DE102004005879B4 - Tool with a template having a flow shoulder, in particular extrusion tool - Google Patents

Abstract

Tool having a die having a flow shoulder (2), in particular an extrusion die, wherein the die sits in a receiving sleeve (8) and can be axially prestressed by means of spring elements, characterized
- That a plate spring (T) generates the axial bias of the flow shoulder (2), wherein an outer reinforcing ring (6) has a shoulder (6.1) against which the plate spring (T) or the bottom (8.1) of the receiving sleeve (8) acts and which transfers the axial preload to the flow shoulder (2),
or
- That the maximum achievable axial preload is adjustable in a trained as a spring bottom (8.1) of the receiving sleeve (8) by the change in the thickness of the bottom (8.1),
or
- That the axial bias of the flow shoulder (2) by the insert material and / or the geometric shape of the wall of the receiving sleeve (8) is adjustable.

Description

The The invention relates to a tool having a flow shoulder having die, in particular an extrusion tool, according to the preamble of first claim.

Numerous solutions for forming tools are already known in which the die is made of ceramic ( US 682,360 ; JP 06122034 A ; G. Schwier :, wire 4/99, wire forming with high-performance ceramic cores; W. Nester, Stressing Cup-Backward Extrusion Die Matrices with Ceramic Due to Mechanical Stress, Diss. Institute for Forming Technology, University of Stuttgart, Springer Verlag, 1986).

A disadvantage of the use of ceramic is that this very brittle material fails by, during the forming process on the inner wall of the die, tensile stresses occurring. It is already known to include tangential and radial tensile stresses by a multi-ring system. The axial tensile stresses should be compensated by the fact that the ring is biased by axial compressive stresses. However, the known solutions are insufficient to compensate for the different thermal expansions in the thermal and stress stress or possible settling of the fittings. An extrusion tool with a ceramic insert is inserted in DE 100 54 232 A1 described. In this case, the die has on its inner contour, for example, a reduction in cross-section with a flow shoulder. An axial preload (insert) is applied to the die by a cup spring. The plate spring rests on the one hand with its outer diameter radially on a, surrounding the die, reinforcement and on the other hand on its inner diameter on the end face of the die. The abutment surface, on which the die rests with its, opposite the plate spring, end face is formed on a pressure piece. This solution is too expensive.

An in DE 198 04 700 A1 described mold for extrusion, for example, has a ceramic die consisting of which is surrounded by a voltage applied to it with radial clamping ring. Die and clamping ring have conical contact surfaces and are relatively displaceable. The clamping ring is surrounded by a prestressed to him armor. Both are fixed to a support. The die is displaceable relative to the carrier and locked in selectable positions by locking means on the carrier. As a result, although a fine adjustment of the critical reference value can be made over a large correction range. However, this mold compensates insufficiently for the different thermal expansions in the thermal and stress loading or possible settling phenomena of the screwed connections.

task The invention is a tool using ceramic to develop, which also at high thermal loads and thereby occurring different thermal expansion coefficients a permanent one Bias in the form of axial and radial compressive stresses on the Ceramic matrix guaranteed and thus a break through the tensile stresses occurring during forming excludes and has a simple structure.

These Task is solved with the features of the first claim. advantageous versions emerge from the dependent claims.

The Tool using a die, in particular extrusion tool has a radially biased die seated in a receiving sleeve and over Spring elements can be axially biased.

According to the invention

• - generated a diaphragm spring, the axial bias of the flow shoulder, wherein an outer reinforcing ring has a shoulder against which the plate spring or the ground the receiving sleeve acts and which transmits the axial bias to the flow shoulder, or
• - is the maximum achievable axial preload in a spring trained bottom of the receiving sleeve by the change the thickness of the floor adjustable, or
• - is the axial bias of the flow shoulder through the insert material and / or the geometric shape of the wall of the receiving sleeve adjustable.

The floating shoulder consists of silicon nitride ceramic. The flow shoulder and / or one above the flow shoulder in feeder the material arranged guide sleeve has while an axial excess on. opposite the feeding direction of the material is arranged under the flow shoulder a pressure piece.

The axial preload can be adjusted at an educated as a spring bottom of the receiving sleeve via an axial excess of the flow shoulder and / or the pickup. When generating the axial preload through the wall the receiving sleeve, the maximum to be achieved bias can be adjusted by the insert material and the geometric shape of the wall of the receiving sleeve. For this purpose, the wall thickness can be partially reduced or increased, so that the desired spring action occurs. So that a spring effect in the wall area can be realized, the clamping sleeve bottom has a greater wall thickness than the sleeve wall. The guide sleeve and the pressure piece are preferably made of hard metal.

The The invention will be explained in more detail with reference to embodiments.

It demonstrate:

1 : Tool half of a symmetrical tool for extrusion molding with a floor made as a spring.

2 : Tool half of a symmetrical tool for extruding with a sleeve made as a spring.

3 : Tool half of a symmetrical extrusion tool using a disc spring.

