Not Applicable.
Not applicable.
The manufacture of tools, e.g. cutting blades for milling or drilling, is frequently performed by a sintering process. Before undergoing sintering, compacts are formed from metallic powder. An eccentric press or hydraulic press is used to press the metallic powder into shape. The invention relates to a powder hydraulic press.
The upper and lower rams are operated by means of appropriate press cylinders in a powder hydraulic press. It is not only necessary to apply a considerable pressure by means of the press cylinders, but the rams also require to be moved to a predetermined position each in order to avoid damage, on one hand, and ensure desired reproducible dimensions for the compact, on the other.
Powder presses of this type are known to measure both the length passed through by the rams and the force which is applied. This way makes it possible to ensure a desired compaction with dimensions being predetermined. To measure forces, it is known to arrange a load cell between the press cylinder and the ram.
Once the rams have taken their predetermined positions and the maximum compression force is reached the press cylinders undergo a reversal of their motion and it is specifically the upper ram which is moved out of the die-bore to enable the compact to be ejected by means of the lower ram.
As is further known the sudden relief of the compression power is disadvantageous. The compact exhibits a certain spring-back behaviour and there is a risk of undesirable cracks forming in the compact during the spring-back, which have an adverse effect in sintering and cause defective compacts. When the compression power is removed it is known to maintain a so-called live load, e.g. by means of a spring. A spring, however, has only one predetermined characteristic line.
During pressure relief, it is also imaginable to jointly displace the lower and upper rams in a way to produce a certain live load which gradually decreases. The existing hydraulic press cylinders, however, make it nearly impossible to obtain a harmonized motion of the upper and lower rams.
It is the object of the invention to provide a hydraulic press for compressing metallic powder or the like to form compacts wherein a controlled spring-back of the compact becomes possible.
The inventive hydraulic press provides for a limited dead path length for the return stroke in which the upper ram is not carried along, in the force path between the press cylinder and the upper ram. If the press cylinder is operated to move in the opposite direction after the maximum compression force or the predetermined position of the upper ram is reached the cylinder will not carry along the upper ram over a first length of the path. If no particular provisions were made the compact would then be loaded by the weighting force of the upper ram. According to the invention, however, a separate pressure generator producing a variable pressure is provided which is arranged in parallel with the force path and produces a predetermined compression force on the upper ram during the aforementioned dead path length. The compression force may be led towards zero along a desired line and will be zero, for example, at the moment when the upper ram is carried along by the press cylinder during the return stroke.
The advantage of the inventive press is that a controlled live load acts onto the compact so as to efficiently prevent cracks from forming on the compact. The live load may be slowly decreased by means of the invention. In addition, there is the advantage that a predetermined live load may be adjusted depending on the material and geometry of the compact. Finally, there is obtained the advantage that the invention allows to reveal the forces acting onto the compact after the compression procedure.
According to an aspect of the invention, the pressure generator acts onto the upper ram via a force measuring device. The force measuring device helps in setting up a regulation with a view to regulating the course of the live load acting on the upper ram by means of predetermined values. The pressure generator preferably is a dual-action pneumatic cylinder. A dual action of the pneumatic cylinder is desirable to enable the cylinder to compensate the weighting force on the upper ram partially or completely.
To permit a control device for controlling the compression procedure and the live load to ascertain at which time to exert a live-load pressure an aspect of the invention provides that an appropriate force measuring device measures forces on the upper ram and initiates the application of the live load if the force falls below a predetermined value. Alternatively, the live load may be initiated if an appropriate path measuring device ascertains that the upper ram has reached a predetermined position. Path measuring devices in such presses are known as such.
Various constructional versions are imaginable to bring about the application of a live load in a hydraulic press. With this in view, an aspect of the invention provides for the upper press cylinder to act onto the upper ram via first and second guide plates between which pressure columns are arranged, which pressure columns are mounted on the second guide plate so as to be supported on the second guide plate during the press stroke and to be lifted by a limited length with respect to the second guide plate until carrying along the second guide plate during a return stroke.
