• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
  • 引用文献
  • 法律状态
  • 优先权
    • 专利摘要:
    The invention relates to a method for producing a stator (6) for a camshaft adjuster (2), wherein the stator (6) comprises an annular base body (9) with an outer spur toothing (4) and with a radially inner lateral surface (10) of the Base body (9) radially inwardly projecting, spaced apart in the circumferential direction of the base body (9) webs (11) is produced, comprising the steps of providing a mold for integrally forming the base body (9) with the spur gear (4) and the radially inward projecting ridges (11), filling a metallic powder into the mold, pressing the powder into a green compact and sintering the green compact into a stator blank. The spur toothing (4), the radially inwardly facing lateral surface (10) of the base body (9), which has been formed between the webs (11), and on the lateral surface (10) adjacent side surfaces (16) of the webs (11) compacted without previous mechanical processing in several steps to the desired final dimension.
    公开号:AT519135A1
    申请号:T50849/2016
    申请日:2016-09-22
    公开日:2018-04-15
    发明作者:
    申请人:Miba Sinter Austria Gmbh;
    IPC主号:
    专利说明:

    The invention relates to a method for producing a stator for a camshaft adjuster, wherein the stator is produced with an annular base body with an end toothing and with radially inwardly projecting from a radially inner surface of the body radially inwardly spaced webs in the circumferential direction of the body comprising the steps of providing a mold for integrally forming the body with the face gear and the radially inwardly projecting lands, filling a metallic powder into the mold, pressing the powder into a green compact, and sintering the green body into a stator blank.
    Furthermore, the invention relates to a stator for a camshaft adjuster comprising an annular base body having on its outer circumference a spur gear teeth and on an inner circumferential surface a plurality of radially inwardly projecting and spaced-apart webs.
    Camshaft adjusters are known to adapt the valve opening times in order to achieve a higher efficiency of an internal combustion engine. They are known in various designs from the prior art. A generic hydraulic phaser comprises a stator in which a rotor is arranged. The rotor is rotatably connected to the camshaft, The stator, which is connected to the crankshaft, has radially inwardly projecting webs which form abutment surfaces for the blades of the rotor. Thus, the rotor can be rotated only in a predefined angular range relative to the stator.
    The present invention has for its object to simplify the production of a stator for a camshaft adjuster or specify a stator produced by the method for a camshaft adjuster.
    The object of the invention is achieved with the method mentioned above in that the spur toothing, the radially inwardly facing surface of the base body, which is formed between the webs, and adjacent to the lateral surface side surfaces of the webs without prior mechanical processing in several steps on the desired final dimension are compacted.
    Furthermore, the object of the invention with the aforementioned stator is achieved, in which the spur toothing, the radially inwardly facing surface of the base body, which is formed between the webs, and adjacent to the lateral surface side surfaces of the webs as mechanical processing exclusively have a compression, wherein a density gradient is formed from a surface in the direction of a core layer.
    Thus, the outer toothing, the radially inwardly facing lateral surface of the base body, which is formed between the webs, as well as the side surfaces of the webs of the stator adjacent to the lateral surface, are already in net-shape or net-shape during pressing and sintering of the powder Quality made. Thus, to improve the component strength only more subsequent to sintering surface compaction is required. By avoiding the mechanical processing of said surfaces of the stator - with the exception of the surface compaction - this can be made easier, with not only the stator per se can be made easier by avoiding a machining machining, but it can also the tightness of the hydraulic Camshaft adjuster improved or easier to achieve. By the method, a risk of the entry of chips in the fluid system of the camshaft adjuster can be avoided. The multi-stage densification of the surfaces achieves that a density gradient is formed in the direction of the core layer of the stator, which has an abrupt transition from the compressed to the non-compressed zone. Thus, the property profile of the stator can be better adapted to the requirements in the camshaft adjuster. The gradual compaction also has an advantage when it is followed by a surface hardening. It can thus be better adjusted the depth of the curing, so that therefore the core layer can remain uncured and thus has a corresponding toughness, which has a positive effect on the fracture behavior of the stator.
    According to a variant embodiment of the method, it can be provided that the radially inwardly directed lateral surface of the base body and the side surfaces of the webs are compacted in a single working step. It is thus achieved a corresponding reduction of the machining time of the stator, whereby its manufacturing costs can be reduced.
