Synera GmbH

Konsul-Smidt-Strasse 8U
Bremen,  28217

Germany
0049(0)42122159700
http://www.synera.io

• Booth: 805

Process Automation Platform for Engineers
Synera is a process automation platform for engineers that accelerates product development by 10X. Seamlessly integrating diverse CAx tools in an open platform ensures that engineering teams operate within a unified ecosystem, promoting agility and accelerating time-to-market for new products.

Instead of relying on IT for developing and maintaining custom solutions, Synera enables (design and simulation) engineers to independently automate manual tasks in all areas using a visual programming (low-code) interface.

Through capturing organizational engineering expertise in these automations and allowing their fast distribution, Synera increases efficiency and scales manual work with consistent quality at minimal cost.

 Show Specials

• Robust Topology Reconstruction for CAD: A Live Demo on Automating OptiStruct Optimization Results - June 26 at 2 PM (Jun 12, 2024)
  Converting topology optimization designs into a smooth CAD geometry that is ready to be sent to a printer is not an easy. It involves lot of manual steps and significant time. This live demo presents how to automate a topology optimization mesh into a CAD design that is smooth & functional.

• Live Demo of Manufacturing-Ready DfAM Optimization using Hexagon Emendate & Cognitive Design System - 26 June at 11 AM (Jun 12, 2024)
  Live demo on performing topology optimization of parts that are ready for 3D printing using Hexagon Emendate inside Synera & how to connect the designs with cost estimation using Cognitive Design Systems inside Synera: An end-to-end fully automated approach.

• Automate Structural Analysis of AM Parts: A Live Demonstration of Meshfree Simulation - 25 June at 2 PM (Jun 04, 2024)
  Live demonstration on automating structural analysis of AM parts using a meshfree approach at Booth 805 at 2 pm on June 25th.

 Press Releases

• BMW Group expands use of 3D-printed, customised robot grippers (May 30, 2024)

  Link to BMW's press release on the achievements working with Synera:  https://www.press.bmwgroup.com/global/article/detail/T0442351EN/bmw-group-expands-use-of-3d-printed-customised-robot-grippers?language=en 

   

  Munich. With more than 30 years of experience, the BMW Group is a pioneer in the field of additive manufacturing, better known as 3D printing. 3D printers have been used from as early as 1991 to produce individual vehicle parts and components, initially for concept cars, prototypes and race cars, then later for production models. The BMW Group now also manufactures many work aids and tools for its own production system in various 3D printing processes. From tailor-made orthoses for employees, and teaching and production aids, to large, weight-optimised robot grippers, used for such things as CFRP roofs and entire floor assemblies. At the “Additive Manufacturing Campus” in Oberschleißheim, the BMW Group’s central hub for production, research and training in 3D printing, more than 300,000 parts were “printed” in 2023. Furthermore, over 100,000 printed parts were produced per year across all the plants that form the global production network, from Spartanburg and the German plants to sites in Asia.

  “The increasing use of additive manufacturing in the BMW Group production system has many benefits. For example, we are able to quickly, economically, and flexibly produce our own production aids and handling robots, which we can individually adapt to specific requirements at any time, as well as being able to optimise their weight. Less weight allows higher speeds on the production line, shorter cycle times and reduced costs. Plus, smaller robots can be used in the medium term, which also cuts CO₂ emissions and costs,” says Jens Ertel, Head of BMW Additive Manufacturing.

  “As well as the direct additive manufacturing procedure, the BMW Group has also been using sand-based 3D printing to create moulds for many years at its site in Landshut. This technology is typically used to manufacture prototype casts, as well as for the large-scale production of components for high-performance motors. Another very attractive field of application is now that of large production aids,” says Klaus Sammer, Head of Product and Process Planning for Light Metal Casting.

  Printed moulds for the production of aluminium cylinder heads in large-scale production

  Additive manufacturing processes have been used on a daily basis for a long time at BMW Group Plant Landshut. For many years, these have included moulds for the manufacturing of aluminium cylinder heads, which are printed three-dimensionally using the sand casting process. Here, sand is repeatedly applied in thin layers and stuck together using binders. This makes it possible to create moulds for the manufacturing of very complex structures, which are then filled with liquefied aluminium.

