Research Projects – Institute of Assembly Technology and Robotics

Optical Technologies

Assembly of photonic integrated circuits

The Cluster of Excellence PhoenixD pursues the goal of integrating conventional and complex high-performance optics into intelligent, miniaturised and adaptive optical systems. In this context, match is researching novel concepts and processes for the micro-assembly of optical systems.

Team: Niklas Terei

Year: 2021

Funding: DFG (PhoenixD)
Self-Assembly

This research area is concerned with the development of self-assembling or self-positioning systems. The specific design creates energetic potentials that effect the components and thus pull them to the assembly position. Handling of the individual components is no longer necessary, which enables new applications, such as non-contact assembly.

Team: Martin Stucki

Year: 2019

Funding: PhoenixD, DFG

Duration: 7 years

SFB Regeneration

Strategies for piezo actuator-assisted disassembly of bolted joints

The Collaborative Research Center (SFB) 871 "Regeneration of Complex Capital Goods" has been researching the scientific principles of regeneration since 2010, using civil aircraft engines as an example. The motivation is how complex components can be efficiently maintained and repaired in a resource-friendly way. The match focuses in the transfer project T16 on and develops novel strategies for gentle disassembly using the example of bolted joints.

Team: Richard Blümel

Year: 2023

Funding: DFG

Duration: 2,5 Years

Developing and Optimising of Handling and Assembly Processes

Strategies for piezo actuator-assisted disassembly of bolted joints

The Collaborative Research Center (SFB) 871 "Regeneration of Complex Capital Goods" has been researching the scientific principles of regeneration since 2010, using civil aircraft engines as an example. The motivation is how complex components can be efficiently maintained and repaired in a resource-friendly way. The match focuses in the transfer project T16 on and develops novel strategies for gentle disassembly using the example of bolted joints.

Team: Richard Blümel

Year: 2023

Funding: DFG

Duration: 2,5 Years
Assembly of photonic integrated circuits

The Cluster of Excellence PhoenixD pursues the goal of integrating conventional and complex high-performance optics into intelligent, miniaturised and adaptive optical systems. In this context, match is researching novel concepts and processes for the micro-assembly of optical systems.

Team: Niklas Terei

Year: 2021

Funding: DFG (PhoenixD)
Assembly station based on a magnetic levitation system

To achieve a cost efficient production of optical components or photonic integrated circuits, PhoenixD is following the approach of implementing an production matrix based on a levitated transport system. The goal is to use the mover not only for the transport between stations, but also as a functional unit during the stations.Therefor the match investigates and develops an integrated assembly station.

Team: Lars Binnemann

Year: 2021

Funding: DFG (PhoenixD)

Duration: 4 Jahre
CRC 1368: adhesive-based assembly processes in XHV-adequate atmospheres

As part of the Collaborative Research Center 1368 "Oxygen-free production", the match deals with adhesive-based assembly technology in a technically oxygen-free atmosphere. The aim of the sub-project is to gain knowledge about the technical properties of bonded joints produced in an oxygen-free atmosphere and with deoxidized joining partners.

Team: Sandra Gerland, Rolf Wiemann

Year: 2020

Funding: DFG
Handling of Hot-Forged Hybrid Components in the Process of Tailored Forming

The CRC 1153 "Tailored Forming" aims to exploit the potential of hybrid solid components based on a novel process chain and to develop the required manufacturing processes. The match focuses on the development of functional modules for form-variable and function-integrated handling of components with temperatures up to 1250 °C.

Team: Caner Ince

Year: 2019

Funding: DFG
PhoenixD

The PhoenixD Cluster of Excellence brings together various specialist domains from optical design, optical simulation and optical production with the aim of developing intelligent, integrated and adaptive optical systems. In this project, match takes on precision assembly tasks and focuses more intensively on fully process-integrated component alignment via self-assembly and the development of innovative, self-optimising assembly concepts.

Team: Martin Stucki, Rolf Wiemann, Niklas Terei, Lars Binnemann

Year: 2019

Funding: DFG
Self-Assembly

This research area is concerned with the development of self-assembling or self-positioning systems. The specific design creates energetic potentials that effect the components and thus pull them to the assembly position. Handling of the individual components is no longer necessary, which enables new applications, such as non-contact assembly.

Team: Martin Stucki

Year: 2019

Funding: PhoenixD, DFG

Duration: 7 years
Precision Assembly

Whether sensors, pacemakers or watch movements: wherever parts have to be assembled very precisely, conventional robots and corresponding peripherals reach their limits. In this area, match is investigating new solutions and strategies to implement reliable and economical precision assembly processes.

Team: Martin Stucki, Rolf Wiemann, Niklas Terei, Lars Binnemann

Year: 2018

Funding: basic funding

Machine Concepts and System Integration

IT security in the deployment of 5G in production ecosystems (5GProSec)

The aim of the research project is to systematically identify and eliminate potential attack vectors and unintentional disruptions when using 5G, especially in production. The focus is on both the technical and non-technical aspects of attack vectors. The methods developed are intended to reduce barriers to the use of 5G in companies and dispel security concerns.