    It is also possible that the outer teeth, the radially inwardly facing surface of the base body, and the side surfaces of the webs are compressed simultaneously, whereby the just mentioned effects can be further improved.
    According to another embodiment of the method or the stator can be provided that between the webs and the spur toothing a hub is formed on which a second spur gear is or is arranged, wherein a spur toothing of the second spur gear with the same geometry with respect to the cross section of Teeth in the axial direction, the division and the module is made or formed. It can thus be considered at the same time with the sintered component, the formation of the stator as a so-called split gear, so that the outer teeth of the stator play-free in the teeth of another gear that is in mesh with the stator mesh. By the game release shocks can be avoided on the teeth of the outer teeth of the stator. This in turn has a positive effect on the permanent load capacity of the teeth of the external toothing of the stator, which in the simplest case "only" have a surface compression to improve the component strength.
    On the other hand, it is also possible that the spur toothing of the stator and the webs of the stator are case hardened before or after compaction to a maximum depth of 1.5 mm, so that the spur toothing and the webs have a surface hardness of at least 500 HV 5. It can thus be further improved the component strength. It has been found that a maximum depth of 0.4 mm is to be preferred, since this better preserves the component toughness in the core layer of the stator.
    For a better understanding of the invention, this will be explained in more detail with reference to the following figures.
    Each shows in a simplified, schematic representation:
    1 shows a detail of a camshaft adjuster;
    FIG. 2 shows the stator and the rotor of the camshaft adjuster according to FIG. 1 in a front view; FIG.
    3 shows a section through an embodiment of a stator and a rotor of a camshaft adjuster in oblique view;
    Fig. 4 shows the stator and the rotor of FIG. 3 with a further spur gear.
    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 to transmit mutatis mutandis to the new situation in a change in position.
    In Fig. 1, a section of an internal combustion engine 1 is shown. A camshaft adjuster 2 and a drive wheel 3 can be seen. The camshaft adjuster 2 has an end toothing 4 on its outer circumference. Likewise, the drive wheel 3 at its outer periphery on a spur gear 5 on. The two serrations 4, 5 are in meshing engagement with each other.
    In principle, this design of hydraulic camshaft adjusters 2 is known from the prior art, so that further explanations are unnecessary.
    The camshaft adjuster 2 has a stator 6 and a rotor 7, as can be better seen in FIG. 2, in which the representation of end covers 8 of the camshaft adjuster 2 (FIG. 1) has been dispensed with.
    The stator 6 has an annular base body 9, which - as already mentioned - has on its outer circumference the external toothing in the form of the face toothing 4. At a radially inner circumferential surface 10 of the base body 9 and projecting radially over these webs 11 are formed. In the specific case, the stator 6 has four webs 11. This number of webs 11 should not be understood as limiting. There may also be more or fewer webs 11. The webs 11 may, if necessary, be provided with a recess 12 or an opening in order to give the stator 6 a lower weight. The webs 11 are circumferentially spaced apart from each other on the base body 9 of the stator 6 is arranged.
    The stator 6 is a one-piece sintered component, so that therefore the spur toothing 4 and the webs 11 with the base body 9 form a single, integral sintered component.
    Within the stator 6 - as already mentioned, the representations of the covers 8 (FIG. 1) have been dispensed with - the rotor 7 is arranged. The rotor 7 also has a base body 13. On an outer lateral surface 14 of this main body 13 wings 15 are formed or arranged, which extend from the lateral surface 14 starting radially outward. In the assembled state of the camshaft adjuster 2, these wings 15 are arranged between the webs 11 of the stator 6. Side surfaces 16 of the webs 11 form the abutment surfaces for the wings 15 of the rotor 7, as shown in FIG. 2 can be seen.
    The number of wings 15 of the rotor 7 depends on the number of webs 11 of the stator 6, so in the specific case so four wings 15 are present.
    The rotor 7 is arranged rotatably in the circumferential direction relative to the stator 6, wherein the path of rotatability is limited by the webs 11.
    The stator 6 is a sintered component, i. that it is made by a sintering process. For this purpose, a metallic powder, for example a sintered steel powder, is introduced into a mold cavity of a mold. The mold cavity is formed as a negative mold of the stator 6. The metallic powder is then pressed into a green compact and the green compact sintered in one or more stages to form a Statorrohlung. In principle, such sintering methods are already described in the prior art, so that reference is made to further details concerning the sintering method.