  Using 3D printing to manufacture large robot grippers for CFRP roofs

  For a number of years, the BMW Group’s Lightweight Construction and Technology Centre in Landshut has been using a particularly large gripper element, which was made using the 3D printing process. Weighing around 120 kilograms, the gripper for a robot can be manufactured in just 22 hours and is then used on a press in the production of all CFRP roofs for BMW M GmbH models. The press is first loaded with the CFRP raw material. The gripper is simply rotated 180 degrees to remove the finished roofs. Compared to conventional grippers, the version manufactured using 3D printing was roughly 20 percent lighter, which in turn extend the operating life of the robots and also reduced wear and tear on the system, as well as cutting maintenance intervals. The combined use for two steps also reduced the cycle time. A unique feature of the robot gripper is the ideal combination of two different 3D printing processes. While the vacuum grippers and the clamps for the needle gripper to lift the CFRP raw material are made using selective laser sintering (SLS), the large roof shell and bearing structure are manufactured using large scale printing (LSP). LSP can be used to produce large components economically and sustainably. The process uses injection moulding granules and recycled plastics, while CFRP residual material can also be used and recycled. Compared to the use of primary raw materials, CO₂ emissions when manufacturing the gripper are roughly 60 percent lower.

  Further weight savings, courtesy of new generation of bionic grippers

  In the summer of 2023, a new, even lighter generation of gripper was introduced. To achieve this, the previous gripper concept was analysed and optimised topologically – the birth of the bionic robot gripper. This combines the roof shell from the LSP printer with SLS vacuums and a bionically optimised bearing structure. For this, a mould with printed cores is used in the sand casting. This mould is then cast with the intricate aluminium structure. The new gripper is a further 25 percent lighter than its predecessor, meaning the entire process of manufacturing a CFRP roof of the BMW M3 can be performed with just one robot, rather than three as was previously the case. Nowadays, double grippers manufactured individually within the BMW Group, courtesy of 3D printing, are used for all CFRP roofs at BMW Group Plant Landshut.

  New 3D-printed gripper also used in chassis construction in operation

  The BMW Group also employs grippers produced using the 3D printing process in chassis construction – for example, grippers printed with the LSP process for dealing with doors at BMW Group Plant Regensburg. “With an optimised bearing structure produced using 3D printing, we were able to increase the rigidity of the gripper when handling door elements at the plant in Regensburg, while at the same time reducing weight. In subsequent projects, it is then possible to use robots with a low bearing capacity, which helps to cut costs,” says Florian Riebel, Head of Door and Flap Production in Regensburg.

  However, the company is now taking it one step further at BMW Group Plant Munich. As of recently, the first examples of a bionic robot gripper have been used at the parent plant. This gripper can hold and move the entire floor assembly of a BMW i4. For the floor assembly gripper, 3D printing is used to create a sand casting mould, which is filled with liquid aluminium. The bearer is optimised in terms of weight and maximum load capacity, and weighs with all additional add-on elements a mere 110 kilograms. That makes it roughly 30 percent lighter than the previous, conventional model. Manufacturing using sand casting and aluminium makes it possible to represent intricate load-optimised structures. This results in maximum weight reduction and thus makes it possible in the medium term to use smaller and lighter heavy-duty lifting robots, which require less energy and thus reduce CO₂ emissions. Markus Lehmann, Head of Plant Engineering and Robotics at BMW Group Plant Munich: “At the Munich plant, we are continuously expanding the use of production aids created through additive manufacturing. When it comes to the field of gripper and handling systems, we use 3D printing to equip our established grippers with individual, printed attachments and are already replacing complete gripper systems with highly-integrated and weight-optimised bearing structures. When handling the full BMW i4 floor assembly, this allowed us to reduce the weight of the complete gripper by 30 percent – 50 kg – and thus to extend the service life of our facilities.”