1 shows a split in the plane of symmetry tool for extrusion, with executed as a spring floor 8.1 a receiving sleeve 8th and therein flow molding 1 , The tool consists of the ceramic flow shoulder 2 , the clamping ring 3 , the guide sleeve 4 , the reinforcing rings 5 . 6 . 11 , the receiving sleeve 8th with ground as a spring 8.1 and the clamping ring 9 ,

2 shows a split in the plane of symmetry tool for extruding, designed with a spring receiving sleeve 8th and therein flow molding 1 , The tool consists of the ceramic flow shoulder 2 , the clamping ring 3 , the guide sleeve 4 , the reinforcing rings 5 . 6 . 7 , the receiving sleeve designed as a spring 8th ,

3 shows a tool for extrusion, with a sleeve 8th and therein flow molding 1 , The tool consists of the ceramic flow shoulder 2 , the clamping ring 3 , the guide sleeve 4 , the reinforcing rings 5 . 6 . 11 and a plate spring T.

The functioning of the tools is the following: In the case of extrusion with ceramic tool inserts, tensile stresses are to be avoided in the interests of a long service life of these inserts. For this purpose, the ceramic flow shoulder 2 biased in the radial direction. However, since during the forming process also tensile stresses can occur in the axial direction, the flow shoulder 2 also biased in the axial direction. This can be done by a receiving sleeve 8th ( 1 ), which the Armierungsverband ( 2 . 4 - 7 . 1 ) and their bottom 8.1 is designed as a spring. Around the flow shoulder 2 targeted bias in the axial direction, the entire Armierungsverband occurs only on the guide sleeve 4 , which is the flow shoulder 2 supports, with the ground 8.1 the receiving sleeve 8th in contact. By means of the first clamping ring 3 who is on the shoulder 2 supports, and a second clamping ring 9 becomes the ground 8.1 the receiving sleeve 8th elastically deformed, causing in the flow shoulder 2 an axial compressive stress state is established.

This axial compressive stress state can also be achieved by a receiving sleeve 8th ( 2 ) can be realized with executed as a spring sleeve wall. Also in this type of execution, the receiving sleeve surrounds the Armierungsverband ( 2 . 4 - 7 . 2 ) Completely. Here, the entire Armierungsverband with the ground 8.1 the receiving sleeve 8th in contact. The floor 8.1 the receiving sleeve 8th has a significantly greater wall thickness than parts of the wall of the receiving sleeve. As a result, when screwing in the clamping ring 3 the sleeve wall elastically deformed. Through in the wall of the receiving sleeve 8th resulting axial tensile stresses of the entire Armierungsverband is biased in the axial direction.

Gem. 3 is the axial compressive stress on the ceramic flow shoulder 2 generated by a plate spring T. The diaphragm spring T sits in the region of its outer diameter between the ground 8.1 the receiving sleeve 8th and an outer ring 7 , Under the flow shoulder 2 sits a hard metal underlay 10 , These and the flow shoulder 2 be from a reinforcing ring 11 radially biased. The guide sleeve 4 is made of a middle and an outer reinforcement 5 . 6 radially biased. The outer reinforcement 6 has a shoulder 6.1 to which the plate spring T acts with a biasing force. The underside of the outer reinforcement 6 is free and the lower sides of the guide sleeve 4 and the middle reinforcement 4 lie at the top of the flow shoulder 2 on, causing the axial preload on the plate spring T, the shoulder 6.1 the outer reinforcement 6 as well as the middle reinforcement 5 and the guide sleeve 4 on the flow shoulder 2 which is transmitted in the direction of their sub-cables in the receiving sleeve 8th is not fixed by clamping elements axially fixed.

Claims (7)

Tool with a a flow shoulder ( 2 ) on pointing die, in particular extrusion tool, wherein the die in a receiving sleeve ( 8th ) is seated and spring biased axially, characterized in that - a plate spring (T), the axial bias of the flow shoulder ( 2 ), wherein an outer reinforcing ring ( 6 ) one shoulder ( 6.1 ), against which the disc spring (T) or the bottom ( 8.1 ) of the receiving sleeve ( 8th ) and which the axial prestress on the flow shoulder ( 2 ) transmits, or - that the maximum achievable axial preload in a designed as a spring bottom ( 8.1 ) of the receiving sleeve ( 8th ) by changing the thickness of the soil ( 8.1 ) is adjustable, or - that the axial prestress of the flow shoulder ( 2 ) by the insert material and / or the geometric shape of the wall of the receiving sleeve ( 8th ) is adjustable. Tool according to claim 1, characterized in that the flow shoulder ( 2 ) consists of silicon nitride ceramic. Tool according to claim 1 or 2, characterized in that the flow shoulder ( 2 ) and / or one above the flow shoulder ( 2 ) in the feed direction of the material arranged guide sleeve ( 4 ) has an axial excess. Tool according to one of claims 1 to 3, characterized in that opposite to the feed direction of the material under the flow shoulder ( 2 ) a pressure piece ( 10 ) is arranged. Tool according to claim 1, characterized in that the wall thickness in the wall region of the receiving sleeve ( 8th ) is reduced in at least one position. Tool according to claim 5, characterized in that the bottom ( 8.1 ) of the receiving sleeve ( 8th ) has a higher wall thickness than the sleeve wall. Tool according to claim 4, characterized in that the guide sleeve ( 4 ) and the pressure piece ( 10 ) consist of hard metal.