The rack is used to ship automotive
components from the supplier site to the
assembly site.The design had to accommodate
for maximum shipping density, component
protection and ergonomics.
Industry engineering process evolves from Hardware based development to Digital based development. This process innovation increases efficiency, reduces development period, and enhances product quality. CAE's responsibility increases and encounter high demand from design engineering, test, styling, and upper management.
How CAE can meet the expectations and can evolve to be the core functionality in development process?
Speakers
Dr. Byungsik Kang, Vice President, Hyundai Kia Motors
Developing Commercial Vehicles Inspired by NatureAltair
As Germany's largest independent engineering partner to the worldwide automotive industry, EDAG is continuously seeking for new technologies and innovative processes to streamline vehicle development. EDAG has a profound expertise in integrated development and the optimization of vehicles, production facilities, derivatives, and modules. To meet fuel efficiency and emission reduction goals, structurally efficient lightweight designs are demanded in the development of passenger cars and commercial vehicles alike. To fulfill customer demands and to deliver lighter and yet fully functional and validated components in shorter time, EDAG is leveraging its engineering knowledge to combine state-of-the-art computer aided engineering tools, in this case Altair's OptiStruct, with new production technologies such as additive manufacturing. OptiStruct enabled the EDAG engineers to design lightweight and, by being inspired by nature, yet stiff structures of a cabin and a chassis. The components were then manufactured using additive manufacturing methods. To find the optimal solution for the final design the engineers later also conducted multi-physical optimizations, combining strength and crash demands of the vehicle, using an equivalent linear approach. The entire development and manufacturing process for the cabin and chassis structures will be subject of this presentation, showing how a combination of topology optimization and additive manufacturing leads to lighter and stiffer products. The project is a prime example of how mature CAE technology can be adjusted and used in combination with new manufacturing methods to introduce revolutionary structural enhancements within the transportation sector.
Speakers
Andreas Pfeiffer, Development Engineer, EDAG
Industry engineering process evolves from Hardware based development to Digital based development. This process innovation increases efficiency, reduces development period, and enhances product quality. CAE's responsibility increases and encounter high demand from design engineering, test, styling, and upper management.
How CAE can meet the expectations and can evolve to be the core functionality in development process?
Speakers
Dr. Byungsik Kang, Vice President, Hyundai Kia Motors
Developing Commercial Vehicles Inspired by NatureAltair
As Germany's largest independent engineering partner to the worldwide automotive industry, EDAG is continuously seeking for new technologies and innovative processes to streamline vehicle development. EDAG has a profound expertise in integrated development and the optimization of vehicles, production facilities, derivatives, and modules. To meet fuel efficiency and emission reduction goals, structurally efficient lightweight designs are demanded in the development of passenger cars and commercial vehicles alike. To fulfill customer demands and to deliver lighter and yet fully functional and validated components in shorter time, EDAG is leveraging its engineering knowledge to combine state-of-the-art computer aided engineering tools, in this case Altair's OptiStruct, with new production technologies such as additive manufacturing. OptiStruct enabled the EDAG engineers to design lightweight and, by being inspired by nature, yet stiff structures of a cabin and a chassis. The components were then manufactured using additive manufacturing methods. To find the optimal solution for the final design the engineers later also conducted multi-physical optimizations, combining strength and crash demands of the vehicle, using an equivalent linear approach. The entire development and manufacturing process for the cabin and chassis structures will be subject of this presentation, showing how a combination of topology optimization and additive manufacturing leads to lighter and stiffer products. The project is a prime example of how mature CAE technology can be adjusted and used in combination with new manufacturing methods to introduce revolutionary structural enhancements within the transportation sector.
Speakers
Andreas Pfeiffer, Development Engineer, EDAG
Surrogate Model-Based Reliability Analysis of Composite UAV Wing facilitation...Altair
Numerical simulation becomes increasingly strategic to design innovative products and to set up their manufacturing processes, reducing simultaneously development costs and time to market while increasing quality and reliability.
To support this evolution, SILKAN develops a platform for the integration of various types of simulation software, named BUILDERTM.
