Thursday, November 21, 2013

F1 2014 rules illustrated

Year 2014 will mark the start of a new era in Formula 1 which comes with many prominent rules changes.
In the next article I will try to explain some of them with illustrated examples, as I'm not keen on the idea that you need to be an engineer to understand the sport. In one sentence, the 2014 rules emphasize less on the aerodynamics as opposed to the energy recovery systems, power train and reliability.

Engine-wise aside, let's go for the outer, visible changes.

Nose shape

Quite simply, in order to prevent incidents, the nose of the car will be moved further lower down. The nose tip could be as low as 185 mm, which is pretty much at the height of the front wing. Apart from the visual change, one should expect major shift in 'under the nose' aerodynamics - prior to 2014 season the cars had large "mouths". In 2014, we are going to see low noses. We can still speculate whether teams are going to try the maximum allowed nose height in order to better manage the underside airflow.
Example of what it might look like follows, base image courtesy of Will Tyson

Image copyright: Will Tyson

Exhaust position

With the new regulations the exhaust positioning to gain aero effects will be heavily crippled. The rules say that there must be a single exhaust tail pipe (as opposed to the two we have today) exiting in the regions 170 - 185 mm behind the rear wheel center line and 350 - 500 mm above the reference plane. This means the exhaust pipe is likely to be situated just below where today we enjoy the so called "Monkey seats" - directly under the engine cover.
The final 150 mm of the tailpipe must be unobstructed right circular cylinder with its axis +/- 5° to the car 
center line when viewed from above the car and between 0° and 5° (tail up) to the reference plane when viewed from the side of the car. 
No bodywork behind this tailpipe will be allowed, which effectively dismisses various turning vanes to redirect hot gases towards the diffuser. This doesn't mean that the cars won't benefit from sealed diffusers, as the downwash / Coanda effect will be still there. 

Image copyright: Will Tyson

Camera positions

Prior to 2014, we could often see the housings behind the front wing center section with cameras being used for aerodynamic benefit. See below inside the circle: 


In 2014, the mandated position of the cameras will be at 325 - 525 mm above the reference plane, which means a lot higher than the position above.

Narrower wings

Front wings will be a little narrower next year with the width reduced from 1800 mm to 1650 mm (a reduction of 15 centimeters width).
The rear wing will also look a little different in 2014 compared to this year’s models. The lower beam wing is being outlawed and the main flap will be slightly shallower in profile.

Overall, it won't be unusual to see designs such as this one. Again, image model courtesy of Will Tyson - click on the image for full size.

If you want to continue the reading for everything regarding the engines, here's the link - http://f1framework.blogspot.com/2014/01/renault-2014-engine.html




Monday, November 4, 2013

F1 Rear Crash Structure analyzed

Another exciting post from Brian Garvey, who has already setup F1Displayed.com and shall present interesting series of parts one by one. Again, I'm publishing his surgical work, this time with Rear Crash Structure in details.

The internal construction of the rear crash structure had bothered me for a long time. I knew it held hidden secrets, from construction, to internal layout, to wall thicknesses, to hard point mounting methods, and so on. This, I needed to know all about, for future constructions.It really is a good item to study, since its design is not to be sneezed at considering its function.
Keep in mind it needs to protect the rear and dissipate a lot of energy should the need arise.
The amount of energy it does dissipate is really amazing, there was a lot to learn from this part.

I'm not going to do much talking about its construction,(famous last words) as for someone that has a keen eye, the pictures will be more than enough. Given that these sort of images do not exist, it was pretty exciting getting inside it. What you see below can be applied to a lot of things, from simple structures, to racing tubs, construction methods are similar (!but fiber direction is not!).

The age of this structure is 1997, I know a lot has progressed since then, but its a start, and should be good starting info should you want to dip your toes into something composite. Its construction could be a good starting point for a test structure to be based on. Obviously, You don't get the full idea of filament direction, or layup plan, but you do get the basics in the form of images for once, and not mildly descriptive text.

I'm sure, by the end of this, I will have a few guys saying that ”I could have told you how it was made without you cutting it up” Well, that's great, its a shame they wouldn't write it down, draw it,or discuss it without having to twist their arms off.

I understand that some cant say much, but surely, 15 yrs odd on, that may not be the case. Or, perhaps there is so many involved in one part, no one guy can describe it all, as he may not be present for all construction. Who knows. There is a large grey area out there in relation to composite/comb construction, and the mounting methods of various hard points. I do know loads on hard points differ, but it's a start.

Hard point mounting is also a very easy thing for someone to breeze over and appear to know what they are talking about. But, until you actually sit down, with a bunch of different colour markers(representing layers), the order at which you place the hard point, and what you do to keep it in there, without imposing on the main structures strength becomes not so apparent to the designer.

Enough talk…onto the part.
Its external construction is pretty simple, its laid into a two piece mould tool, the part line not straight, but instead following as it does on contoured parts, the point along the side where the two draft angles converge.

I do know from looking inside it, that the outer layers were laid in first(1mm thick(ish)), that cured, and then the four main hard points for the lower(x4(inserts bonded in. The outer layers were high Kevlar content.
Once these were cured, the hard points were drilled, and the inserts fitted.

I'm sure some form of thread minder was inserted to keep excess epoxy out of the inserts. I know the inserts were fitted before any other internal layers were fitted, as there was small amounts of run off epoxy present in the last most portions of the inserts. This epoxy flowed in there as additional layers and comb was laid up. This run-off epoxy was the same color as the epoxy used to bond in the first layer of aluminium honeycomb(6mm thick)so I can be certain the inserts were fitted before an internal structure was placed.

