HIGH speed civil Tilt Rotor wInd tunnel Project

HIGHTRIP is a fundamental pillar of the NGCTR-TD program since it is one of the key demonstrators that will support the confirmation of the aerodynamics benefit in line with the Clean Sky 2 objective for noise footprint and CO2 reductions. The new wing and tail configuration will provide information mandatory for the future aircraft envelope expansion in high speed airplane mode. Considering the current status of the NGCTR-TD program the data gained will fit in line with the current scheduling.

HIGHTRIP (HIGH speed civil Tilt Rotor wInd tunnel Project) is a 3.495 M€ funded EU project to investigate the full scale high speed aerodynamic characteristics of the NGCTR (Next Generation Civil Tilt Rotor). The original time span of the 3-year project ran from November 1st 2018 till October 31st 2021. Extension was necessary up to July 31st, 2022.

WHY?
The aerodynamic configuration of the Next Generation Civil Tilt Rotor (NGCTR) needs to be characterized at high speed by a dedicated wind tunnel test campaign.

Within the EU CleanSky 2 program new T- and V-tail empennages were designed and fabricated in the NEXTTRIP project, envisaging use for higher speeds. In order to fully exploit this research, HIGHTRIP will design a new model based on NEXTTRIP design philosophy and scale, re-using the new (instrumented) NEXTTRIP empennages. Consequently, the exact HIGHTRIP model scale will result from sizing NEXTTRIP empennage to the NGCTR Technology Demonstrator geometry.

HOW?
The partners will work together to design and manufacture a new fuselage, wing and nacelles in the HIGHTRIP model, based on the NEXTTRIP tails and NICETRIP parts. NLR will coordinate the HIGHTRIP project and will perform wing design and manufacture. The Polish partners will focus on the design and manufacturing of the new fuselage. NLR will subcontract the non-powered high speed wind tunnel test to ONERA-S1MA, resulting in a data package (on model scale) corrected for wind tunnel effects.

To provide full scale Reynolds number data and perform aerodynamic characteristics analysis at high speeds and full scale conditions, extrapolation to full scale Reynolds numbers will be done by CFD.

WHAT?
The Next Generation Civil Tilt Rotor fast rotorcraft concept aims to deliver superior vehicle productivity and performance. The aerodynamic configuration definition of the novel tilt rotor NGCTR Technology Demonstrator needs to be validated further at high speeds.

By exploiting outcomes and facilities of NICETRIP (EU FP6) and NEXTTRIP (EU CleanSky 2) projects and providing a full scale high speed database of different empennage configurations, HIGHTRIP provides a vital contribution for the validation of an innovative tilt rotor concept, the configuration of which will go beyond current architectures of this type of aircraft.

WWork package 1: Management, dissemination and exploitation
After the kick-off WebEx (2018/11/06) a face-to-face kick-off meeting was held at Leonardo’s premises in Cascina Costa, Italy (2018/11/19-20). The project had a slow start due to a change of scope and late delivery of geometry and loads. This and a problem with the wind tunnel caused extension of the lead time of the project extended , captured in two project amendments.

Work Package 2: Design of the unpowered model components
At the beginning of the project the scope of the original work was slightly changed. Due to this and the late delivery of geometry and loads the real start of the project was delayed for some months. The Critical Design Review was in February 2020. With some delay the design was finalized in November 2020.

Work package 3: Manufacturing of the unpowered model components
Manufacturing activities started late due to late signing of the subcontract by ONERA and their feedback with respect to materials and design. Manufacturing of all components and subassembly at NLR was finalized mid-October 2021.

Work package 4: Wind tunnel tests of the unpowered model
Due to the late finalization of the subcontract the original slot for the wind tunnel could not be realized. Due to another drawback with the wind tunnel, the test needed to be postponed to April/May 2022. Final data delivery were delivered and of May 2022.

Work package 5: Wind tunnel data analysis and reporting
Preparations for the Reynolds extrapolations, such as the computational grid, consisting of the 4 components fuselage/wing+farfield, tails, nacelle and spinner were finalized well before the test and shared to be used in calculations for sting corrections. Based upon test results Reynolds extrapolation were tuned and completed in July 2022.

Wind tunnel model
The model is unique in the sense that never a wind tunnel model has been equipped with so many balances; a main balance measuring the overall loads on the model, a wing balance measuring the loads on the wing-nacelle substructure, a nacelle balance to measure the nacelle loads, a tail balance to distinguish the loads on the two tails and further control-surface loads (2x aileron, 2x ruddervators, rudder and elevator).
In the trend to always aim for a more accurate load measurement and more accurate remotely controlled positioning of a control surface, new laboratory techniques were put in where possible.

Reynolds number extrapolation and analysis for Tilt Rotors
A novel procedure was applied providing reliable corrections to the wind tunnel data. This was accomplished through extensive CFD calculations covering the complete range of Mach en Reynolds numbers as well as angle-of-attack and side-slip conditions. The range of Reynolds numbers extended from wind tunnel to full scale conditions. This procedure was done for each of the two empennages, resulting in two very detailed sets of correction values to all force and moment coefficients, not just drag and lift. The calculations take into account Reynolds number, Mach number, angle of attack and sideslip, and are specific for the tilt rotor concepts under consideration.

High Speed Machining (HSM)
HSM was used for manufacturing of the fuselage, internal structure and interfaces; except reduction of manufacturing time it can offer a wide range of advantages:
• Cutting force reduction;
• Small heat flow to workpiece, heat transferred into chips;
• Increased quality of manufactured parts;
• Reduction of finishing machining
Moreover, in addition to above features of HSM, it also allow to manufacture more complex shapes and thin walls, what can have impact on final weight of the part or surface fidelity.

By contributing to the optimization of the tail, to be implemented on the Technology Demonstrator, the aerodynamics will be improved and effect the effectiveness of the vehicle.
With high maturity of technology integration aimed at completion of this rotorcraft program including flight demonstrations, the possibility to match ACARE goals (sustainable mobility) with actual products to be subsequently developed will be substantiated.