AbstractThree techniques are presented to enhance the control of grid‐point distribution for a class of algebraic grid generation methods known as the two‐, four‐ and six‐boundary methods. First, multidimensional stretching functions are presented, and a technique is devised to construct them based on the desired distribution of grid points along certain boundaries. Second, a normalization procedure is proposed which allows more effective control over orthogonality of grid lines at boundaries and curvature of grid lines near boundaries. And third, interpolating functions based on tension splines are introduced to control curvature of grid lines in the interior of the spatial domain. In addition to these three techniques, consistency conditions are derived which must be satisfied by all user‐specified data employed in the grid generation process to control grid‐point distribution. The usefulness of the techniques developed in this study was demonstrated by using them in conjunction with the two‐ and four‐boundary methods to generate several grid systems, including a three‐dimensional grid system in the coolant passage of a radial turbine blade with serpentine channels and pin fins.