While this invention may be embodied in many different forms, there are described in detail herein a specific preferred embodiment of the invention. This description is an exemplification of the principles of the invention and is not intended to limit the invention to the particular embodiment illustrated
Referring to
The die-plate 10 has arranged thereon guide columns 32, 34. They guide a plate assembly 36 having a lower plate 38 and an upper plate 40. Plate assembly 36 defines a lower guide plate. Upper ram 16 is connected to plate 38 via a component 42 which is not referred to in detail.
An upper plate 44 is connected to the slide (not shown) of the press cylinder via a ram 46 and a distance plate 48. Ram 46 acts onto a separate thrust plate 50 which is embedded in a recess of upper guide plate 44.
Pressure columns 54, 56 are connected to the lower side of guide plate 44 by means of pins 52. At the lower end, pressure columns 54, 56 are supported on sleeves 58, 60 which, in turn, are bolted to the upper side of plate 50. Pins 62, 66 are passed through bores of sleeves 58, 60 and are bolted into blank bores at the lower end of pressure columns 54, 56. Pins 62, 66 have flanges 68, 70 which interact with the lower side of sleeves 58, 60 when pins 62, 66 are lifted.
Connected to the lower side of upper guide plate 44 is a pneumatic cylinder 74. The upper side of plate 40 has connected thereto a load cell 76. Pneumatic cylinder 74 is capable of exerting a pressure onto load cell 76 that is transferred to plate assembly 36 and, hence, upper ram 16.
It is understood that not only two guide 32, 34 and two pressure columns 56, 56 are provided, but at least four each which may be arranged at a square.
During the normal compression procedure, the press cylinder which is not shown exerts a pressure on distance plate 48 in a way shown by arrow F, which has a direct effect on upper ram 16. Upper ram 16 is introduced into die-bore 12 and performs the compression procedure in a known manner until it reaches a predetermined position or has applied a predetermined force. Subsequently, the press cylinder is acted on and displaced in the opposed direction. As soon as the dead centre is reached for the press cylinder and upper ram or also a short time afterwards pneumatic cylinder 74 also exerts a force onto the ram via load cell 76. A return stroke motion of the upper press cylinder, however, does not immediately cause upper ram 16 to be carried along, which lasts up to a point where flanges 68, 70 strike at the lower side of sleeves 58, 60. In the condition drawn, the spacing is about 3 to 4 mm between flanges 68, 70 and sleeves 58, 60. Thus, as soon as the press cylinder begins its return stroke the compact is relieved of pressure with the compact, however, still applying a counter-force to upper ram 16 as before until this force becomes equal to the force of pneumatic cylinder 74. When the return motion continues the force applied to the lower ram by the pneumatic cylinder is maintained and will be reduced to zero according to a predetermined characteristic line, i.e. in a manner by which an optimum live load is achieved on the compact and avoids cracking or the like in any case. When the press cylinder has overcome the gap between flanges 68, 70 and sleeves 58, 60 upper ram will now be lifted, after which pneumatic cylinder 74 is no longer able to exert any force on upper ram 16.
The above Examples and disclosure are intended to be illustrative and not exhaustive. These examples and description will suggest many variations and alternatives to one of ordinary skill in this art. All these alternative and variations are intended to be included within the scope of the attached claims. Those familiar with the art may recognize other equivalents to the specific embodiments described herein which equivalents are also intended to be encompassed by the claims attached hereto.
Number | Date | Country | Kind |
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101 42 773 | Aug 2001 | DE | national |
Number | Name | Date | Kind |
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3890413 | Peterson | Jun 1975 | A |
4260346 | Anderson, Jr. et al. | Apr 1981 | A |
4946634 | Shaner | Aug 1990 | A |
5043111 | Hinzmann et al. | Aug 1991 | A |
6432158 | Harada et al. | Aug 2002 | B1 |
Number | Date | Country |
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07-266086 | Oct 1995 | JP |
Number | Date | Country | |
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20030041749 A1 | Mar 2003 | US |