BUILDERTM is an efficient, innovative and scalable simulation-based platform designed to deal with the increasing use of complex numerical simulations applied to part design, system design or manufacturing processes.
The principal objectives of this platform are to:
Promote and structure the use of simulation
Standardize, parameterize and automate simulation processes.
Capture and re-use the best practices.
Facilitate coupling between different simulation levels and tools.
Improve collaboration across different project teams.
Facilitate access to simulation means for the uninitiated.
Accelerate design and production cycles.
Democratize the use of optimization and reliability procedures and better control manufacturing processes and failure risks.
An application example using BUILDERTM is addressed in this paper. It deals with the robust design of a composite UAV wing. The associated simulation workflow includes two principal steps.
During the first step, Matlab is used to estimate aerodynamic loads applied to the wing when as a function of flight parameters: air flow speed, angle of attack of the wing and aileron deflection angles. A Design of Experiment (DoE) is built by varying the flight parameters in order to cover all the flight domain of the UAV.
The aerodynamic loads thus obtained are then injected into OptiStruct to estimate Tsai-Wu failure criteria for the composite material. An efficient surrogate model is then built from the obtained Tasi-Wu criteria and covers the entire flight domain. Finally to conclude this first part, a failure probability , based on Tsai-Wu criteria, is estimated using the produced surrogate model.
In the second step the following optimization problem is defined using some design variables of the wing (essentially thicknesses of composite layers of the wing):
Wing Mass is calculated by Optistruct, and being evaluated using the step1. An evolutionary algorithm implemented into Dakota is used to perform this surrogate-model -
based optimization.
The set up, parameterization and automation of this complex simulation workflow is facilitated and achieved through the use of the BUILDERTM platform. The combination of different software at different levels of the workflow is also made accessible by the use of BUILDERTM.
Speakers
Samir Ben Chaabane, Numerical Simulation Manager for EMEA, SILKAN S.A
Tecosim research project: Reducing calculation times for crash modelsTECOSIM Group
Due to increasingly shorter development times and high licence fees, there is a desire for calculations to be completed as quickly as possible while ensuring the same quality of results. As part of a research project TECOSIM realise significant saving on calculation times for crash models.
TECOSIM project: Automatic bolt generator for crash simulationsTECOSIM Group
In crash simulations, bolt connections are generally modeled as simplified analogous models (Beams or Connectors). More efficient modelling at a favourable cost is required. In a project TECOSIM develop an automatic bolt generator for crash simulations in ABAQUS.
Fitman webinar 2015 09-21 Dynamic Visualisation and Interaction (DyVisual)FITMAN FI
A webinar on the Dynamic Visualisation and Interaction (DyVisual) Specific Enabler (SE) developed in FITMAN project. It is based on the FiVES implementation of the FI-WARE synchronisation GE. In the context of FITMAN, DyVisual will be used for synchronising and visualising use case specific events triggered by the DyCEP SE. The visualisation infrastructure combines several GE implementations, with FiVES as multi-user synchronisation framework, including KIARA as transport layer and XML3D as web-based 3D visualisation approach for the DyVisual web-clients. Nevertheless, other client frameworks can be supported by implementing the required client plugins. Presented by Klaus Fischer from DFKI GmbH
Topology optimization to guide the architecture of a BIW structure, challenge...Altair
For automotive industry, lightweight design is one of the five key factors among engine enhancement, aerodynamics, rolling resistance and energy management to overcome challenges due to environmental regulations. Thanks to new developments, recent models weigh 140 kg to 200 kg lighter than their predecessors. But to achieve more ambitious objectives in vehicle weight, structural design optimization is necessary at all stages of the design process. This presentation shows how topology optimization could be used very early to guide the body-in-white design and reach the best compromises between the vehicle performance expectations and the architecture constraints. We first remind how applying topology optimization for sheet metal design remains difficult. Then we explain the conditions for a success. The complete optimization process is detailed from the computation model building phase to the optimization results and their complex conversion into a design made from stamped or folded parts. Finally we conclude with a short summary about the topology optimization method and highlight some remained issues.
