This page will document the work and progress involved in selecting and validating an adhesive option for aero-chassis integration.
Document used to compile all the work is here:
Things to look for when selecting adhesives
When deciding on what adhesive to use, one of the first things that should come to mind is identifying what substrates need to be bonded together. Most adhesives are engineered for a certain application or a limited set of materials, e.g. only wood or only steels.
For this project, the main substrates involve 4130 chromoly steel and carbon fiber reinforced plastic (CFRP). One can begin researching adhesive suppliers that have these types of adhesives and compiling a list of potential options. It is also very useful to contact adhesive suppliers directly to seek their technical expertise on what options they recommend, which can greatly reduce your research time. Some companies may not be in a position to sponsor large quantities of adhesives for free, but they may still try to offer their technical expertise as a substitute for qualifying for our sponsorship rewards.
There are many types of categories of adhesives that are meant for larger or smaller applications. By researching adhesives for your specific application, you will naturally find a common adhesive category that often shows up. Research can also be done on the adhesive categories if one is obliged to specialize in this area.
Our specific application includes large loading and large impact which calls for a stronger adhesive category. Research has found that structural epoxy adhesive are the primary options for this application.
Afterwards, there are many other adhesive factors such as working time, curing time, etc. that will be factored into the final adhesive choice. The primary focus for this project was to find an adhesive that was appropriately specified based on its adhesive strength.
How the adhesive strength required was calculated
The adhesive must sustain all appropriate loading that individual components of the car are expected to withstand. For example, aerobody panels are not expected to be structural as per regulation therefore it only needs to withstand its own weight. The bonding between the chassis and the bottom panel is expected to be structural as per our design requirements for the car to function safely therefore it needs to withstand a 2G bump and vehicle collisions (based on regulation).
The analysis for adhesive strength focused on the larger loading scenarios. If an adhesive was selected based on the strength requirement of a larger load scenario, then applications with lesser load conditions will also be accounted for.
The approach for calculating adhesive strength involved hand calculations of simplified force models and simulations using Ansys Static Structural. A simplified force model involves creating a more simplified and worst case scenario. This was to be done because there exists multiple adhesive joints between the bonding of two components, each at different angles. This made it difficult to accurately calculate the force distribution using solely hand calculations. Simulations were used to get a better approximation of the expected force the adhesive would endure. Figure 1 shows how the bonding in MS XIV can become more complex when more adhesive joints are involved which brings the need for simulations.
Figure 1: Images to show complex bonding in MS XIV compared to more basic bonding scenarios
should probably divide this into the scenarios looked at: 2G bump and Crash Scenarios
Make tips for creating simplified model; worst case scenario
go from hand calc approach to simulation set up (features used)
display hand calc results and sim results in an organized table + should show formulas used as equations
lastly talk about design safety factor for adhesives -
There are two main loading scenarios that the vehicle should be designed towards:
2G bump (ASC2020, Appendix F, F.2)
This basically features a loading scenario consisting of twice the weight of the car’s mass
Vehicle collision scenarios. (ASC2020, Appendix F, F.3)
There are a total of 12 loading scenarios featuring a 5G impact at different directions and angles
Not all carbon fibre parts are expected to be structural therefore selected crash scenarios are placed at higher priority for analysis
Figure 2: Vehicle Collision Scenarios (ASC 2020, Appendix F, F.3.3)
Bonding scenarios in MS XIV that were considered in this analysis
The bonding between the Chassis and the Bottom Panel must be structural.
This structure contributes to the foundation of the car.
The bonding between the bulkheads and the Chassis.
Bulkheads A and C cover the front and back of the Chassis.
They are used for cover and may be used for mounting.
They are not designed to be structural; the Chassis is primarily responsible for withstanding vehicle impacts
 |  |  |
Figure 3: Shows the bonding area and force diagram for the bonding between the Chassis and Bottom Panel. Bulkhead A can be seen at the front (to the left) and Bulkhead C can be seen at the back (to the right). | Figure 4: Bonding areas for Bulkhead A | Figure 5: Bonding areas for Bulkhead C |
Bonding Scenario | Design Requirement | Loading Scenario | Expected Stress | Notes |
|---|---|---|---|---|
Chassis and Bottom Panel | Structural | 2G Bump | Tensile | This analysis laid the foundation for adhesive selection |
Vehicle Crash Scenarios | Shear | |||
Bulkheads to Chassis | Strong enough to allow mounting of potential dynamic assembly parts | 2G Bump | Shear | Later in the analysis, bulkheads were concluded to not be structural which led to ceasing its analysis. Documentation is still written for educational purposes. |
Vehicle Crash Scenarios | Tensile |
Safety Factor of Adhesives can be found on this page:
Adhesive Research (Types of Adhesives, Adhesive Behaviour, Adhesive Design Tips)
Final Decision on Adhesive and Quantity
Testing and Validation