Die assembly and method of making the same

Abstract

A draw or ironing die assembly includes a housing having a minimum modulus of elasticity of 50,000,000 p.s.i. and an axial hole therethrough. A die wear ring of greater elastic modulus and greater hardness is shrunk fit into the axial hole. Tungsten carbide is a suitable material for each part.

Description

The invention relates to a die assembly and to a method of making the same and particularly to a draw or ironing die assembly used in the manufacture of cans from tin plate (steel coated with tin). It may also be used in other types of dies including heading and extrusion dies for use with various types of material in addition to steel can bodies. The dies most commonly used have a precision ground steel body with a counterbored axial hole therethrough. The working surface of the die is provided by a canbide insert which is shrunk fit into the counterbore. In making the skrink fit the die body becomes deformed to such an extent that it is more expensive to repair the body and replace it with a new insert when the old one must be replaced than to make a new die body and put in a new insert. Thus no part of the die is reused.

In my co-pending application I use a three part die assembly which results in very substantial savings in that the housing and intermediate insert may be reused with only the die wear ring being replaced. This, however, does not increase the life of the die wear ring.

I have also found that a standard die having a steel housing or body and a tungsten carbide insert or die wear ring expands from 0.0006 to 0.0008 inch when ironing. This starts microscopic cracks on the surface of the land and entrance angle of the wear ring, thus decreasing its life.

I have found that by substituting a cemented or sintered tungsten carbide die case or housing having a much higher modulus of elasticity than a steel housing this expansion is eliminated or greatly reduced with resultant much greater life of the wear ring. The deformation of the die housing is also eliminated or greatly reduced so that it can be reused.

This solid cemented carbide housing also allows the use of a very hard, extremely low binder (such as 11/2% by weight of cobalt) material in the die insert. The die insert can also be made of very brittle material.

It is therefore an object of my invention to provide a die assembly which permits reuse of the die housing while replacing only the die wear ring.

Another object is to provide such a die assembly which results in several times greater longer life of the die wear ring and virtually eliminates die expansion during the ironing operation.

A further object is to provide such a die which has lower tool maintenance and replacement costs, and results in less downtime than previous dies.

A still further object is to provide such a die which results in better surface conditions of the can or other workpiece.

Still another object is to provide a die which results in a product, suchb as a can, having decreased wall thickness variation and greater overall accuracy.

Still another object is to provide a method of making such a die.

These and other objects will be more apparent after referring to the following specification and attached drawings in which the single FIGURE is a sectional view of the die of my invention.

Referring more particularly to the drawing, reference numeral 2 indicates the die housing or body of my invention. The die body 2 has a counterbored axial hole 4 therethrough. It will be seen that the bottom of the counterbore forms a shoulder 6. An insert or wear ring 8 is received in the counterbore against the shoulder 6. It will be seen that the outer diameter of insert 8 is greater than the inner diameter of the counterbore. The inner surface 10 of insert 8 extends beyond the shoulder 6 and forms the die working surface.

According to my invention the body 2 is made of a material having a minimum modulus of elasticity of approximately 50,000,000 pounds per sq. in. with the die wear ring 8 having a higher modulus of elasticity which preferably approaches that of the body 2. However, it is preferred that the modulus of elasticity of the body 2 be at least approximately 80,000,000 p.s.i. In no case should the modulus of elasticity of the housing 2 be less than 1/2 that of the die ring 8. For example, the body 2 may be made of tungsten carbide and the die wear ring 8 also of tungsten carbide having a higher modulus of elasticity and greater hardness than the housing. I have found that cemented tungsten carbide having 10% cobalt, R.sub.A 88 to 90 hardness, a density of 14.2 to 14.6 grams per cubic centimeter, an elastic modulus of 86 to 88.times.10.sup.6 lbs. per square inch and a porosity of A-2, B-1, C-1 is very suitable for the body 2 and that cemented tungsten carbide having approximately 98.5% tungsten carbide and approximately 1.5% cobalt, R.sub.A 93.2.+-.3 hardness, density of 15.55.+-.0.1 grams per cc., an elastic modulus of 108.times.10.sup.6 lbs. per square inch and a porosity of A-0, B-0, C-0 is highly suitable for the wear ring 8. All percentages are by weight.