Speakers
Benoît Guillaume, Optimization expert, PSA Peugeot Citroën - Centre Technique de Vélizy A
Due to recurrent lack of on time delivery of Drilling grid (made of a 2cm thick aluminium pad), 3D printing can potentially propose an alternative enlightened solution in 3D printing (topology optimization).
Speakers
Sébastien Haudrechy, Engineer, Airbus Group Aerospace
Car makers have to reduce consumption of vehicles and so, are continually looking for solutions to lighten components. For powertrain, components generally mean screwed assembly, contact and fitting interfaces, with different kind of loading to take into account (static and dynamic). Hence, we decided to apply with Altair assistance, a process of topology optimization on an assembly of gearbox housing in order to check its feasibility and efficiency. Several steps had to be solved from exhaustive identification of all mechanical constraints to execution of large models with Optistruct. By the end, the process has been defined and implemented on an existing gearbox and will be soon apply on the next one to design.
Speakers
Philippe Dausse, Modelization Specialist, PSA Peugeot Citroen Automobiles
Optimization Culture Arena at Volvo Car GroupAltair
CAE has been used for a long time in the vehicle industry. It has been an efficient method for replacing expensive physical testing and predicting the performance of a component, system or complete model. This process has been supported by a rapid increase of computer power. CAE methods for replacing physical testing will continue to develop, however a shift in focus and application of CAE methods for the early development phases can be seen in the vehicle industry. This indicates a trend to a more CAE and knowledge driven development. This will put high demands of development of CAE methods and tools to drive the design. Some key areas for this is efficient use of e.g. topology, thickness and material optimization, performance balancing, etc.
To support this shift to more upfront CAE an “Optimization Culture Arena” has been launched at Volvo Car Group. This arena is a cross technical network for knowledge sharing and optimization competence development at VCG that consist of people from CAE, attribute areas, design, testing, technical specialists, academy etc. The arena function is to support implementation of an optimization driven culture and support development of guidelines and methods regarding optimization. The arena is supported by a knowledge hub to spread latest news and planned activities and also handle a competence matrix to support exchange of knowledge. A geographic area will serve as a place to meet, get support and share good examples of CAE driven development.
Speakers
Harald Hasselblad, Senior Analysis Engineer, VOLVO CAR CORPORATION
Large scale topological optimisation: aircraft engine pylon caseAltair
An engine pylon holds the engine to the wing and ensures multiple others functions: aerodynamics, structure and systems. Moreover, it is designed to prevent a fire in the engine area from spreading to the wing. These multi-functions make the global pylon architecture design highly complex. Existing designs reach their limits regarding the aircraft performance requirements, with ever more powerful, bigger and hotter engines. Thus, the technological breakthrough becomes necessary to achieve better performance.
In the present work, we propose a new concept based on Additive Layer Manufacturing (ALM) process which eliminates many conventional constraints from the manufacturing process and can produce complex, precisely designed shapes.
Topological optimization, using ALTAIR’s finite element analysis software, is realized by integrating systems elements, fluid pipes mainly, to structural parts. Thus, these elements become structural unlike the existing design.
One objective of this work is to demonstrate the numerical feasibility of topology optimisation of large-size (5 m long, 0.83 m width and 1.19 m in height) and highly complex architecture design of an aeronautical structure.
The results show that a significant mass saving, more than 20%, can be achieved even with heavily constrained structure in terms of stresses, dimensions, interfaces, systems, etc. Furthermore, this study highlights benefits in the parts number which dropped by 97%.
Note that the existing engine pylon is made mostly of Titanium and Steel materials but for the topology optimisation a single material, Inconel 718, was chosen due to its best thermal and mechanical properties.
In order to ensure aerodynamic function, obtained organic shape structure is covered by custom-made cowls.
1/8 scale model is 3D printed by INITIAL company, using plastic material, can be exposed during the Altair Technology Conference.
