The Fracture Toughness of Cold Work Tool Steels

"The influence of the composition and the microstructure on the plane strain fracture toughness of five cold work tool steels all processed via the powder metallurgical route is investigated using 3-point bending specimens. The steels differ in composition and therefore possess different volume fractions of carbides. The amount, size and distribution of the carbides in the matrix are estimated by quantitative image analysis on a plane parallel to the fracture surface without discrimination of the carbide type, since the carbides are always much harder [1,2] than the matrix, irrespective of their composition. Due to the production of the steels via the powder metallurgical route almost all carbides are spherical in shape. The mechanical in-situ properties of the matrix are characterized by indentation tests performed with an ""UltraMicro"" -indenter in a scanning electron microscope.IntroductionCold work tool steels are used as tools in applications where excellent wear resistance and high hardness are required. Examples are cutting, woodworking, thread rolling, wire and deep drawing, cold extrusion and pressing of parts at process temperatures below 200°C. For such applications the steels must show an optimum combination of hardness, wear resistance and toughness while offering good machinability. Hardness and wear resistance are controlled by the amount of carbon and carbide forming elements such as molybdenum, tungsten, vanadium, chromium and niobium. These elements are present in the MC-, M6C and M7C3-carbides and are also responsible for the precepitation of secondary carbides during tempering. In this report attention is paid to the influence of the primary carbides only, while the very small ~~nm) secondary carbides will be treated as constituent of the homogeneous matrix. Increasing the amount of carbides (alloying elements) usually results in a decrease of the material's toughness which is caused by the presence of clusters and/or bands of carbides. To achieve an optimum combination of hardness, wear resistance and toughness many of the today's cold work tool steels are processed via the powder metallurgical (PM) route, which helps to prevent non-uniform element/carbide distribution because of the rapid solidification of the powders used. The resulting microstructure of the tool steel then consists of a tough matrix with uniformly distributed hard carbides· of globular shape. This shape of the carbides is also desirable instead of blocky carbides present in non-PM tool steels, since they improve the machinability of the steel. An additional advantage of PM-steels lies in the possibility to produce near net shaped tools thus lowering the costs of machining."