The hard points were 25mm round x 15mm thick, solid sections of carbon composite. They are constructed in a separate operation by stacking dozens of coin shaped fabric on each other until the part is 15mm high. Or, perhaps they were cut from 15mm composite plate.

They are very dense and were belt sanded to match approximately the interior corner radius of the first layers that were placed inside the female tools.
The outer circumferential edges(facing into the part) were also eased with the belt sander. Im guessing to rid high energy areas, and also to make smoothing easier.

Around these hard points was more epoxy, filleting them in nicely to their surroundings. The interior was wetted up, and the first layer of 6mm Al comb was placed down. It was cut pretty well to fit, and was cut around where the hard points had just been bonded.

More epoxy, this time with filler added, possibly hollow glass spheres was filled around the hard points, further bonding them in to their surroundings, some of this epoxy can be seem in the areas of comb surrounding the hard points.

In some of the images, the cross-section of the hard points will appear solid tube like, this is not the case, it is just the way the saw has displayed them, and their cross-sectional profile at the point.

Once the first comb layer was fitted, there then was a .5mm layer installed ontop. This layer measures half the thickness of the first external lay up mentioned above. It is also of high Kevlar content, I do see carbon in there too, so a hybrid weave fabric.
This layer covered the first comb layer, and the hardpoints/epoxy filler.

Over this, were laid last interior layers including another comb layer, same thickness as the outer first lay up, 1mm thick, the comb also 6mm. Im guessing at this stage, epoxy hard point filler, all comb layers, and last interior layer were vacuum bagged to all conform neatly to each other inside the structure, and to the outer first cured layup. The bag being inserted down into the whole assembly. Inside out vac bagging if you like.

We know from the way that the inserts were fitted(see above) that the outer and first lay up had been cured prior to the internal structure being built in, so whether or not the part was left in the tool the entire time is debatable. Perhaps for lay up it was removed for ease of part handling, then refitted for vacuuming.

Once all the internal layers were cured, the bag was removed and the 50mm thick comb sections and partitions were added.These were all done in the one hit, and done wet lay.They are 1mm thick and there is seven in total including the last, outer thrust cap panel, adjacent to the gearbox.

Interestingly, the first section of comb is kept back 10mm from the rear(end tip) wall of the crash structure. Looks like the nose and walls take some of the energy before it starts to progress on into the 50mm comb structures.

The comb is a good fit to the inner walls of structure, as are the kevlar partitions. The first rear most nose comb is fitted, and the rest are stacked onto it. The rear most comb locates via interference fit with the walls, keeping the nose 10mm as mentioned from the end wall.

The kevlar partitions are filleted where they meet the structure walls as the operator progresses. The interior has a heavy coat of epoxy applied also.The end of the structure where it attaches to the rear of the car is also mounted with hardpoints inside the structure. This time, 8mm composite plate is used. Two strips down either side run from top to bottom. These are shaped on the other edges to match mating profile.

These strips get bonded to the first layup as with the first layer of 6mm comb. It is also bonded into the first comb layer with filled epoxy.This solid composite strip closes off the edge of the first comb layer. The .5mm later ontop of the first comb stops at the interior rear of strip.

The second comb is placed and cut at the same place the first comb layer stops, at the rear of strip.
A 45 degree fillet of filled epoxy is then formed at the end of the second comb layer and is filleted down onto the solid composite strip. The final interior 1mm layer is then laid down over the second comb layer and covers this 45 degree fillet, and ends at the out profile of the composite strip.

This can be seen if you look carefully at the pictures, as can everything else mentioned.
One last thing to look out for, the second last partition(gearbox end) does not touch the interior walls.
The partitions may look angled from the photos, but they are 90 degrees to the road surface when the structure is fitted to the car.

The structure before cutting:



















The cut sections next,







Next, a load of various pictures in no real order. If you look carefully enough, you’ll figure out where each piece goes, or not!
This is the hardpoint I'm most interested in, and what I talked about above. There are four in total, but I'm just going after one.



The hard points, clearly visible,





















The hardpoint cut out for further study,







You will also notice in some of the photos, the pinkish glue line. This is an epoxy sheet film, used with honeycomb. Its main purpose is to provide a good glue line between comb and composite at all points of contact, but at the same time being just enough so to avoid filling the comb with epoxy, resulting in extra weight.























Next, the small section I cut out, for a closer look at hard point mounting,here is where the piece was taken from,





The piece,











Opening the piece to reveal carbon disc hard point,























Macro shots,

The hole is drilled, and tapped. The insert is not self tapping since the cut threads extend past the insert. Once home, the lock barbs are driven in and the spacer fitted outside it. No epoxy evident on spacer, or insert. Looks like interference fit holds in spacer. Spacer would be pretty good at the transferal of shear loads also, should they arise.





The solid disc’s layers can clearly be seen here,







They got the hole pretty much in the middle…



The rear section of the solid carbon.F disc de-laminated on removal, possibly one of the toughest parts I've ever had to remove for r+d, It was ‘well’ in there to say the least.





So, there you have it. An extremely good learning tool for looking at. I've studied these structures a lot, from various docs, to Nasa PDFs, to aerospace stuff all mainly aimed at testing, and not so much actual full constructions or images.

What you see here should answer a lot of questions depending on what you want to make some day, it certainly did for me. I do realize that the nearer crash structures are hollow, and contain just an ‘x’ in carbon/Kevlar internally, but the honeycomb construction methods above are useful for a lot of construction techniques.