    After sintering, the stator blank is compacted in several stages, i. at least the outer spur gearing 4, the radially inwardly facing lateral surface 10 of the base body 9, which has been formed between the webs 11, and adjacent to the lateral surface 11 side surfaces 16 of the webs 11. In addition, these surfaces or areas of Statorrohlings no mechanical Processing subjected, in particular no machining machining. It is thus with the method for producing the stator 6, a stator 6 with a near net shape, in particular in net shape, quality of the spur gearing 4, the radially inwardly facing lateral surface 10 of the base body 9, which has been formed between the webs 11 , And the side surfaces 16 of the webs 11 adjoining the lateral surface 11 are produced without further mechanical processing (with the exception of the compression). The compression is thus carried out to the desired final dimension of said areas of the stator. 6
    In particular, the compression immediately follows the sintering, so that, if appropriate, the still warm stator blank is compacted. But it can also be done a previous cooling of the stator blank.
    The mentioned compression takes place in several steps. It is possible that the stator blank is pressed by a plurality of compression dies, which are arranged one after the other in the manufacturing process. The clear width of the compression matrices decreases, in particular gradually. Preferably, a compaction die has a constant clearance.
    It should be noted at this point for the sake of completeness that the compression matrices have one of the spur gearing 5 of the Statorrohlungs corresponding contour.
    However, the multi-stage compaction preferably takes place in a single compaction tool that has several sections of decreasing clear width. In this case, sections with a constant clear width can be formed within the compression die. During the compression of the spur gear teeth 4 of the stator blank, this is not relaxed in this variant of the method.
    If the compaction is carried out with reversal of movement of the stator blank by the compacting die, the stator blank can be relaxed in a direction of movement after the last compacting step. For the multi-step compression of the radially inwardly facing lateral surface 10 of the base body 9, which has been formed between the webs 11, and the lateral surface 16 of the webs 11 adjacent to the lateral surface 11 of the webs 11, a corresponding rod-shaped compression tool is used, which is inserted into the stator blank , The multi-step compression can in turn be performed with several of these rod-shaped compaction tools or with a single rod-shaped compaction tool, analogous to the compaction of the spur gear 4, but with the difference that the outer cross-section of the rod-shaped compaction tools or the rod-shaped compaction tool becomes larger with increasing compression of the stator blank ,
    It should be noted that the stator blank is supported during compaction, for example with a punch. The stator blank may in particular be clamped between a lower punch and an upper punch during compaction.
    Radially inwardly facing surfaces 17 of the webs 11, so the radially innermost surfaces of the webs 11, if necessary mechanically, in particular machined, be reworked, but it is also possible, these surfaces 17 according to the method described above in near net-shape , especially in net-shape, to produce quality.
    The stator 6 produced by the method has due to the multi-stage compression at least in the region of the spur gearing 4, the radially inwardly facing lateral surface 10 of the base body 9, which is formed between the webs 11, and the side surfaces 16 of the webs 11 adjacent to the lateral surface 10 as mechanical processing exclusively a compression, wherein from a outer surface in the direction of a core layer of the stator 6, a density gradient is formed. The core layer of the stator 6 is that region which has the density that has after the green compact after the pressing of the powder. In other words, the core layer begins where the subsequent multi-step compaction ends.
    According to the preferred embodiment of the method, therefore, the spur toothing 4, the radially inwardly facing lateral surface 10 of the base body 9, and the side surfaces 16 of the webs 11 of the stator are compacted in one step. This is done for the spur gearing 4 with said compression die with decreasing clear width. The lateral surface 10 and the side surfaces 16 can be compacted with the rod-shaped compaction tool mitzunehmendem outer cross-section. The multi-step compression of the spur gearing 4 can take place before or after the multi-step compression of the lateral surface 10 and the side surfaces 16.
    It should be noted at this point that the term "multi-step" in the case of using only one compaction die or only a rod-shaped compaction tool in the sense of "multi-level" is to read.
    It can be provided according to a further embodiment of the method that the spur gearing 4, the radially inwardly facing lateral surface 10 of the base body 9 and the side surfaces 16 of the webs 11 are compressed simultaneously. For this purpose, the stator blank is inserted into the compaction matrix (s) and at the same time the rod-shaped compaction tool is introduced into the stator blank.
    FIGS. 3 and 4 show a further embodiment of the stator 6, which may be independent of itself, with the same reference numerals or component designations being used again for the same parts as in the preceding FIGS. 1 and 2. In order to avoid unnecessary repetition, reference is made to the detailed description of FIGS. 1 and 2.