  Use of innovative software solutions in additive manufacturing

  Intricate and bionic structures are designed and calculated using special generic software tools, such as Synera. BMW iVentures had strategically invested in this software, previously known as Elise. Synera allows fast and efficient optimisation and is now used in many development areas within the BMW Group. It is particularly worth using the software in 3D printing, as topologically optimised, bionic structures can virtually be printed one to one, thanks to the high degree of flexibility of the 3D printing process. This makes it possible to exploit the full potential for lightweight construction. The BMW Group’s Additive Manufacturing Campus is home to a team of design and construction specialists, who compare a diverse range of software solutions and use them to design components. The knowledge is then passed on throughout the company via the Additive Manufacturing Campus. In the case of gripper design, special workflows have been developed and implemented, which allow the calculation and construction of the bearing structure to be largely automated, and thus fast and efficient.

• Synera integrates low-code platform with additional CAD/CAE/PLM products from Siemens Xcelerator portfolio of industry software (May 30, 2024)

  Press release link: https://newsroom.sw.siemens.com/en-US/synera-xcelerator/

  Integration with NX and Teamcenter complements Synera's extensive CAx connectivity with solutions from Siemens Digital Industries Software for engineers

  Synera, the low-code engineering process automation platform, announces further integration of industry-leading engineering software from Siemens Digital Industries Software into its platform. Engineers can now process designs and CAD data directly from the product development solutions in the Siemens Xcelerator industrial software portfolio and feed back the results. In addition to integration with Siemens NX™ software, Siemens Solid Edge® users can also dramatically shorten product modelling, design and simulation processes via Synera workflows, freeing them from manual repetitive tasks.

  The latest integration goes far beyond simple data exchange and extends to the ability to make parametric adjustments to the CAD model within Synera or to run selected Synera workflows from Siemens' NX Algorithmic Modeler. Designers can save Synera workflows in NX, view and update versioning through integration with Siemens' Teamcenter® product lifecycle management (PLM) software, access the Parasolid kernel in Synera, or exchange data such as geometry and simulation files with Teamcenter.

  For engineers in many large companies, Siemens' Teamcenter is the central hub for product lifecycle management of their technical products. The link allows them to access, edit and check in data from Teamcenter directly into Synera. The tight integration helps users to control the user rights set up by the company for Teamcenter, and ensures that the versioning of data is seamlessly transferred, while allowing users to develop new things in their Synera workflows. This opens up new possibilities for design, engineering and simulation analysis experts, who can use the full functionality of Synera, which in turn integrates with other software products on the process automation platform and can be extended with numerous extensions from the Synera Marketplace. Synera's visual programming allows quick adaptation of simple algorithmic models, resulting in efficient and fast innovation cycles.

  Deeper integration with Siemens NX

  In addition to this data exchange between Teamcenter and Synera, the new NX integration goes even further. NX users can now access Synera workflows directly and use them within the Siemens NX Algorithmic Modeller. The reverse is also possible: anyone working in Synera can access NX parts and assemblies directly and change their parameters quickly and seamlessly. They can access a library of more than 700 ready-made nodes in Synera and adapt them for their own purposes.

  The new options extend the collaboration between Siemens Digital Industry Software and Synera, which began in 2019. The collaboration started four years ago with the licensing of the proven, widely used and powerful Parasolid® kernel model, which is used in both Synera and NX. The integration of Siemens' Teamcenter, Solid Edge and NX now extends this integration.

  Comprehensive process automation for nonprogramming engineers

  Users of Siemens CAD/CAE/PLM tools now have new options that complement the built-in macro and algorithmic capabilities of the original software and extend them beyond the CAD domain into the CAE domain in particular. They allow engineers to work much more efficiently and to automate workflows to a high degree, without having to delve into programming.  

  "Working with Synera and their innovative low-code solution is a great advantage for us.  Not only is the technology constantly and rapidly evolving, but it also perfectly complements Siemens' digital offering. This collaboration provides real value to all parties involved - both Synera users and Siemens product users," said Bob Haubrock, Senior Vice President, Product Engineering Software at Siemens Digital Industries Software.

  "We are very pleased to have further enhanced the integration of Synera into Siemens Digital Industries' industry-leading software tools. For users, this means a tremendous reduction in workload and the convenience of using our leading low-code platform," added Moritz Maier, CEO of Synera. "The integration helps companies reduce costs and make more efficient use of the limited resource of highly specialised engineers.

