US1784865A

US1784865A - Method of strain hardening manganese steel

Info

Publication number: US1784865A
Application number: US154645A
Authority: US
Inventors: Frank A Fahrenwald
Original assignee: American Manganese Steel Co
Current assignee: American Manganese Steel Co
Priority date: 1926-12-13
Filing date: 1926-12-13
Publication date: 1930-12-16
Anticipated expiration: 1947-12-16

Description

Dec. 16, 1930. F. A. FAHRENWALD 1,784,865

METHOD O' STRAIN HARDENING MANGANESE STEEL I y Fild Dec Patented Dec. 1.6, 1930 UNITED STATES PATENT Aor-fricla FRANK A. FAHRENWALD, OF CHICAGO, ILLINOIS, ASSIGNOR T AMERICAN MANGA- NESE STEEL COMPANY, `OIF CHICAGOA HEIGHTS, ILLINOIS, A CORPORATION OF MAINE METHOD OF STRAIN HARDENING MAN GANESE STEEL Application mea December 1s, 192e. serial` No. 154,645.

This invention relates to the manufacture of articles of manganese steel, and partlcularly to a method of hardening portions'of such articles to increase their resistance to [6l abrasive forces and to deformationstresses encountered in service; also to an article resulting from the application of the method.

It is well known that most metals and alloys can be hardened by cold workin or de- 10 formation at temperatures below t ose at which spontaneous re-crystallization takes place, #and this phenomenon is usefully employed in many industrial operations today, for instance, in the production'of cold rolled,

hard, elastic wire, roof sheets, .and other standard articles of commerce in which various metals and alloys are employed; in fact, the capacity in metals to harden under cold plastic deformation is'so great that it be'- ,20Y comes very objectionable in many metalformingu operations and necessitates frequent heating of themetal being worked, to an annealing temperature, to prevent fracture of the metal in progressive deformation, or to maintain softness to a degree which renders the metal responsive to rolls, dies; or other instrumentalities through means of which it is being worked."

A number of theories have been advanced to explain why. metals and alloys harden when cold worked. Onejof these assumes the transformation of soft austenite to relativelyl the planes in which flow will be induced; stillanother states that' the hardening is the resultfofbreakin'g down the original` crystal 'space lattice, with resulting interruption of flow planes. But the phenomenon of hard- 40 ening, in itself, is not.A claimed to be of the present invention, and thea reasons therefor are immaterial for purposes of explanation of the present invention.

It has long been proposed to harden the surfaces of manganese steel castings the better to adapt them to resist abrasive forces or impact stresses, but this has generally been practiced in a manner to develop over the entire surface to be hardened, asubstantially 5o uniform dimension of excess metal or a pad of metal, and depressing this pad-.until the excess metal has been retired within the desired ultimate surface of the work-piece.

I have discovered that induced hardening,

or hardening by cold working, is proportional to the degree of actual plastic deformation with respect to degree of space-lattlce, distortion, ory to the number of flow planes produced in the mass per unit of volume; and that applicationof simple pressure alone, such as might be exerted upon a piece of manganese steel surrounded with liquid in a pressure chamber, in whatever degree, has no hardening edect'. I have also found that the customary methods' heretofore employed such as pressing large areas of a casting or merely hammering relatively large surfaces,

besides being relatively ineective, introduce l iiaws into the treated casting, chiefly .in -the form of shear cracks, because of propagation of iow over the large areas. As corollary to this, I have found that intensive Working of quite small areas or subdivisions of the total area to be affected, produces hardness of a degree impossible of production in larger sections treated all at once, without at the same time rupturing the entire mass.

p Many efforts have been made to peen harden surfaces of manganese steel castings, but these have usually comprised the simple process of repeated application o f the hammer at shiftin points in a manner to pro'- duce small in entations which collectively involve,l eventually, the whole of the large flat surface; or they have comprised the pressing or pounding of elevated areas or pads corresponding in dimension to the sec tiongwhich it is desired to harden, with the result that a certain vdegree of hardness has been produced, measuring around 350 or in extreme cases even 400 (Brinell). But nearly always castings so treated suffer a spalling or flaking of the pressed areas due to shear cracks produced by the extreme pressure and excessive local shear flow inthe n castings at the boundaries of pressure areas.

In my copending applications, Serial N o.