Speakers
Abdelkader Salim, Innovation Engineer, SOGECLAIR Aerospace
Aircraft Finite Element Modelling for structure analysis using Altair ProductsAltair
The Airbus airframe design process has considerably evolved since 20 years with the constant improvement of numerical simulation capability and the computational means capacity. Today the size of Finite Element Models for aircraft structural behaviour study is exceeding the boundary of airframe components (fuselage section, wing); for the A350, a very large scale non-linear model of more than 60 million degrees of freedom has been developed to secure the static test campaign. This communication will illustrate the partnership with Altair and the use of Altair products for the creation and verification of very large models at Airbus. It will deal with: - Geometry preparation - Meshing - Property assignment - Assembly - Checking More generally, numerical simulation will play more and more a major role in the aircraft process, from the development of new concepts / derivatives to the support of the in-service fleet. Then, this presentation will also state the coming needs regarding model creation tools to cope with Airbus strategy.
Speakers
Marion Touboul, Ingénieur en Simulation Numérique - Calcul Structure, Airbus Opérations SAS
Surrogate Model-Based Reliability Analysis of Composite UAV Wing facilitation...Altair
Numerical simulation becomes increasingly strategic to design innovative products and to set up their manufacturing processes, reducing simultaneously development costs and time to market while increasing quality and reliability.
To support this evolution, SILKAN develops a platform for the integration of various types of simulation software, named BUILDERTM.
BUILDERTM is an efficient, innovative and scalable simulation-based platform designed to deal with the increasing use of complex numerical simulations applied to part design, system design or manufacturing processes.
The principal objectives of this platform are to:
Promote and structure the use of simulation
Standardize, parameterize and automate simulation processes.
Capture and re-use the best practices.
Facilitate coupling between different simulation levels and tools.
Improve collaboration across different project teams.
Facilitate access to simulation means for the uninitiated.
Accelerate design and production cycles.
Democratize the use of optimization and reliability procedures and better control manufacturing processes and failure risks.
An application example using BUILDERTM is addressed in this paper. It deals with the robust design of a composite UAV wing. The associated simulation workflow includes two principal steps.
During the first step, Matlab is used to estimate aerodynamic loads applied to the wing when as a function of flight parameters: air flow speed, angle of attack of the wing and aileron deflection angles. A Design of Experiment (DoE) is built by varying the flight parameters in order to cover all the flight domain of the UAV.
The aerodynamic loads thus obtained are then injected into OptiStruct to estimate Tsai-Wu failure criteria for the composite material. An efficient surrogate model is then built from the obtained Tasi-Wu criteria and covers the entire flight domain. Finally to conclude this first part, a failure probability , based on Tsai-Wu criteria, is estimated using the produced surrogate model.
In the second step the following optimization problem is defined using some design variables of the wing (essentially thicknesses of composite layers of the wing):
Wing Mass is calculated by Optistruct, and being evaluated using the step1. An evolutionary algorithm implemented into Dakota is used to perform this surrogate-model -
based optimization.
The set up, parameterization and automation of this complex simulation workflow is facilitated and achieved through the use of the BUILDERTM platform. The combination of different software at different levels of the workflow is also made accessible by the use of BUILDERTM.
Speakers
Samir Ben Chaabane, Numerical Simulation Manager for EMEA, SILKAN S.A
Tecosim research project: Reducing calculation times for crash modelsTECOSIM Group
Due to increasingly shorter development times and high licence fees, there is a desire for calculations to be completed as quickly as possible while ensuring the same quality of results. As part of a research project TECOSIM realise significant saving on calculation times for crash models.
TECOSIM project: Automatic bolt generator for crash simulationsTECOSIM Group
In crash simulations, bolt connections are generally modeled as simplified analogous models (Beams or Connectors). More efficient modelling at a favourable cost is required. In a project TECOSIM develop an automatic bolt generator for crash simulations in ABAQUS.