• Accelerating the German bobsleigh national team with 3D printed spike plates (May 30, 2024)

  Link: https://www.synera.io/extended-case-studies/accelerating-german-bobsleigh-national-team-3d-printed-spike-plates

  
  BMW Group extends its technological know-how from the automotive sector to the ice track by introducing 3D-printed shoe spikes for faster bobsled starts. With Synera integrated into the process, it enables rapid, automated, and tailored creation of the 3D print data, ensuring customized spike plates in no time.

  In anticipation of the 2026 Winter Olympics, the German Bobsleigh, Luge, and Skeleton Federation (BSD) is building on its partnership with BMW Group to bring their performance standards to new heights. Leveraging BMW Group’s innovative know-how, and automotive and 3D-print expertise, the BSD aims to optimize their bobsleigh national team’s performance through customized spike plates.

  Spike plates: From off-the-shelf to customized 3D prints

  In the high-speed world of bobsleigh, start times are critical, determining the sled's velocity as it enters the ice channel. To maximize the athletes' pushing power, the spike plates on their footwear play a pivotal role. Traditionally, these plates were standardized, limiting customization. However, BMW Group's technology transfer from automotive development to bobsleigh has changed the game.

  Utilizing 3D printing technology and Synera’s software, BMW Group has enabled the creation of individualized spike plates for each athlete. This innovative approach allows for precise customization of geometry, stiffness, and weight distribution, optimizing performance on the ice track. Unlike traditional manufacturing methods, 3D printing offers rapid prototyping and cost-effective production, ensuring that each athlete receives tailored spike plates for enhanced performance.

  

  Synera’s process automation for time savings and performance improvements

  The integration of Synera's software further streamlines the design process. By automating the creation of 3D print data based on individual athlete parameters, Synera ensures maximum efficiency and variability. Engineers at BMW Group can seamlessly incorporate athlete preferences into the spike plate design, resulting in significant time and cost savings, as well as customizability.

  As the BSD prepares for the 2026 Winter Olympics, BMW Group continues to refine and optimize the spike plates, targeting stiffness and material selection to meet the unique needs of each athlete. With BMW's expertise in additive manufacturing and Synera's software solution, the German bobsleigh team is poised to achieve new heights of success on the international stage.

• Connected Engineering: Digital turbo for the design process (May 30, 2024)

  ARRK Engineering, a key player in automotive development, is revolutionising high-voltage battery simulation, improving collaboration and automating processes with the Synera low-code engineering platform. Amidst the complexities of electrification in vehicle development, the integration of digital tools such as simulation, AI and machine learning is critical. Traditionally, simulation phases are bottlenecked, leading to longer time-to-market cycles - a challenge OEMs can't afford in a competitive market.
  
  ARRK Engineering is taking a connected engineering approach with Synera, streamlining digital processes and interdisciplinary collaboration. Using a universal low-code platform, engineers seamlessly share expertise, define parameters and map workflows, reducing manual effort and facilitating efficient template reuse.
  
  The versatility of the low-code platform is demonstrated in a feasibility study where ARRK Engineering models a design of experiments (DoE) workflow. They analyse a dynamic simulation of the lateral collision of a high-voltage storage structure with a pile, automating the creation and simulation of different CAD variants.
  
  By using Synera's connectivity to their simulation infrastructure, ARRK Engineering achieves seamless integration with tools such as ANSA, LS-Dyna and Animator, accelerating the simulation process.
  
  The collaborative platform enables real-time visualisation of results, facilitating rapid evaluation and comparison of design alternatives. This efficient workflow not only saves time, but also serves as a blueprint for future projects, improving long-term design validation.
  
  Synera's integration of different tools and departments streamlines collaboration, reducing waiting times by up to 30%. In essence, ARRK Engineering's adoption of the Synera low-code platform represents a paradigm shift in automotive development, enabling efficient interdisciplinary collaboration and accelerating time-to-market in an increasingly competitive industry.

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  Read the full article

  Would you like to learn more about Connected Engineering? Read the full article in Konstruktionspraxis (in german) and discover the benefits of this innovative approach.

  About ARRK Engineering (Synera Silver Partner)

  ARRK Engineering is a global development partner for automotive and mobility, offering end-to-end support for product development. This includes concept phase, series development, validation, and integration of mechanical and electronic components. Our expertise extends to e-mobility, autonomous driving, and software development in a digitalized environment. Efficient project management ensures we meet development goals with our customers.
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