Coanda Research & Development

Coanda Research & Development

Research Services

Burnaby, British Columbia 2,248 followers

Process Modeling & Optimization | CFD | Artificial Intelligence

About us

Coanda, a Tetra Tech company, specializes in solving complex problems in engineering and beyond. Services include process flow modeling, Artificial Intelligence, forensic analysis, instrumentation, design optimization, engineering consulting, software development and training. Strategically located in Western Canada’s three largest cities, Coanda’s growing presence now includes our head office in the heart of Metro Vancouver, British Columbia; a second fully equipped branch in Edmonton, Alberta and a satellite office in Calgary, Alberta.

Website
http://www.coanda.ca
Industry
Research Services
Company size
51-200 employees
Headquarters
Burnaby, British Columbia
Type
Public Company
Founded
1996
Specialties
Research, CFD, Rheology, Data Analysis, Tailings, Mining, Oil & Gas, Fluid Dynamics, Measurement, Design, Data Collection, Process Engineering, Physical Modelling, Mixing, Analytical Chemistry, and Artificial Intelligence

Locations

Employees at Coanda Research & Development

Updates

  • We're glad to have been part of this incredible year!

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    323,599 followers

    We’re closing out the best year in Tetra Tech’s history. In 2024 our 30,000 employees brought innovative solutions to 25,000 clients on 110,000 projects in more locations around the world than ever before. We’re on our way to our goal of positively impacting the lives of 1 billion people by 2030 through innovative water, environment, sustainable infrastructure, and energy solutions. To our clients: Thank you for the trust you place in us every day to help you meet your goals. To our employees: Thank you for your dedication to #LeadingTheWay by #LeadingWithScience and for giving back to your communities. Thank you for a wonderful 2024. Here’s to an even better 2025!

  • Viscoelasticity in Material Rheology A lot of materials exhibit rheological behavior that places them somewhere between a liquid and a solid, classifying them as viscoelastic materials. Emphasizing the determination of elastic properties of a fluid, while acknowledging its viscous properties, provides scientists with valuable insights into its molecular structure. This understanding enables them to modify the structure to meet specific application requirements. Many polymeric liquids possess long chain molecules that randomly loop and entangle with other molecules. When subjected to sudden high shearing forces, this chain network results in the fluid initially exhibiting a solid-like resistance. Subsequently, the chains undergo elastic stretching, and eventually disentangle and orient in the direction of the shearing force, at which point the fluid begins to behave more like a liquid. At slow rates of deformation, polymer liquids predominantly exhibit viscous flow behavior, with elasticity being less apparent. At high shear rates, a significant portion of the deforming energy is absorbed by elastic intra- and intermolecular deformation, storing energy that can be recovered during a relaxation phase. Testing the viscous and elastic properties of materials can be crucial, particularly in production processes like coating, spraying, and extruding. Elastic behavior often takes precedence over viscous response in these processes, as it frequently governs flow anomalies that can limit production rates. Rather than subjecting viscoelastic samples to a constant stress for achieving steady-state flow, it is common practice to expose them to oscillating stresses or strains. This approach enables the rheological examination of their "at rest structure" without inducing mechanical disturbance. At Coanda, we often perform oscillatory measurements to investigate the viscoelastic properties of different materials. Our expertise extends beyond conventional measurements, encompassing the handling and preparation of structured fluids along with more sophisticated rheological techniques to better understand material characteristics. #Viscoelasticity #Rheology #oscillatory

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  • For the past few years, Coanda and our employees have been proud to contribute to a number charities and this year we are glad to be able to continue this tradition. We have set up holiday fundraising campaigns for the following charities in Western Canada: Calgary Food Bank https://lnkd.in/gJdpp8w9 Edmonton Food Bank: https://lnkd.in/gr-PBJnc Family Services of Greater Vancouver: https://lnkd.in/gc73cdse Coanda will be matching staff donations dollar for dollar, doubling your efforts to reach as far as possible. Please help us support these worthy causes before Friday, December 20th 2024. Thank you in advance for your generosity & support! #CoandaCares #CommunityFirst #GiveBack #TogetherWeCanMakeADifference #charity #christmascharity #TtGivesBack

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  • Did you know that Coanda offers a full suite of Research & Development services to support the Water and Wastewater industries? We have decades of expertise in analyzing, evaluating, and optimizing existing water-related processes, combining physical and numerical modeling techniques including Computational Fluid Dynamics (CFD). We have also played a key role in assisting clients develop new installations and troubleshoot large infrastructure projects all over the world. Read more about our capabilities and expertise in the water space at our new dedicated webpage: https://lnkd.in/gcR-qcZN #waterindustry #Wastewater #research #ComputationalFluidDynamics #CFD #infrastructure

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  • We previously introduced the topic of sequestration and storage, providing examples of natural storage sites. However, the capacity of the oceans, plant life, and natural rock formations for permanent storage within a timeframe needed to lessen the impact of climate change is limited. We must therefore look for other safe and permanent storage sites for carbon removed from the atmosphere. In this post, we introduce proposed methods of trapping captured CO2 underground in geological formations. Geologic sequestration refers to the long-term storage of gaseous, liquid, or supercritical carbon dioxide in underground sites. The current focus is primarily on storage in saline formations, depleted oil and gas reservoirs, and unmineable coal seams. However, before any solution(s) can be implemented, it is first necessary to understand how CO2 will behave once injected underground, in order to minimize leakage back to the surface. Head over to our website to read the rest of this article: https://bit.ly/Coanda-CO2 #carbon #sequestration #CO2 #Geologic #oilandgas #criticalpoint #research #cleantech