Fitman webinar 2015 09-21 Dynamic Visualisation and Interaction (DyVisual)FITMAN FI
A webinar on the Dynamic Visualisation and Interaction (DyVisual) Specific Enabler (SE) developed in FITMAN project. It is based on the FiVES implementation of the FI-WARE synchronisation GE. In the context of FITMAN, DyVisual will be used for synchronising and visualising use case specific events triggered by the DyCEP SE. The visualisation infrastructure combines several GE implementations, with FiVES as multi-user synchronisation framework, including KIARA as transport layer and XML3D as web-based 3D visualisation approach for the DyVisual web-clients. Nevertheless, other client frameworks can be supported by implementing the required client plugins. Presented by Klaus Fischer from DFKI GmbH
Topology optimization to guide the architecture of a BIW structure, challenge...Altair
For automotive industry, lightweight design is one of the five key factors among engine enhancement, aerodynamics, rolling resistance and energy management to overcome challenges due to environmental regulations. Thanks to new developments, recent models weigh 140 kg to 200 kg lighter than their predecessors. But to achieve more ambitious objectives in vehicle weight, structural design optimization is necessary at all stages of the design process. This presentation shows how topology optimization could be used very early to guide the body-in-white design and reach the best compromises between the vehicle performance expectations and the architecture constraints. We first remind how applying topology optimization for sheet metal design remains difficult. Then we explain the conditions for a success. The complete optimization process is detailed from the computation model building phase to the optimization results and their complex conversion into a design made from stamped or folded parts. Finally we conclude with a short summary about the topology optimization method and highlight some remained issues.
Speakers
Benoît Guillaume, Optimization expert, PSA Peugeot Citroën - Centre Technique de Vélizy A
Due to recurrent lack of on time delivery of Drilling grid (made of a 2cm thick aluminium pad), 3D printing can potentially propose an alternative enlightened solution in 3D printing (topology optimization).
Speakers
Sébastien Haudrechy, Engineer, Airbus Group Aerospace
Car makers have to reduce consumption of vehicles and so, are continually looking for solutions to lighten components. For powertrain, components generally mean screwed assembly, contact and fitting interfaces, with different kind of loading to take into account (static and dynamic). Hence, we decided to apply with Altair assistance, a process of topology optimization on an assembly of gearbox housing in order to check its feasibility and efficiency. Several steps had to be solved from exhaustive identification of all mechanical constraints to execution of large models with Optistruct. By the end, the process has been defined and implemented on an existing gearbox and will be soon apply on the next one to design.
Speakers
Philippe Dausse, Modelization Specialist, PSA Peugeot Citroen Automobiles
Optimization Culture Arena at Volvo Car GroupAltair
CAE has been used for a long time in the vehicle industry. It has been an efficient method for replacing expensive physical testing and predicting the performance of a component, system or complete model. This process has been supported by a rapid increase of computer power. CAE methods for replacing physical testing will continue to develop, however a shift in focus and application of CAE methods for the early development phases can be seen in the vehicle industry. This indicates a trend to a more CAE and knowledge driven development. This will put high demands of development of CAE methods and tools to drive the design. Some key areas for this is efficient use of e.g. topology, thickness and material optimization, performance balancing, etc.
To support this shift to more upfront CAE an “Optimization Culture Arena” has been launched at Volvo Car Group. This arena is a cross technical network for knowledge sharing and optimization competence development at VCG that consist of people from CAE, attribute areas, design, testing, technical specialists, academy etc. The arena function is to support implementation of an optimization driven culture and support development of guidelines and methods regarding optimization. The arena is supported by a knowledge hub to spread latest news and planned activities and also handle a competence matrix to support exchange of knowledge. A geographic area will serve as a place to meet, get support and share good examples of CAE driven development.
Speakers
Harald Hasselblad, Senior Analysis Engineer, VOLVO CAR CORPORATION
Large scale topological optimisation: aircraft engine pylon caseAltair
An engine pylon holds the engine to the wing and ensures multiple others functions: aerodynamics, structure and systems. Moreover, it is designed to prevent a fire in the engine area from spreading to the wing. These multi-functions make the global pylon architecture design highly complex. Existing designs reach their limits regarding the aircraft performance requirements, with ever more powerful, bigger and hotter engines. Thus, the technological breakthrough becomes necessary to achieve better performance.
In the present work, we propose a new concept based on Additive Layer Manufacturing (ALM) process which eliminates many conventional constraints from the manufacturing process and can produce complex, precisely designed shapes.
