Process for compacting powdered material

Information

  • Patent Grant
  • 6827889
  • Patent Number
    6,827,889
  • Date Filed
    Saturday, July 13, 2002
    22 years ago
  • Date Issued
    Tuesday, December 7, 2004
    20 years ago
Abstract
A process for compacting powdered material to form a compact of a predetermined thickness and having at least one lateral oblique surface by means of a bore in a die bolster for receiving the powdered material and an upper ram and a lower ram, which are operable by means of a hydraulic power-exerting device and are positionable by means of a control device with respect to the die bolster, comprising the following steps:The deformations of the die bolster are measured or calculated for various compacting forces and the correlating values are filed as a table in a memory with the deformations forces being determined from the difference of the compacting forces of the two rams, andDeformation is determined during the compaction procedure by applying the deformation force measured to the table and the feed length of the upper and lower rams is corrected depending on deformation.
Description




A common technique for compacting powdered material consists in forming the mould space in a so-called die bolster and in producing the compact by means of an upper ram and a lower ram. Usually, the lower ram is moved into the die bore up to a predetermined position, whereupon filling is effected with powdered material. Subsequently, the compact is formed with the aid of the upper ram. Such a technique is used, for instance, to compact metallic powder for the manufacture of molded components according to the sintering process. This aims at molding the compact in a relatively precise way already, if possible, with a view to its geometrical dimensions and its density so as to achieve the desired dimensional accuracy later after the sintering process.




If the compact has a geometrical shape in which an oblique surface is provided at the outside as is the case, for instance, in cutting blades for milling and drilling tools a very significant deformation force is applied to the die bolster during the compaction procedure. The deformation force causes the die bolster to get deformed by flexing and upsetting. The flexing effect thus caused on the bolster may be reduced by a skilful selection of the supporting surfaces and the die bolster cross-sections, but cannot be eliminated.




In the compaction process described, the deformation of the die bolster may not be ignored. It is necessary for the upper ram to travel to and stop at the edge at the transition point of the mould surfaces in a precise manner. If the upper ram is not stopped at this point the ram and die bolster will be damaged. On the contrary, there will be a lack of dimensional accuracy if the ram is stopped too early.




It is known to determine by tests or calculations by which amount a die bolster undergoes deformation in a certain compaction procedure to predetermine the displacement length of the upper ram. This is normally accomplished by ascertaining on the compact whether or not the compaction ram has traveled through the predetermined distance. Such a technique involves relatively great expenditure and does not protect the compaction device from damage. If relatively low compacting forces occur because material was insufficiently filled in there will be no de-formation of the die bolster or it achieves distinctly smaller values so that if the compaction ram is positioned the upper ram will strike against the edge of the bolster bore, as a consequence.




It is the object of the invention to provide a process for compacting powdered material by which a compact may be manufactured in a reproducibly precise manner while protecting the compaction device against unintended damage caused by insufficient die bolster deformation.




The invention relies on the fact that the flexing force acting on the die bolster results from the difference of the compacting forces applied by the upper and lower rams. In the inventive process, a curve or table is obtained to report the dependence of die bolster deformation from the compacting forces applied. Furthermore, to adjust the feed paths of the compaction, it is essential to know which displacements of the die bore occur if deformations differ. Therefore, in the inventive process, the compacting forces are measured from time to time or even continuously during the compaction process to determine the respective deformation. A certain deformation rate of the die bolster also includes a predetermined feed path for the compaction rams. Therefore, it is possible to correct the length of the feed length by means of the inventive process during the compaction procedure depending on the results of the measurements described. Therefore, an outcome of the invention is that the upper ram is precisely moved up to the edge of the die bore without touching it significantly, however.




When the die bolster is deformed a relative displacement of the lower ram and the die bore will also occur naturally. Hence, it is necessary to correct the feed length of the lower ram concurrently with the correction described for the feed length of the upper ram.




The inventive process allows to prevent the upper ram from striking against an edge of the die bore if no deformation occurs to the die bolster. Since the compacting force is consistently measured as was mentioned, but can also fall below certain values this way permits to determine the time the entire compaction device needs to be stopped to avoid damage to both the upper ram and die bore.




In the compaction process described, not only does the die bolster undergo deformation, but the upper and lower rams also undergo an upsetting deformation. The deformation rates are relatively small as is the deformation of the die bolster, but are not negligible. Thus, for instance, a deformation of some μm per tonne of compacting force is obtained in a die bolster. To enable a correction also in the event of a non-negligible upsetting of the compaction rams, an aspect of the invention provides that the upsetting deformation of the rams are measured or calculated for various compacting forces thereon. The correlating values of the upsetting deformation and compacting forces are filed as a table in a memory. Then, the feed rate of the upper and lower rams will be corrected depending on the extent of upsetting.











An embodiment of the invention will be explained in more detail below with reference to the drawings.





FIG. 1

schematically shows a compaction device according to the invention.





FIG. 2

shows the operation of the compaction device of

FIG. 1

with reference to a block diagram.