    In this embodiment of the stator 6, the spur gear 4 (FIG. 2) is divided into two in the axial direction. A first face gear part 18 is formed by the stator 6 described above, which in this embodiment thus represents only a first stator part, a second face gear part 19 is formed by a further spur gear 20, which forms a second stator part.
    The first stator part comprises, in addition to the first spur gear part 18, the lateral surface 10 described above and the webs 11 with the side surfaces 16. The lateral surface 10 and the webs 11 have a greater length in the axial direction than the first spur gear part 18.
    To arrange the further spur gear 20 on the first stator part is - viewed in the radial direction - between the webs 11 and the first spur gear part 18, an annular hub 21 is formed. This hub 21 is already considered in the shaping of the green compact for the stator 6, so that it also forms an integral part of the first stator.
    In particular, the hub 21 is immediately adjacent to the webs 11, i. directly in the radial direction above the webs 11, formed.
    The further spur gear 20 has an end toothing, which has the same geometry with respect to the cross section of the teeth in the axial direction, the pitch and the module. It is thus the formation of the stator 6 as a so-called split gear for play clearance of the engagement of the teeth of the stator 6 in the spur gearing 5 of the drive wheel 3 (Fig. 1) possible. This will be the other
    Spur gear 20 is rotated in the circumferential direction relative to the first stator, so that therefore the first and the second face gear portion 18, 19 are not arranged congruently in the axial direction. Further, the further spur gear 20 is biased in the circumferential direction against the first stator, for example, with a so-called Ω spring, which is arranged in the axial direction between the first stator and the further spur gear 20 and which are at corresponding projections on the first stator and the other Spur gear 20 is supported. Since such training of gears for play clearance from the prior art are known, reference is made to further details on this prior art.
    In this two-part embodiment variant of the stator 6, the webs 11 in the axial direction are preferably viewed over the entire length of the stator 6 in the same direction.
    According to a further embodiment of the method can be provided that the spur gear teeth 4 (or the two spur gear teeth 18, 19) and the webs of the stator 6 are hardened before or after the multi-stage compaction to a depth of at most 1.5 mm, so they have a surface hardness of at least 500 HV 5. But it is also possible that the stator 6 is at least partially cured.
    The exemplary embodiments show or describe possible design variants, it being noted at this point that various combinations of the individual design variants are also possible with one another.
    For the sake of order, it should finally be pointed out that for a better understanding of the structure of the stator 6 or of the camshaft adjuster 2, these are not necessarily shown to scale.
    LIST OF EMBODIMENTS 1 internal combustion engine 2 camshaft adjuster 3 drive wheel 4 spur gear teeth 5 spur toothing 6 stator 7 rotor 8 cover 9 main body 10 lateral surface 11 web 12 recess 13 base body 14 lateral surface 15 wing 16 side surface 17 surface 18 spur gear part 19 spur gear part 20 spur gear 21 hub
    权利要求:
    Claims (8)
    [1]
    claims
    1. A method for producing a stator (6) for a camshaft adjuster (2), wherein the stator (6) with an annular base body (9) with an external spur toothing (4) and with a radially inner circumferential surface (10) of the Base body (9) radially inwardly projecting, spaced apart in the circumferential direction of the base body (9) webs (11) is produced, comprising the steps of providing a mold for integrally forming the base body (9) with the spur gear (4) and the radially inward projecting webs (11), filling a metallic powder in the mold, pressing the powder to a green compact and sintering the green compact to a stator blank, characterized in that the spur toothing (4), the radially inwardly facing lateral surface (10) of the main body ( 9), which has been formed between the webs (11), and on the lateral surface (10) adjacent side surfaces (16) of the webs (11) without prior mechanical treatment tion in several steps to the desired final dimension.
    [2]
    2. The method according to claim 1, characterized in that the spur toothing (4), the radially inwardly facing lateral surface (10) of the base body (9), and the side surfaces (16) of the webs (11) are compacted in one step.
    [3]
    3. The method according to claim 1 or 2, characterized in that the spur toothing (4), the radially inwardly facing lateral surfaces (10) of the base body (9), and the side surfaces (16) of the webs (11) are compressed simultaneously.