Topological optimization, using ALTAIR’s finite element analysis software, is realized by integrating systems elements, fluid pipes mainly, to structural parts. Thus, these elements become structural unlike the existing design.
One objective of this work is to demonstrate the numerical feasibility of topology optimisation of large-size (5 m long, 0.83 m width and 1.19 m in height) and highly complex architecture design of an aeronautical structure.
The results show that a significant mass saving, more than 20%, can be achieved even with heavily constrained structure in terms of stresses, dimensions, interfaces, systems, etc. Furthermore, this study highlights benefits in the parts number which dropped by 97%.
Note that the existing engine pylon is made mostly of Titanium and Steel materials but for the topology optimisation a single material, Inconel 718, was chosen due to its best thermal and mechanical properties.
In order to ensure aerodynamic function, obtained organic shape structure is covered by custom-made cowls.
1/8 scale model is 3D printed by INITIAL company, using plastic material, can be exposed during the Altair Technology Conference.
Speakers
Abdelkader Salim, Innovation Engineer, SOGECLAIR Aerospace
Aircraft Finite Element Modelling for structure analysis using Altair ProductsAltair
The Airbus airframe design process has considerably evolved since 20 years with the constant improvement of numerical simulation capability and the computational means capacity. Today the size of Finite Element Models for aircraft structural behaviour study is exceeding the boundary of airframe components (fuselage section, wing); for the A350, a very large scale non-linear model of more than 60 million degrees of freedom has been developed to secure the static test campaign. This communication will illustrate the partnership with Altair and the use of Altair products for the creation and verification of very large models at Airbus. It will deal with: - Geometry preparation - Meshing - Property assignment - Assembly - Checking More generally, numerical simulation will play more and more a major role in the aircraft process, from the development of new concepts / derivatives to the support of the in-service fleet. Then, this presentation will also state the coming needs regarding model creation tools to cope with Airbus strategy.
Speakers
Marion Touboul, Ingénieur en Simulation Numérique - Calcul Structure, Airbus Opérations SAS
Bikram Jeet (Achievements from 2006 - 2013)Bikram Jeet
This presentation shows some of the interesting projects snapshots that were completed under my supervision during 2006-2013.
Email: bj@bikramjeet.com
Website: www.bikramjeet.com
Our esteemed European client's vision is to establish a truly global portable printer device thus making it a necessary accessory for laptop,mobile phone and PDA users. The design needed to be innovative,
aesthetically good and consumer oriented.
This USA client of ours provides companies with an efficient method to transport their products throughout the supply chain: faster, better, safer and more cost-effectively.
The returnable packaging products are to be custom designed and are based on the component shipped viz., automotive, pharmaceuticals, food, appliances, fragile articles, and like-wise. The design calls for reusability, recyclable, ergonomics, costeffective and has to ensure safety of the component through transit.
Vee designed an external accessor y for a robotic application.It is a spring operated 2 jaw gripper arm with smooth opening and closing gripping action.
Software Tools: Solidworks
Industry: Design and Engineering Services
The Challenge
To design a heat-proof mechanically rigid solid state relay.
The Solution
Aesthetically various ranges of solid-state relays were designed
The scope involved using the Hand sketches
and iges data to develop a 3D model of the Toy
Wagon. Surfacing option of Solid works-2008
was extensively utilized to complete the model
Things to remember while upgrading the brakes of your carjennifermiller8137
Upgrading the brakes of your car? Keep these things in mind before doing so. Additionally, start using an OBD 2 GPS tracker so that you never miss a vehicle maintenance appointment. On top of this, a car GPS tracker will also let you master good driving habits that will let you increase the operational life of your car’s brakes.
The Octavia range embodies the design trend of the Škoda brand: a fusion of
aesthetics, safety and practicality. Whether you see the car as a whole or step
closer and explore its unique features, the Octavia range radiates with the
harmony of functionality and emotion
Ever been troubled by the blinking sign and didn’t know what to do?
Here’s a handy guide to dashboard symbols so that you’ll never be confused again!
Save them for later and save the trouble!
