45 research outputs found
Primary crystal orientation of the thin-walled area of single-crystalline turbine blade airfoils
The thin-walled airfoil areas of as-cast single-crystalline turbine blades made of CMSX-4 superalloy were studied. The blades were produced by the industrial Bridgman technique at withdrawal rates of 2, 3 and 4 mm/min. The angle between the [001] crystallographic direction and blade axis, related to the primary orientation, was defined by the Ω-scan X-ray diffraction method at points on the camber line located near the tip of an airfoil and at points of a line located in parallel and near the trailing edge. Additionally, primary crystal orientation was determined by Laue diffraction at the selected points of an airfoil. The influence of mould wall inclination on the primary crystal orientation of the thin-walled areas is discussed. The effect of change in the [001] crystallographic direction, named as "force directing", was considered with regard to the arrangement of primary dendrite arms in relation to the trailing edge and the camber line. It was stated that when the distance between the mould walls is less than the critical value of about 1.5 mm the "force directing" increases as the distance between the walls of the mould decreases. The effect may be controlled by selecting an appropriate secondary orientation using a seed crystal in the blade production process. The model of dendrite interaction with the mould walls, including bending and "deflection", was proposed
The Number of Subgrain Boundaries in the Airfoils of Heat-Treated Single-Crystalline Turbine Blades
In the present study, the dendrites deflection mechanism from the mold walls were subjected to verification regarding its heat-treated turbine rotor blades. The number of macroscopic low-angle boundaries created on the cross-section of the blades’ airfoil near the tip was experimentally determined and compared to the number of low-angle boundaries calculated from a model based on the dendrites deflection mechanism. Based on the Laue patterns and geometrical parameters of airfoils, the number of low-angle boundaries occurring at the upper part of the blades airfoil after heat treatment was calculated. This number for the analyzed group of blades ranged from 5 to 9
The influence of the cooling bores on crystal orientation and lattice parameter in single-crystalline cored turbine blades
The areas located near the cooling bores of single-crystalline cored turbine blades made of
nickel-based CMSX-4 superalloy were studied. The blades were solidified by the vertical Bridgman
technique in the industrial ALD furnace. Longitudinal sections of the blades were studied by
Scanning Electron Microscopy, X-ray diffraction topography, X-ray diffraction measurements of the
0-phase lattice parameter a, and the angle of the primary crystal orientation. The local changes in
were analyzed in relation to the changes of the dendrite’s growth direction near the cooling bores.
It was found that in the area approximately 3 4 mm wide around the cooling bores, changes of
and a, both in the blade root and in the airfoil occurred. The local temperature distribution near
the cooling bores formed a curved macroscopic solidification front, which caused changes in the
chemical composition and, consequently, changes in the a value in a range of 0.002 Å to 0.014 Å. The
mechanism of alloying elements segregation by tips of the dendrites on the bent solidification front
was proposed. The multi-scale analysis that allows determining a relation between processes proceed
both on a millimeter-scale and a micrometric and nanometric scale, was applied in the studies
Defect Creation in the Root of Single-Crystalline Turbine Blades Made of Ni-Based Superalloy
An analysis of the defects in the vicinity of the selector–root connection plane occurring
during the creation of single-crystalline turbine blades made of CMSX-6 Ni-based superalloy was
performed. X-ray diffraction topography, scanning electron microscopy, and positron annihilation
lifetime spectroscopy were used. Comparing the area of undisturbed axial growth of dendrites to the
area of lateral growth concluded that the low-angle boundaries-like (LAB-like) defects were created
in the root as a result of unsteady-state lateral growth of some secondary dendrite arms in layers of
the root located directly at the selector–root connection plane. Additional macroscopic low-angle
boundaries (LABs) with higher misorientation angles were created as a result of concave curvatures of
liquidus isotherm in platform-like regions near selector–root connections. Two kinds of vacancy-type
defects, mono-vacancies and vacancy clusters, were determined in relation to the LABs and LAB-like
defects. Only mono-vacancies appeared in the areas of undisturbed axial growth. Reasons for the
creation of macroscopic LABs and LAB-like defects, and their relationships with vacancy-type defects
were discussed
Effect of creep on crystallographic orientation in single crystal superalloy
The creep-rupture tests were performed on a single crystal rods made of CMSX-4 superalloy obtained at
withdrawal rates of 3 and 5 mm/min. After the rupture the microstructure and fracture surface were examined
and correlated with X-ray crystal rotation measurements by the
-scan method. The conclusions about the crystal
lattice rotation during creep test were provided
Variation of crystal orientation and dendrite array generated in the root of SX turbine blades
The variation of the crystal orientation and the dendrite array generated in the root of the single-crystalline (SX) turbine blades made of CMSX-4 superalloy were studied. The blades with an axial orientation of the [001] type were solidified by the industrial Bridgman technique using a spiral selector at a withdrawal rate of 3 mm/min. The analysis of the crystal orientation and dendrite arrangement was carried out using scanning electron microscopy, X-ray di raction topography, and Laue di raction. It was found that the lateral growth of such secondary dendrite arms, which are defined as “leading” and grow in the root at first, is related to the rotation of their crystal lattice,
which is the reason for creation of the low-angle boundary (LAB) type defects. The primary crystal orientation of the selector extension (SE) area determines the areas and directions of the lateral growth of the leading arms. Additionally, it was found that in the SE areas of the root, near the connection with the selector, the spatial distribution of the [001] 0 crystallographic direction has a complex wave-like character and may be related to the shape of the crystallization front
The effect of withdrawal rate on crystal structure perfection, microstructure and creep resistance of single crystal castings made of CMSX-4 nickel-based superalloy
This study focuses on the evaluation of the crystal structure perfection in the single crystal made of CMSX-4 nickel superalloy and its effect on creep resistance. Single crystal castings were manufactured by directional solidification process at the withdrawal rate of 1, 3, 5 and 7 mm/min. Light (LM) and electron (SEM, TEM) microscopy, X-ray diffraction and Mossbauer spectroscopy were used for evaluation of the microstructure and crystal structure perfection. Castings were also subjected to creep tests. The best creep resistance was obtained for the casting manufactured at the withdrawal rate of 3 mm/min, characterized by the highest crystal structure perfection compared to the other castings examined