part of the content of the present description.
The other component, that is to say in particular the metallic component 2, can consist of a solid material, that is to say, for example, of steel or another metal or another metal alloy. For example, the component 2 may be a cast component that is optionally machined by machining.
In an alternative embodiment, however, the component 2 may also be designed as a sintered component. Reference is made to the above comments on the sintering of the component 3. The following comments on the sintered component, i. the component 3, are therefore applicable to this embodiment of the component 2 to this.
However, it is also possible that the component 2 is designed as a sintered component and the component 3 made of a solid material.
To improve the cohesive connection, in particular the weldability of the sintered component, ie in particular of the component 3 and / or the component 2, it is provided that at least in that part of the surface 6 and / or 4, in which the additional material for the formation of cohesive Connection N2011 / 16200 fr • • • • • • • • «« * l · • ·
is applied, so in particular the weld is formed, this is compacted prior to the production of the cohesive connection. This part of the surface 6 and / or 4 corresponds to the above-mentioned surface regions 5 and / or 7 of the components 2 and / or 3, wherein the cohesive connection can also be formed only in a portion of these surface regions 5 and / or 7. The surface areas 5 and / or 7 thus have a higher density compared to the surface areas 5 and / or 7 surrounding the further surface areas of the components 2 and / or 3. Of course, the immediately below the surface regions 5 and / or 7 lying areas of the components 2 and / or 3 due to the compression also have a higher density, optionally higher than underlying core layers of the component 2 and / or 3, so in the context of the invention the densification of the surface area 5 and / or 7 is not just exactly the surface itself meant.
One possibility of forming the compacted surface regions 5 and / or 7 is shown in FIG.
Fig. 2 shows the formed as a coupling body for a transmission synchronization component 3 in side view cut and simplified. The component 3 has a component body 10 on which on a radially outwardly facing end face 11 has a conventional toothing 12 for engagement of a sliding sleeve of the transmission synchronization. In the region around the center axis 9, an opening 13 or a bore is formed into which the hub-shaped projection 8 of the component 2 (FIG. 1) can be inserted. The surface area 7 to be compacted is located immediately adjacent to the opening 13, since in this area, in the illustrated embodiment, the integral connection with the component 2 takes place.
It should be noted that the exact location of the compacted surface area 7 is dependent on the location at which the cohesive connection is to be formed. In other words, the location of this surface area 7, depending on the assembly, can deviate from the situation illustrated in FIG. 2, so that the illustrated placement is not restrictive for the invention ,
To achieve the compaction of the component 3 is made in the region of the surface region to be compacted 7 with an oversize, so that thus produced after sintering semi-finished product has a projection 14 which is formed in the illustrated embodiment of the component 3 as a ring land. In a post-sintering compacting step, this projection 14 can be pressed into the material of the component body 10 with the aid of a suitable pressing die or another suitable compaction tool, whereby a compacted zone 15 is produced in this surface region 7, which is indicated by dashed lines in FIG.
Alternatively, there is also the possibility that the compaction takes place before the sintering, by the green compact is carried out during powder pressing in this area with a correspondingly higher amount of powder.
The compacted surface region 7 is preferably made of the same material as the remaining component body 10. However, it is also possible to arrange in this surface region 7 a material with a different composition for the composition of the material of the rest of the component body 10, for example with a composition that facilitates the compaction or has the more favorable properties in terms of cohesive connection. The introduction of this additional material can in turn be carried out during the powder pressing, for example, by providing a corresponding recess for this purpose in the powder press, or after sintering by placing on the sintered semi-finished product, it being possible in the latter case due to better handling that the Additional material also already compacted and optionally sintered. Likewise, this filler material can be placed in a two-stage sintering process after pre-sintering and sintered together with the other material.
The projection 14 may, for example, have a height 16 in the direction of the central axis 9, which is selected from a range with a lower limit of 3 N2011 / 16200 -0- *% and an upper limit of 150%, in particular a lower limit of 5%. and an upper limit of 40%, a component height 17 in this range.
Preferably, the compaction is performed so far that this surface region 7 of the sintered component has a density of at least 95%, in particular at least 97%, preferably at least 98%, the full density of the material of the component 3 or of the additional material used.
Due to the compression of the surface area 7, in the illustrated embodiment, an annular, compressed zone 15 is formed around the opening 13, the surface 6 being planar even after compaction or corresponding to the desired component geometry of the finished component in this area, ie no additional compression due to compaction Projections are present - although this is possible in principle.