A compaction device


10


illustrated in

FIG. 1

has a die bolster


12


with a die bore


14


with which an upper ram


16


and a lower ram


18


cooperate. The power-exerting devices which actuate the rams


16


,


18


are not shown. They are conventional and act hydraulically, for instance. Such compaction devices make it possible to position the compaction rams in the μm range. The power-exerting devices and rams


16


,


18


have interposed therebetween a load cell


20


and


22


, respectively. The die bolster


12


rests on spaced supports


24


,


26


.




As can be recognized the mould space proper of the die bolster


12


is conical or trapezoidal in cross section and has two oblique surfaced


29


. Naturally, there is only one conical surface if a circular mold space exists. The mould space, which can be seen in

FIG. 1

, serves for the manufacture of a compact from powered metallic material, for instance, from which a reversible cutting blade is manufactured according to the sintering process, e.g. for use in milling or drilling tools or the like. Both of the compaction rams


16


,


18


move into the bore


14


with the upper compression ram requiring to travel up to the edge


28


, thus predetermining the position of the compact upper side whereas the lower ram requires to travel up to the edge


30


to predetermine the thickness of the compact. During the compaction procedure, the lower ram


18


is initially advanced up to a filling position. Subsequently, filling is effected with powered material. The upper ram


16


is actuated afterwards and is moved up to the edge


28


to deform the compact by compaction. The lower ram


18


is moved up to the edge


30


at the same time.




Since the cross-sections of the upper and lower rams


16


,


18


are different for compaction a pressure differential is applied to the die bolster


12


and the die bolster is flexed and upset between the supports


24


,


26


as can be clearly seen in an exaggeration in FIG.


1


. Such deformation of the die bolster


12


now makes it necessary for the upper ram


16


to be moved farther into the die bore


14


than if the die bolster


12


is not deformed, with a view to getting to the edge


28


. This displacement length is dependent upon the deformation of the die bolster


12


which, in turn, is dependent on the differential force on the die bolster.




The way the compaction device


10


of

FIG. 1

operates clearly ensues from the block diagram of

FIG. 2. A

computer


38


has filed therein a table reporting the way of action between the deformation force on the die bolster


12


and the deformation resulting therefrom. More specifically, it has filed therein the displacement of the die bore or edge


28


relative to the deformation force. This relationship may be determined by means of appropriate measurements or calculations before production begins. The powdered material requiring compaction is known and so is the density required for the compact. Thus, deformation can be determined for the individual deformation forces which are formed from the difference of the compacting forces of rams


16


,


18


.




During the compaction procedure, the compacting forces acting on the compacting rams


16


,


18


are measured continuously or intermittently by means of the load cells


20


,


22


and the deformation force is calculated therefrom. The associated deformation of the die bolster


12


or the displacement of the edge


28


of the die bolster


12


is determined in the computer


38


. The computer


38


therefrom transmits the feed length of the compacting ram


16


and provides a control device


32


with an appropriate positioning signal for the power-exerting members


34


and


36


for the compacting rams


16


,


18


. This way allows to make the upper ram


16


travel precisely to the edge


28


and the lower ram


18


precisely to the edge


30


regardless of the deformation that the die bolster


12


undergoes. This is because if the die bolster


12


is deformed there is also a relative displacement of the lower ram


16


and the die bolster


12


and the lower ram


18


needs to be appropriately positioned by the power-exerting member


36


to make it remain at the edge


30


.




If too low a value appears while compacting forces are measured the computer


38


generates a turn-off signal for the compacting device


10


. This avoids damage to the rams and die bolster.



Claims
  • 1. An improvement to a process for compacting powdered material to form a compact of a predetermined thickness and having at least one lateral oblique surface by means of a bore in a die bolster for receiving the powdered material and an upper ram and a lower ram, which are operable by means of a hydraulic power-exerting device and are positionable by means of a control device with respect to the die bolster, the improved process including the following steps:the deformations of the die bolster are measured or calculated for various compacting forces and the correlating values are filed as a table in a memory with the deformation forces being determined from the difference of the compacting forces of the two rams, and deformation is determined during the compaction procedure by applying the deformation force measured to the table and the feed length of the upper and lower rams is corrected depending on deformation.
  • 2. The process as claimed in claim 1, characterized in that the deformation force is continuously determined during the compaction procedure.
  • 3. The process of claim 1, characterized in that the power-exerting device is turned off when the compacting forces or deformation force are below predetermined values.
US Referenced Citations (7)
Number Name Date Kind
4680158 Hinzpeter et al. Jul 1987 A
5004576 Hinzpeter et al. Apr 1991 A
5043111 Hinzmann et al. Aug 1991 A
5211964 Prytherch et al. May 1993 A
6074584 Hinzpeter et al. Jun 2000 A
6442859 Hinzpeter et al. Sep 2002 B1
6562291 Hinzpeter et al. May 2003 B2
Foreign Referenced Citations (1)
Number Date Country
WO 0020192 Apr 2000 WO