    • Carbon Dioxide Pressure Temperature Phase Diagram
  • Rodrigo holds a Diploma of Technology in Mechanical Engineering Design from the British Columbia Institute of Technology. He has been an integral part of Coanda since 2010. His multifaceted expertise encompasses several critical areas. As the laboratory manager in Edmonton, Rodrigo oversees lab operations, equipment maintenance, and efficient processes. He excels in designing and upgrading test rigs and ensuring accurate and reliable results during testing processes. Beyond testing, Rodrigo actively promotes safety protocols within the organization, fostering a secure work environment for employees. Additionally, Rodrigo’s involvement extends to facility planning which includes ventilation, electrical, mechanical upgrades and infrastructure layout design. His effective project management skills keep projects on track, and he also streamlines day-to-day operations. Rodrigo’s dedication, adaptability, and diverse skill set make him an indispensable asset to Coanda’s Edmonton team. #laboratorymanager #MechanicalEngineering #Technology #equipment #safetyprotocols #infrastructure #projectmanagement #Coanda #ourteam

    • portrait of Rodrigo Naranjo
  • Caisson use to improve tailings dredging efficiency Management of fluid fine #tailings (FFT) in oil sands operations requires harvesting it from tailings ponds via dredge pumps followed by chemical/mechanical treatment. One of the challenges during harvesting is cone formation between the clear water layer and tailings, which adversely affects the density of FFT and its consistent delivery to the tailings processing facilities. The coning occurs due to the non-Newtonian nature of the FFT material. Currently, the main mitigation strategy is to move the dredge from time to time to a different location outside of the developed cone. However, such interventions are costly and necessitate frequent process interruptions. Decreasing the frequency of #dredge moves can reduce costs and streamline the withdrawal process. Therefore, improving the ability to withdraw denser material and develop a shallower cone can be very beneficial. Recently, Coanda completed an IOSI (Institute for Oil Sand Innovation) funded study to investigate the use of a #caisson —a large diameter cylinder placed coaxially around the dredge pipe—to mitigate the coning phenomenon. This is accomplished by increasing the effective dredge diameter and, therefore, the amount of slurry material withdrawn prior to significant density decrease. The study combined rheological experiments of aged material (to quantify the thixotropic nature of FFT), along with the development of a mathematical thixotropy model coupled with CFD flow simulations. In addition, small-scale withdrawal tests were conducted in Coanda’s lab to validate the comprehensive model, and finally, the model was applied to commercial tailing ponds to evaluate the advantages of a caisson. As can be seen from the graph, dredging with the caisson results in higher density of the withdrawn slurry but the variability of the material increases, evidenced by density fluctuations, particularly during the first 50 hours of the withdrawal process. The density distribution contour plots highlight the profile changes inside the caisson as the denser slurry reaches the dredge from under the caisson without engaging less dense material. Outside of the caisson, however, the density profiles are very similar.

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  • One of Coanda's senior research scientists, fluid dynamicist Dr. Marvin Weiss presented at #WEFTEC2024: https://lnkd.in/gjETuMJa

    View profile for Kari Nemiro, graphic

    Marketing Enthusiast I SMPS Central Florida President

    Great to be at WEFTEC with my amazing Tetra Tech colleagues! Exciting conversations and innovations happening here in water quality, sustainability, and resilience. Proud to be part of a team driving the future of water solutions. #WEFTEC2024 #TetraTech #WaterInnovation

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  • Demand forecasting, predicting the quantity of items desired at a future date, plays a key role in many businesses. Traditionally, the predicted items are goods and services for a consumer market, but the same techniques can be transferred to other areas such as predicting hospital admissions or the number of participants requiring access to a homeless shelter. Demand forecasting has a long history, using both classical statistic methods (e.g. ARIMA models) and more modern machine learning methods including time-series specific forecasting (e.g. LSTMs). These methods can be adapted depending on the data and forecasting goal. For instance, goods data are often hierarchical where the sales are reported geographically by province, region, and individual store; and grouped by main product type, a sub-category, all the way down to an individual product number. In these cases, using both the aggregate product type and regional data, and the finer product number and store data together can produce more tailored models. These models can predict both national sales and the amount of a specific product to stock at a particular store. In some scenarios, the demand will be greater than the available stock or capacity. A provider needs to be able to react to such situations by increasing inventory or adjusting the sales forecast. One example is providing beds at homeless shelters. If a particular shelter can predict that they will have a demand for more beds than they have available, they can plan ahead and liaise with other nearby shelters. A similar example is related to hospital intakes with the goal of predicting both the number of intakes, how many of those expected intakes will require a bed, and their likely length of stay. Accurate forecasting is key to many industries and businesses. The nuances of a particular application - available data, specific prediction goal, extra conditions (e.g. storage space, capacity, etc.) – mean that there is no universal “best” model and that the best performance is likely obtained from a customized, application-specific model. #DemandForecasting #datascience #data #statistics #machinelearning #accurate #customresearch #project

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