It should be noted that the rectangular shape of the compressed zone 15 shown in FIG. 2 is simplified or idealized. In practice, a different course of this condensed area arises in the illustrated embodiment variant due to the formation of the so-called "blacksmith cross". during the compression. For this reason, it is advantageous if the surface area 7 of the sintered component has a width 18 which is at least the width of the material connection, that is, for example, a weld width, in particular at least 1.5 times, preferably at least twice, this width, and at most seven times the width of the cohesive connection corresponds. It can thus be set a compromise between the size of the compacted area and mechanical stress of the compaction tool, since with increasing size of the compacted zone, the load of the tool increases.
A depth 19 of the compressed zone 15 in the direction of the central axis 9 can correspond at least to the width of the integral connection, wherein the compression can also be carried out over the entire component height 17, N2011 / 16200
To clarify that the compacted surface region 7 or the compressed zone 15 can also be embodied differently, FIG. 3 shows the component 3 in cross-section and simplified representation, which can likewise be designed as a coupling body, with a boundary line 20 extending at an angle to the central axis 9 This compressed zone 15 is likewise achieved by the pressing or pushing in of the projection 14 (not shown in FIG. 3), wherein the compacting tool acts on the component body 10 at an angle to the central axis.
With the method according to the invention, when using a sintered steel, the compacted region can have, for example, a density of more than 7.5 g / cm.sup.3, while the remaining region of the component body has a density of less than 7.5 g / cm.sup.3 (= basic density).
The compression of the surface region 7 is, as already stated above, preferably carried out during the calibration of the sintered component with a corresponding calibration tool, for example a sizing press. The calibration is known to increase the dimensional accuracy of a sintered component.
Optionally, at least the sintered component, preferably the entire assembly 1, can be hardened after bonding, for example by case hardening. Finally, a hard fine machining of the assembly 1 or of the sintered component can be carried out, for example, on the bearing points or on cone or flat surfaces. The hard fine machining also increases the accuracy of the component geometry.
The cohesive joining of the two components 2, 3 with each other at least in a partial area whose surface can be carried out with or without a filler material. If a filler material is used, this corresponds to the prior art to cohesive connections. In particular, the two components 2, 3 are welded together, although other methods, such as soldering, are possible. Preferably, the two components N2011 / 16200 Ί2- * 2, 3 are connected to each other by laser welding or electron beam welding.
To illustrate the effect achieved by the invention, a weld 21 between the component 2 and the component 3 is shown in FIG. 4 - The two components 2, 3 correspond to the prior art, so have no densified zones 15. As a result of the washing medium evaporating out of the pores of the sintered component 3 during welding, voids 22 are produced in the weld seam 21, which lead to a weakening of the weld seam 21.
In contrast, Fig. 5 shows a welded assembly 1 according to the invention, in which case both components 2, 3 are designed as sintered components and in each case in the region of the weld 21, the compressed zone 15. However, it should be expressly pointed out that within the scope of the invention it is also possible that one of the two components 2, 3 is not a sintered component but a solid material component.
As can be seen from FIG. 5, the weld seam 21 is formed free from voids.
FIGS. 6 and 7 show alternative embodiments of the compression of the surface area 7 in the case of components 3, in particular coupling bodies. In this case, the compression of the surface region 7 is not produced by pressing in an additional amount of material, but is generated by the compression of a recess 23, which may optionally be undercut or bevelled. This recess 23 is subsequently at least approximately completely filled with the welding material in the material-locking connection, preferably. It is shown that based on the embodiment of the component 3 of FIG. 2, an annular groove or in accordance with the embodiment of the component 3 of FIG. 3, a bevel can be generated.
Of course, within the scope of the invention it is also possible for a plurality of compressed surface regions 7 to be formed. Likewise, there is the possibility of a combination of a planar, compacted surface area 7 with a densified surface area 7 recessed to form the recess 23 in a component 2 and / or 3.
Furthermore, the designs of coupling bodies shown in FIGS. 2, 3, 6, 7 can only be seen by way of example. These can generally have a geometry corresponding to the state of the art, that is to say they can also be designed, for example, with a cone.
The embodiments show possible embodiments of the assembly 1 and the components 2, 3, it being noted at this point that also various combinations of the individual variants are possible with each other and this possibility of variation due to the doctrine of technical action by representational invention in the ability of this technical expert.
For the sake of order, it should finally be pointed out that in order to better understand the construction of the assembly 1 or the components 2, 3, these or their components have been shown partly unevenly and / or enlarged and / or reduced in size. N2011 / 16200 • * * * * * *
REFERENCE NUMBERS
module
component
component
surface
surface area
surface
surface area
head Start
central axis
component body
face
gearing
breakthrough
head Start
Zone height
component height
width
depth
boundary line
Weld
Lunker
Recess N2011 / 16200