Team: Henrik Lurz

Year: 2023

Funding: BSI
CRC 1153: Flexible process chain for the resource-efficient production of tailored forming components

As part of the Collaborative Research Centre 1153, new design, joining, forming, post-processing and testing processes for the production of hybrid solid high-performance components were developed and implemented. The aim of this sub-project is to link these individual processes into an automated overall process in order to validate the functionality of the processes in a continuous process chain and to produce reproducible samples.

Team: Sebastian Blankemeyer

Year: 2023

Funding: DFG
Active image-based feeding of small parts using aerodynamic chicanes

A crucial component of automated assembly is the feeding device, which provides the handling device (e.g. industrial robot) with the components to be assembled in a defined position and orientation. In this project, methods for the flexible and efficient feeding of components are being researched with the help of image processing, AI and aerodynamic orientation modules.

Team: Torge Kolditz

Year: 2022

Funding: DFG (German Research Foundation)
Underactuated handling systems

Within the field of "underactuated handling systems" assembly systems with fewer actuators than degrees of freedom are being researched. The basic idea is to reduce the design effort and avoid the costs of actuated systems, where each degree of freedom is typically linked to a separate motor. The main topics are the structural synthesis of the orientation mechanism and the control of the highly nonlinear dynamics.

Team: Tobias Recker

Year: 2017

Robot aided Assembly and Handling Processes

Digital planning and automated production of buildingintegrated photovoltaics (DIGI-PV)

The goal of the DIGI-PV project is to reduce barriers to the large-scale use of PV technology in order to open up significantly more façade areas for energy use. For this purpose, automated processes and tools are being developed that enable planners, producers and users to implement efficient and cost-effective processes and support them along several phases of the product life cycle.

Team: Sebastian Blankemeyer, Jessica Schönburg

Year: 2023

Funding: BMWK
TRR 277 Additive Manufacturing in Construction

While productivity in the manufacturing industry increased linearly in most areas, this value has stagnated in the construction industry for about 50 years. The reason for this is the high manual effort required to create complex formwork elements. The aim of TRR 277 is to avoid this by using additive manufacturing processes. An interdisciplinary approach is being pursued, taking into account planning, production and assembly.

Team: Lukas Lachmayer

Year: 2020

Funding: DFG
Autonomous Mobile Robotics

Currently, the assembly of large products and systems requires the use of complex and bulky assembly equipment that can only be installed and operated at central production sites. The vision for the future is the use of a network of autonomous mobile robots that take over assembly or production directly at the target location. This solution requires coordinated cooperation between robots of different sizes.

Team: Tobias Recker, Henrik Lurz

Year: 2018
Collaborative Assembly of Human and Machine

Assembly is the final step in the process chain and therefore plays a key role in the value chain. The high cost and time shares of assembly in overall production reveal considerable potential for rationalisation, from assembly planning and preparation to assembly execution. For this reason, match is developing collaborative assembly systems and processes.

Team: Sebastian Blankemeyer

Year: 2015
Robot-assisted cooperative handling and assembly

The handling and assembly of compliant and large-scale components is an important step in the process chain, especially with regard to fiber composite production. The problems that can occur when handling flexible components are their shape changes, which can lead to an undefined placement position. Furthermore, grasping with conventional grippers is often not possible.

Team: Sebastian Blankemeyer

Year: 2015

Soft Material Robotic Systems

Active Suction Device for Deep-Sea Applications (ASDDSA)

In a collaboration with the GEOMAR (Helmholtz Center for Ocean Research Kiel), the match team is researching the development of a soft robotic system that can be used in the deep sea to take sediment samples. The aim is to develop a lightweight, cost-effective and pressure-neutral actuation system to replace the hydraulically actuated titanium manipulator currently in use and reduce the overall costs of deep-sea sediment sampling.

Team: Jan Peters, Cora Maria Sourkounis

Year: 2022

Funding: DFG
Coherent Methodology for Modelling and Design of Soft Material Robots – The Soft Material Robotics Toolbox (SMaRT)

Robots made of soft materials offer a high degree of flexibility. The compliance of the material leads to a high level of adaptability that classic robot systems do not offer. In the project SMaRT ("Soft Material Robotics Toolbox"), match is conducting research together with the Institute for Mechatronic Systems (imes) and the Institute for Dynamics and Vibrations (IDS) on a coherent methodology for modeling and designing soft material robots.

Team: Mats Wiese

Year: 2019

Funding: DFG
Soft Material Robotic Systems

Soft Material Robotic Systems (SMRS) are flexible robots made of soft materials such as silicone or elastomers. Unlike conventional robots, they can adapt to complex environments and utilize pneumatic, hydraulic, or even chemical actuators for movement. SMRS are frequently utilized in areas where traditional robots are unsuitable due to their rigidity or limited flexibility, such as in medical rehabilitation, food production, or underwater research.

Team: Ditzia Susana Garcia Morales, Mats Wiese, Jan Peters, Cora Maria Sourkounis

Year: 2019

Funding: DFG Priority Programme