Fleet management these days is next to impossible without connected vehicle solutions. Why? Well, fleet trackers and accompanying connected vehicle management solutions tend to offer quite a few hard-to-ignore benefits to fleet managers and businesses alike. Let’s check them out!
Your VW's camshaft position sensor is crucial for engine performance. Signs of failure include engine misfires, difficulty starting, stalling at low speeds, reduced fuel efficiency, and the check engine light. Prompt inspection and replacement can prevent further damage and keep your VW running smoothly.
What Could Cause The Headlights On Your Porsche 911 To Stop WorkingLancer Service
Discover why your Porsche 911 headlights might flicker out unexpectedly. From aging bulbs to electrical gremlins and moisture mishaps, we're delving into the reasons behind the blackout. Stay tuned to illuminate the road ahead and ensure your lights shine bright for safer journeys.
Learn why monitoring your Mercedes' Exhaust Back Pressure (EBP) sensor is crucial. Understand its role in engine performance and emission reduction. Discover five warning signs of EBP sensor failure, from loss of power to increased emissions. Take action promptly to avoid costly repairs and maintain your Mercedes' reliability and efficiency.
𝘼𝙣𝙩𝙞𝙦𝙪𝙚 𝙋𝙡𝙖𝙨𝙩𝙞𝙘 𝙏𝙧𝙖𝙙𝙚𝙧𝙨 𝙞𝙨 𝙫𝙚𝙧𝙮 𝙛𝙖𝙢𝙤𝙪𝙨 𝙛𝙤𝙧 𝙢𝙖𝙣𝙪𝙛𝙖𝙘𝙩𝙪𝙧𝙞𝙣𝙜 𝙩𝙝𝙚𝙞𝙧 𝙥𝙧𝙤𝙙𝙪𝙘𝙩𝙨. 𝙒𝙚 𝙝𝙖𝙫𝙚 𝙖𝙡𝙡 𝙩𝙝𝙚 𝙥𝙡𝙖𝙨𝙩𝙞𝙘 𝙜𝙧𝙖𝙣𝙪𝙡𝙚𝙨 𝙪𝙨𝙚𝙙 𝙞𝙣 𝙖𝙪𝙩𝙤𝙢𝙤𝙩𝙞𝙫𝙚 𝙖𝙣𝙙 𝙖𝙪𝙩𝙤 𝙥𝙖𝙧𝙩𝙨 𝙖𝙣𝙙 𝙖𝙡𝙡 𝙩𝙝𝙚 𝙛𝙖𝙢𝙤𝙪𝙨 𝙘𝙤𝙢𝙥𝙖𝙣𝙞𝙚𝙨 𝙗𝙪𝙮 𝙩𝙝𝙚 𝙜𝙧𝙖𝙣𝙪𝙡𝙚𝙨 𝙛𝙧𝙤𝙢 𝙪𝙨.
Over the 10 years, we have gained a strong foothold in the market due to our range's high quality, competitive prices, and time-lined delivery schedules.
What Are The Immediate Steps To Take When The VW Temperature Light Starts Fla...Import Motorworks
Learn how to respond when the red temperature light flashes in your VW with this presentation. From checking coolant levels to seeking professional help, follow these steps promptly to prevent engine damage and ensure safety on the road.
1. Shipping rack
Project: Design , 3d modeling and detailing of Shipping /
Storage racks for a reputed Automotive
company
Description: The rack is used to ship automotive
components from the supplier site to the
assembly site. The design had to accommodate
for maximum shipping density, component
protection and ergonomics
Scope: Design the system to meet technical
specification and to meet performance
requirement
Prove the concept and provide manufacturing
drawings on approval of concept
Integrate with the in feed and delivery lines
Inputs: 3D model of the component and layout drawing
Out put: Manufacturing drawings in Solid works
The Challenge
Design of racks for fragile components like Wind shield.
Quick turnaround time of 48 hours
Value Addition
Engineering effort :- 20 Hrs per rack
Other benefits :- The client benefitted from quick turnaround time
and was able to improve business by 30%
www.veecreate.com
Case Study VEE Create
End-to-End Engineering Solutions
A Division of VeeTechnologies