An experimental investigation on shock-shock interactions has been conducted with the aim of studying the transition between Regular (RI) and Mach interactions (MI) under the condition of variable inflow Mach number. The RI contains only oblique shocks while the MI has a quasi-normal shock segment, known as the Mach stem. MI configurations generate larger total pressure losses, which is specially relevant for the design of supersonic inlets and rocket nozzles. The study was conducted in the TST-27 transonic-supersonic wind tunnel at Delft University of Technology, which allows a variation of the Mach number during a run through a flexible nozzle system. The wind tunnel model was built using two full span wedges that deflected the freestream flow to generate a shock-shock interaction. The minimum vertical distance between the wedges was kept constant throughout the runs. The Mach number was determined through continuous pressure readings in both the settling chamber and the test section. Schlieren and Focusing Schlieren systems were used to visualize the shock wave pattern. For all cases, the wind tunnel runs were initialized in the RI domain after which the Mach number was slowly decreased to the MI domain, thereby traversing the whole dual solution domain. The process was then inverted to reach again the RI domain in order to investigate a possible transition hysteresis. The Focusing Schlieren setup was capable of eliminating three-dimensional effects that contaminated the images obtained with the Schlieren visualization system. It also revealed that the main three-dimensional effect in the setup was a boundary layer detachment at the sidewalls. Schlieren visualization was used as the main quantitative flow diagnostics tool, allowing a clear view of the shock pattern and revealing the absence of any hysteresis effect. A custom built image processing software was used to obtain accurate measurements of the Mach stem height (MSH) evolution and detect transition. The MSH measurements confirmed the nonexistence of the hysteresis loop and an increase of the rate of change of the MSH with the Mach number as the deflection angle was decreased. The detected transition points between RI and MI showed a very good experimental repeatability and revealed that transition always occurred at the von Neumann condition regardless of the initial shock configuration. These results suggest that flow perturbations present in the TST-27 wind tunnel may prevent a RI from existing within the theoretical dual solution domain and thus suppressing any hysteresis loop. Further experiments and simulations are required to characterize these perturbations and fully understand the physical mechanism that triggers premature transition.

An experimental investigation of shock-shock interactions has been conducted with the aim of studying the transition between Regular (RI) and Mach (MI) interactions induced by a variation of the inflow Mach number. The experiments were conducted in the TST-27 wind tunnel at Delft University of Technology. For all cases, the wind tunnel runs were initialized in the RI domain after which the Mach number was slowly decreased to the MI domain, thereby traversing the whole dual solution domain. The process was then inverted to reach again the RI domain in order to investigate a possible transition hysteresis. Both conventional Schlieren and Focusing Schlieren systems were used to visualize the shock wave patterns. The recorded Schlieren images allow accurate transition detection together with quantitative measurements of the Mach Stem Heigth (MSH). The results show no hysteresis effects. All transitions are recorded to occur at the von Neuman line, for both RI to MI and MI to RI cases. @en