权利要求:
Claims (10)
[1]
1. Assembly (1) at least comprising a first metallic component (2) with a first surface region (5) and a second metallic component (3) with a second surface region (7), wherein the two Surface regions (5, 7) facing each other, and the first and the second component (2, 3) at least in a partial region of the two surface regions (5, 7) are integrally connected to each other, and wherein at least one of the two metallic components (2, 3) is a sintered component, characterized in that the, the cohesive compound having surface portion (7) of the sintered component has a higher density than the subsequent thereto further surface regions of the sintered component.
[2]
2. Assembly (1) according to claim 1, characterized in that the compacted surface region (7) of the sintered component has a density of at least 95% of the full density of the material.
[3]
3. Assembly (1) according to claim 1 or 2, characterized in that the compacted surface region (7) of the sintered component has a width (18) which corresponds to at least one Schweißnahtbereite and a maximum of seven times the Schweißnahtbereite.
[4]
4. Assembly (1) according to claim 3, characterized in that the sintered component in the compacted surface region (7) is compressed to a depth (19) of at least the Schweißnahtbereite.
[5]
5. Assembly (1) according to one of claims 1 to 4, characterized in that both metallic components (2, 3) are designed as sintered components and that both the first surface region (5) of the first metallic component (2) and the second Surface region (7) of the second metallic component (3) are compressed. N2011 / 16200
[6]
6. assembly (1) according to one of claims 1 to 5, characterized in that the first component (2) as a gear and the second component (3) are designed as a coupling body of a transmission synchronization.
[7]
7. A method for materially joining a first metallic component (2), which has a first surface area (5), with a second metallic component (3), which has a second surface area (7), wherein the two surface areas (5, 7) be facing each other, and wherein at least one of the two components (2, 3) is a sintered component, characterized in that prior to the formation of the material connection of the two components (2, 3) with each other at least in the surface region (7) of the sintered component in which the cohesive connection is formed, the density is increased.
[8]
8. The method according to claim 7, characterized in that for the production of the compacted surface area (7) this is produced with an oversize.
[9]
9. The method according to claim 7 or 8, characterized in that the compression of the surface region (7) is carried out during the calibration of the sintered component.
[10]
10. The method according to any one of claims 7 to 9, characterized in that the two metallic components (2, 3) are cured after the cohesive bonding. Miba Sinter Austria GmbH

Lawyer GmbH N2011 / 16200

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法律状态:

优先权:

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申请号 | 申请日 | 专利标题

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ATA1075/2011A|AT510985B1|2011-07-22|2011-07-22|ASSEMBLY COMPRISING TWO CONSTRUCTIONALLY CONNECTED COMPONENTS|ATA1075/2011A| AT510985B1|2011-07-22|2011-07-22|ASSEMBLY COMPRISING TWO CONSTRUCTIONALLY CONNECTED COMPONENTS|

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US14/233,931| US9956614B2|2011-07-22|2012-07-11|Assembly having two components connected cohesively together|

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CN201280035440.XA| CN103687684B|2011-07-22|2012-07-11|Comprise the assembly of the component that two mutual materials connect in locking manner|

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PCT/AT2012/050100| WO2013013254A1|2011-07-22|2012-07-11|Assembly having two components connected cohesively together|

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BR112014001442A| BR112014001442A2|2011-07-22|2012-07-11|two-piece mounting assembly joined by material joining|

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EP12750518.8A| EP2734324B1|2011-07-22|2012-07-11|Method for material fit joining of two metallic components|