CAE in the Cloud

Over the past two years we have seen tremendous growing interest in cloud computing in the engineering community. According to Hyperion (the former HPC High-Performance Computing Group at IDC), over 70% of HPC sites run some simulation jobs in public clouds today, up from 13% in 2011, and over 10% of all HPC jobs are now running in clouds like Microsoft Azure, Amazon AWS and Google Cloud. Although the cloud “on-boarding” process is well understood, major challenges still exist. Obstacles include on-demand independent software vendor software licenses for the cloud, multi-gigabyte data transfer, security concerns, lack of cloud expertise and potentially losing control over your cloud-based assets.

In 2015, based on our experience gained from the previous 100+ cloud experiments, we reached an important milestone when we introduced novel software container technology based on Docker containers, which we applied to complex engineering CAE workflows. Use of these HPC containers by our cloud experiment teams dramatically shortened cloud experiment times from months to days. Today, major cloud hurdles are well understood and have mostly been resolved, and access to and use of cloud resources became as easy as the use of in-house desktop systems.

Now, our new UberCloud 2019 annual compendium describes 13 technical computing applications in the cloud. Like its predecessors, this year’s edition draws from a select group of projects undertaken as part of the UberCloud Experiment, sponsored again by Hewlett Packard Enterprise, Intel and Digital Engineering Magazine. The Compendium is a way of sharing our cloud experience with the broader engineering community. The Compendium has just been released and is now available for free download.

These new case studies include:

• Establishing the Design Space of Sparged Bioreactors;
• Moisture and Moisture Transfer Within a Residential Condo Tower;
• 9^th Graders Design Flying Boats in ANSYS Discovery Live;
• CFX Aerodynamics of a 3D Wing;
• Race Car Airflow Simulation;
• Deep Learning for Fluid Flow Prediction;
• Machine Learning Model for Predictive Maintenance;
• Deep Learning in CFD; 
• Fluid-Structure Interaction of Aortic Heart Valves;
• Atrial Appendage Occluder Device using the Living Heart Model;
• Migrating Engineering Workloads for FLSmidth A/S; and,
• Overhead Electrical Power Lines in Preventive Maintenance.

In the following we have briefly summarized four of these CAE UberCloud Experiments to demonstrate the power of cloud for engineering and scientific applications.

Establishing the Design Space of a Sparged Bioreactor on Azure

Bioreactors are the heart of every pharmaceutical manufacturing process. One goal of a bioreactor is to operate at process conditions that provide sufficient oxygen to the suspended cells. The design space of a bioreactor defines the relationship between the input and output parameters of the cell culture process. This knowledge is used to establish and maintain consistent process (and therefore product) quality. The design space typically relies on a design of experiments (DOE) approach to characterize the interdependencies between tank design and process operating conditions.

This can be an expensive, time-consuming exercise to perform in the lab, especially at manufacturing scale. Therefore, the pharmaceutical industry has adopted computational fluid dynamics (CFD) modeling as a cost-saving option that can also reduce the risk associated with scale-up and day-to-day operations. However, the simulation time and compute resources required to explore the relationships between various process parameters can be quite extensive.

Comparison of solution speed scale-up for a different number of cores and with different mesh densities. All images courtesy of UberCloud.

Therefore, Sravan Kumar Nallamothu, senior application engineer, and Marc Horner, PhD, technical lead, Healthcare, at ANSYS, explored the use of HPC to establish the design space of a production scale sparged bioreactor.  They developed and executed the simulation framework on Azure Cloud resources running the ANSYS Fluent container from UberCloud. In Fig. 1, air bubbles undergo breakup near the impeller blades and coalesce in the circulation regions with low turbulent dissipation rates. This leads to bubble size variation throughout the tank. Since the interfacial area depends on the bubble size, bubble size distribution plays a critical role in oxygen mass transfer.

Fluid-Structure Interaction of Artificial Aortic Heart Valves in the Advania Data Center Cloud

This cloud experiment was performed by Deepanshu Sodhani, R&D project manager for Engineering, Modeling and Design at enmodes GmbH, a worldwide service provider in the field of medical technology with special expertise in the field of conception, research and development of medical devices. In this project, enmodes has been supported by Dassault Systèmes SIMULIA, Capvidia/FlowVision, Advania Data Centers and UberCloud, and sponsored by Hewlett Packard Enterprise and Intel. It is based on the development of Dassault’s Living Heart Model applied to Fluid-Structure Interaction of Artificial Aortic Heart Valves.