154,644, filed Decul, 1926, and Serial No. 177,878 led Mar. 24, 1927, I have described new methods of developing desired intensive plastic deformation and thereby strain hardeniiig manganese steel castings; the method described in the former of said copending applications consisting in forming, at the time of casting, on those areas of the manganes@V steel Acastings which are subjected to heavy wear or stresses in use, a number of essentially equally spaced projections which, after heat treatment'of the casting and while the casting is in a cold state, are compressed to a fraction of their original height, though preferably not .depressed to a degree sufficient to form a continuous lia't surface.; while that described in the latter of said copending applications consists in pressing into the heat treated casting, while in a cold state and atspaced intervals, a tool with a rounded end, the curvature of the rounded end of the tool being preferably on a radius less than one fourth of the thickness of the casting at the point of treatment, and the depth of depression being preferably less than this radius.

The invent-ion with which the present application is concerned, while involving the 'l broad principle of the invention set forth in the said copending applications, follows more closely the copending'application irst named, in that a number of equally spaced projections are formed upon the are@ to be hardened and compressed in the cold state, after heat treatment, but differs therefrom in .detail and principally. in the circumstance that the projections formed upon the surface to be hardened are of special form, to-wit, cast-on conchoidal elevations, or elevations arny section of which would be arcuate in form, for instance, elevations that are spherical, spheroidal, or egg-shaped `in contour, and which elevations-are joined onto the general surface ofthe casting through means of a smooth sweeping curve; the process of hardenin by depressing projections of this general c aracter having been discovered to be much more satisfactory for certain applications of my new principle of producing deep seated, hardened, Wear-resisting surfaces. v Y

In order that the invention maybe more fully understood, reference will be had to the accompanying` drawing, in which-- Figure 1 is a surface view of a portion of a manganese steel casting formedwith projections in accordance with thepresent invention.

Figure 2 is a section on the line 20c- 2m of Figure l; and

resisting surface of the casting, elevations B spaced at proper intervals, on neral contours, which elevations may be c aracterized surface of the casting is through smooth sweeping curves S (Figures 1 and 2). After such a casting has been heat treated and preferably cleaned, its -surface carrying the elevations described, is subjected to the action of a powerful press or heavy drop hammer capable of driving the elevations into the casting until the surface of the casting is approximately level. The excess material thus forced into the body of the casting act-s in a manner similar to a rounded tool, as described in my copending application, Serial No. 177,878, causing the surface surrounding each individual elevation to rise slightly, in an annular area, to accommodate the metal t-hat has been flowed into the mass. The plastic flow incident tothe leveling of the elevations produces hardness to a very high degree, locally, which hardness gradually diminishes with the distance from the focus.

For a specific example, let it be assumed that the casting is formed with elevations of the kind described having a one inchv radius,

and that these elevations are raised about pressing the metal of all the elevations into the body ofthe casting, the casting being made of ordinary commercial manganese steel, the work-piece will be found to have had its hardness raised to about 450 to 550 (Brinell).

E levations of the shape and size described are such that when sunk into the casting, the iow' produced by their depression is .propa-l gated deeply into the casting, and not merei ly to the extent of a fraction of an inch (for instance, one-sixteenth of, an inch) as in Figure 3 is an edge view of the work-piece or castin after the hardening process is completed, ow lines in the piece beingl suggested by the use of dotted lines.

According to the present invention, I pro-- duce 'a casting such as A., Figures 1, 2, and 3,

in the usual manner, but in a mold so designed that it will produce upon the wearordinary process of hardening by cold workingl. In fact, the metal is caused to iow for a epth of from one half inch to one inch, as suggested by the broken flow lines in Figu're 3, and the deep hardening so produced is such as to produce long life to the casting. Unless smooth curves are maintained. in the merger of the elevations with the general surface of thev casting, shear cracks will' appear at points corresponding to those indicated by the letter S in Figures 1 and 2..

In. designing the casting, the surface of which is to'be treated in accordance with the present process, it is', of course necessary to select the dimensions of the r)casting so that the ultimate dimension eiectedby depressing the elevations into the mass will be that rWhich is desired.

I claim:

1. The process of strain hardening'manganese steel, characterized by forming upon a surface of the steel, spaced, conchoid-al elevations, and after heat treatment of the steel, and while the steel is cool, depressing these elevations into the body of the casting.

2. The process of strain hardening manganese steel, characterized by the steps of forming the steel with a series of individual, spaced elevations of convexcontour meeting the general surface of the steel in substantially smooth curves, and While the steel is cool depressing these elevations into the body l of the casting.

3. The process of strain hardening mananese steel, characterized by the steps of ormin upon a surface of the steel, elevations o convex contour, with spacing bearing a ratio to their radii greater than unity, with elevation above the ultimate general surface of the casting vapproximately one-fourth of their radii, and with smooth sweeping curves of merger between the elevations, and

then While the metal is cool depressing the `elevations with resultant raising-'of the intemediate merging curves until a substantially smooth surface is developed.

Signed at Chicago, Illinois, this 9th day of December, 1926.

FRANK A. FAHRENWALD.