Other materials which are particularly suitable for the housing 2 include various metal carbides such as cemented tungsten carbide with a nickel or metal alloy binder in place of the cobalt binder, and cemented titanium carbide with a nickel, cobalt, molybdenum or a metal alloy binder.

Other materials which are particularly suitable for the wear ring 8 include various metal carbides such as cemented titanium carbide, cemented molybdenum carbide, ceramic materials such as zirconium oxide and aluminum oxide (Al.sub.2 O.sub.3) and cements such as hot pressed Al.sub.2 O.sub.3 and TiC mixtures as well as other metal oxide-metal carbide combinations.

The radial wall thickness of the housing 2 is not critical and may vary greatly depending upon the material being drawn, the amount of reduction and the other factors commonly considered by the routine designer. In general the thinner the wall thickness of the wear ring 8, the thicker will be the wall thickness of the housing 2. Some typical die assemblies using carbide housings and wear rings are as follows:

A housing 2 having an outside diameter of 6.000 in., and 2.680 in. and 3.000 in. diameters of the counterbored hole 4 and a wear ring 8 having an outside diameter of 3.000 in. and an inside diameter which may vary, but which is less than 2.680 in.

A housing 2 having an outside diameter of 4.500 in., and 2.680 in. and 3.000 in. diameters of the counterbored hole 4 and a wear ring 8 having an outside diameter of 3.000 in. and an inside diameter which may vary, but which is less than 2.680 in.

A housing 2 having an outside diameter of 4.250 in., and 2.680 in. and 3.000 in. diameters of the counterbored hole 4 and a wear ring having an outside diameter which may vary from 2.900 to 3.000 in. with the larger diameter of the counterbore corresponding thereto.

In making the die, the wear ring 8 is shrunk fit into the body 2 with an interference fit of 0.0007.+-.0.0001 inch. When the wear ring has been ground through its range of sizes it is pressed out and a new one installed by heating only to about 300.degree. F. At this temperature the body 2 retains its flatness and roundness.

While one embodiment has been shown and described in detail, it will be readily apparent to those skilled in the art that various adaptations and modifications may be made within the scope of the invention.

Claims

1. A drawing and ironing die assembly comprising

a housing having an axial hole therethrough, and a radial shoulder on the exit side of said housing, provided by means of a counterbore on the entry side of said axial hole, and

a die wear ring in said axial hole bearing against said shoulder having a shrink fit with said housing with an interference fit of from 0.0006 to 0.0008 inch, said housing made of a material having a minimum modulus of elasticity of approximately 50,000,000 pounds per square inch, and said wear ring having a higher modulus of elasticity than said housing, and an outer diameter of the wear ring greater than an inner diameter of the counterbore.

2. A die assembly according to claim 1 in which said housing and die wear ring are made of metal carbides.

3. A die assembly according to claim 1 in which the housing has a minimum modulus of elasticity of 80,000,000 pounds per sq. in.

4. A method of making a drawing and ironing die assembly which comprises

providing a housing having a minimum modulus of elasticity of approximately 50,000,000 pounds per square inch, having an axial hole therethrough, and a counterbore on the entry side of said axial hole providing a radial shoulder,

providing a die wear ring of a material having a higher modulus of elasticity and greater hardness than said housing and having an outside diameter only slightly greater than the diameter of said axial hole, and shrink fitting said wear ring into said axial hole with an interference fit of from 0.0006 to 0.0008 inch.

5. The method of making a die assembly according to claim 4 in which said body is heated to a temperature of approximately 300.degree. F. during said shrink fit.