Abstract:The microstructure and mechanical properties of 93W-Ni-Fe powder extruded bars with a diameter of 15 mm sintered via microwave (1 550 ℃, 30 min) and conventional hydrogen (1550 ℃, 120 min) were investigated, respectively. The phases and quantitative analysis of the main elements in the core portion of samples were measured. The relative density, tensile strength, hardness and elongation of the samples were investigated, respectively. The results show that the average grain size of the alloys sintered via microwave sintering is finer and the tungsten content of the alloys is higher than that via conventional hydrogen sintering. Cracks between part of the tungsten grains and the matrix phase are observed on the fracture of the alloy sintered via microwave sintering. The hardness of the alloys sintered via microwave sintering is 33.8HRC, which is a little higher than that via the conventional hydrogen sintering. The relative density, tensile strength and elongation of the alloys sintered via microwave sintering are fairly close to that via the conventional hydrogen sintering. For the tungsten heavy alloys samples with large size, in order to get the better microstructure and mechanical properties than that via the conventional hydrogen sintering, further optimization of the microwave sintering process is required.

Key words: 93W-Ni-Fe alloy; extruded rods; microwave sintering; microstructure; mechanical property