Periodic Reporting for period 1 - DART (Feasibility study for market introduction of the T-Minus DART research rocket system)
Période du rapport: 2017-02-01 au 2017-07-31
Phenomena in the highest layers of the atmosphere play an important role in day-to-day life. They have a large influence in large-scale, long-term weather effects and climate, but also on satellite navigation and communication and re-entry or satellite orbit decay: issues of growing importance in modern society. Nonetheless, data from the middle- and upper atmosphere (50 – 120 km altitude) is scarcely available, because the means are currently not available to deploy a sensing system in this region in a cost-effectively manner. Atmospheric balloons have a maximum altitude of approximately 40 km, whereas satellites cannot orbit lower than 200 km. Remote sensing techniques can be used in some cases, but this does not work for all parameters, and discrimination in altitude proves difficult with these methods. Because of this knowledge gap, the region is therefore sometimes called the “ignorosphere”.
The only available way to perform in-situ observations in these layers is by means of so-called sounding rockets: rockets that are launched almost vertically to a certain altitude and then fall back through the atmosphere. These rocket systems are expensive both in product cost and operational cost. This limits their practical use to few yearly launch campaigns, with one or two launches each, and for this reason they provide scarce data from single-point measurements, and not the continuous datasets, or datasets over larger areas that are necessary to improve and validate atmosphere models.
As a solution to this problem, T-Minus Engineering is developing the T-Minus DART: a small and cost-effective rocket system for fast and easy access to space and the highest layers of the atmosphere. By making full use of the trend of miniaturizing electronics, applying a smart and fully integrated design, and using state-of-the-art materials and manufacturing techniques, estimates show that the product- and operational cost can be reduced by a factor 10 with respect to other rocket systems.
The T-Minus DART can reach an altitude in excess of 120 km, as verified by validated trajectory simulation software. It is designed to accommodate a variety of miniaturized payloads: from highly integrated, electronic multi-sensor packages to simple chaff or chemical tracers. The payload diameter is limited at 30 mm, but sufficient for plenty of sensor systems due to the current trend of miniaturizing electronics and sensors.
In this project, T-Minus Engineering answers all questions regarding technical, economical, legal and operational feasibility of the DART product. The steps needed to bring the production process to the required Technology Readiness Level (TRL) are identified to assess the technical feasibility. The main focus in this respect is on the development of key enabling technologies: the propulsion module (the rocket motor) and the electronic flight computer. Conclusions on economic feasibility follows from a detailed market survey, resulting in a target sales price, and an analysis of the production cost. Acceptance in the conservative sounding rocket market is very much driven by product reliability and safety. For this reason, conducting a product qualification test campaign in a representative operational scenario is essential. During the SME-instrument project, it is attempted to formalise a consortium with which such a test campaign will be carried out. Finally, the production and operation of a rocket system shall conform with specific legal requirements. An in-depth study thereof is carried out during this project as well.
The only available way to perform in-situ observations in these layers is by means of so-called sounding rockets: rockets that are launched almost vertically to a certain altitude and then fall back through the atmosphere. These rocket systems are expensive both in product cost and operational cost. This limits their practical use to few yearly launch campaigns, with one or two launches each, and for this reason they provide scarce data from single-point measurements, and not the continuous datasets, or datasets over larger areas that are necessary to improve and validate atmosphere models.
As a solution to this problem, T-Minus Engineering is developing the T-Minus DART: a small and cost-effective rocket system for fast and easy access to space and the highest layers of the atmosphere. By making full use of the trend of miniaturizing electronics, applying a smart and fully integrated design, and using state-of-the-art materials and manufacturing techniques, estimates show that the product- and operational cost can be reduced by a factor 10 with respect to other rocket systems.
The T-Minus DART can reach an altitude in excess of 120 km, as verified by validated trajectory simulation software. It is designed to accommodate a variety of miniaturized payloads: from highly integrated, electronic multi-sensor packages to simple chaff or chemical tracers. The payload diameter is limited at 30 mm, but sufficient for plenty of sensor systems due to the current trend of miniaturizing electronics and sensors.
In this project, T-Minus Engineering answers all questions regarding technical, economical, legal and operational feasibility of the DART product. The steps needed to bring the production process to the required Technology Readiness Level (TRL) are identified to assess the technical feasibility. The main focus in this respect is on the development of key enabling technologies: the propulsion module (the rocket motor) and the electronic flight computer. Conclusions on economic feasibility follows from a detailed market survey, resulting in a target sales price, and an analysis of the production cost. Acceptance in the conservative sounding rocket market is very much driven by product reliability and safety. For this reason, conducting a product qualification test campaign in a representative operational scenario is essential. During the SME-instrument project, it is attempted to formalise a consortium with which such a test campaign will be carried out. Finally, the production and operation of a rocket system shall conform with specific legal requirements. An in-depth study thereof is carried out during this project as well.
On the technical feasibility study, the infrastructure, supply lines and processes for the production of the T-Minus DART have been investigated. An important conclusion is that one of the key elements, the rocket propellant, will be produced in-house. This guarantees maximum freedom of operation, as well as an absolute minimum cost for this important part of the product.
For the economic feasibility, a market analysis has been performed: a survey of potential customers has been made. In-depth interviews with promising potential customers have lead to the first sales agreement, which is currently being formalised. Next to that, several specific demands from customers have been identified. By a solid presence at the most important symposium on sounding rockets, ESA-PAC, maximum awareness of the DART has been created in the community. Currently, a consortium for performing the qualification test campaign is being built, consisting of the rocket launch base Andoya Space Center, the radar operator and specialist sounding rocket launch organisation DLR MORABA and one of the largest potential customers IAP Kühlungsborn.
In the legal field, the necessary steps to conform the DART production, operation and sales with international regulations have been identified, and the first steps have been taken towards compliance. These include the arrangement of necessary permits, and detailed planning of certification steps in cooperation with the national notified body of the Netherlands: TNO.
For the economic feasibility, a market analysis has been performed: a survey of potential customers has been made. In-depth interviews with promising potential customers have lead to the first sales agreement, which is currently being formalised. Next to that, several specific demands from customers have been identified. By a solid presence at the most important symposium on sounding rockets, ESA-PAC, maximum awareness of the DART has been created in the community. Currently, a consortium for performing the qualification test campaign is being built, consisting of the rocket launch base Andoya Space Center, the radar operator and specialist sounding rocket launch organisation DLR MORABA and one of the largest potential customers IAP Kühlungsborn.
In the legal field, the necessary steps to conform the DART production, operation and sales with international regulations have been identified, and the first steps have been taken towards compliance. These include the arrangement of necessary permits, and detailed planning of certification steps in cooperation with the national notified body of the Netherlands: TNO.
Detailed assessments of the production process show that the use of novel materials, such as carbon fibre and technologies like electronics miniaturisation lead to a large reduction in production cost with respect to competing systems. This enables extended usage within existing scientific project budgets, leading to a significant increase in knowledge of the "ignorosphere", and the phenomena that take place here. With this, long-term weather effects and climate change will be better understood and possibly counteracted. Next to that, insight into the disturbance factors of these atmospheric layers in satellite communication and navigation leads to a higher accuracy and better usage, which is of utmost importance for today's society, as it depends increasingly on those technologies.