    [4]
    4. The method according to any one of claims 1 to 3, characterized in that between the webs (11) and the spur toothing (4) has a hub (21) is formed, on which a second spur gear (20) is arranged, wherein a spur toothing ( 4) the second spur gear (20) with the same geometry with respect to the cross section of the teeth in the axial direction, the pitch and the module as the spur gear (4) is produced.
    [5]
    5. The method according to any one of claims 1 to 4, characterized in that the spur toothing (4) of the stator (6) and the webs (11) of the stator (6) before or after the compaction to a depth of at most 1.5 mm hardened.
    [6]
    6. Stator (6) for a camshaft adjuster (2) comprising an annular base body (9) having on its outer periphery a spur gear (4) and on an inner circumferential surface (10) a plurality of radially inwardly projecting and spaced apart webs (11) characterized in that the spur toothing (4), the radially inwardly facing lateral surface (10) of the base body (9), which is formed between the webs (11), and on the lateral surface (10) adjacent side surfaces (16) Webs (11) have as mechanical processing exclusively a compression, wherein from a surface in the direction of a core layer, a density gradient is formed.
    [7]
    7. stator (6) according to claim 6, characterized in that between the spur toothing (4) and the webs (11) has a hub (21) is formed, on which a second spur gear (20) is arranged, wherein a spur toothing (4 ), the second spur gear (20) has the same geometry with respect to the cross section of the teeth in the axial direction, the pitch and the module as the spur gear (4), and wherein the second spur gear (20) in the circumferential direction relative to the spur toothing (4) rotated and is arranged biased.
    [8]
    8. Stator according to claim 6 or 7, characterized in that the spur toothing (4) and the webs (11) have a surface hardness of at least 500 HV.
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    同族专利:
    公开号 | 公开日
    CN107866574A|2018-04-03|
    AT519135B1|2019-03-15|
    US20180080538A1|2018-03-22|
    BR102017020243A2|2018-05-29|
    DE102017008835A1|2018-03-22|
    引用文献:
    公开号 | 申请日 | 公开日 | 申请人 | 专利标题
    US6013225A|1996-10-15|2000-01-11|Zenith Sintered Products, Inc.|Surface densification of machine components made by powder metallurgy|
    EP1500449A2|2003-07-22|2005-01-26|Nissan Motor Company, Limited|Sintered sprocket for silent chain and production method therefor|
    DE102010003546A1|2010-03-31|2011-10-06|Schwäbische Hüttenwerke Automotive GmbH|Combined sprocket and stator unit|
    CN103421992A|2013-07-16|2013-12-04|沈军|Manufacturing technique of timing sprocket device for ultralight aluminium alloy valve camshaft|
    US4011295A|1974-10-07|1977-03-08|The Garrett Corporation|Ceramic rotor for gas turbine engine|
    US7905018B2|2006-03-29|2011-03-15|Hitachi Powdered Metals Co., Ltd.|Production method for sintered gear|
    AT9818U1|2007-04-04|2008-04-15|Miba Sinter Austria Gmbh|DEVICE AND METHOD FOR CALIBRATING A SINTERING PART|
    CN101555937B|2009-05-20|2011-10-05|中南大学|Iron-based gradient structure gear and manufacturing method thereof|
    AT510283B1|2010-09-29|2012-03-15|Miba Sinter Austria Gmbh|GEAR ARRANGEMENT|
    AT512777B1|2012-11-12|2013-11-15|Miba Sinter Austria Gmbh|gear|US11097346B1|2017-05-18|2021-08-24|Keystone Powdered Metal Company|Process for manufacturing toroid parts|
    法律状态:
    优先权:
    申请号 | 申请日 | 专利标题
    ATA50849/2016A|AT519135B1|2016-09-22|2016-09-22|Method for producing a stator for a camshaft adjuster|ATA50849/2016A| AT519135B1|2016-09-22|2016-09-22|Method for producing a stator for a camshaft adjuster|
    US15/672,396| US20180080538A1|2016-09-22|2017-08-09|Method for producing a stator for a camshaft adjuster|
    CN201710732183.XA| CN107866574A|2016-09-22|2017-08-24|For manufacturing the method and stator of the stator for camshaft adjuster|
    DE102017008835.7A| DE102017008835A1|2016-09-22|2017-09-20|Method for producing a stator for a camshaft adjuster|
    BR102017020243-7A| BR102017020243A2|2016-09-22|2017-09-21|METHOD FOR MANUFACTURING A STATOR FOR A CAM SHAFT ADJUSTER|
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