Quote from: livingjw on 04/26/2020 05:32 pmYes, the tiles are ~-05% fiber and binder and 95% void. For attachment points, maybe when they are casting/molding the tiles, they insert a fiber matrix that terminates in one or more attachment points?Or they could glue an attachment plate onto the bottom of each tile, but that could add a lot of weight.
Yes, the tiles are ~-05% fiber and binder and 95% void.
In my design the tiles get narrower as you move towards the apex. At some point depending on the degree of curvature relative to the size of the tiles it might also be necessary to decrease their height as well.
Quote from: Slarty1080 on 04/26/2020 01:01 pmIn my design the tiles get narrower as you move towards the apex. At some point depending on the degree of curvature relative to the size of the tiles it might also be necessary to decrease their height as well.It looks to me like the radius in the in that direction is constant, so you would not need to decrease the height. Getting narrower is enough.
Quote from: DusanC on 04/26/2020 01:38 pmI have a questions based on excellent BCG's photos https://forum.nasaspaceflight.com/index.php?topic=48895.msg2072270#msg2072270There are indications that some tiles on SS SN4 are made by coating bent sheet metal. There are even some areas where there is small surface damage to the coating. Is there any other explanation?The Shuttle had thin high temperature pads which would be inserted in the gaps between tiles to prevent heat getting under the tile.Elon is trying to avoid having to do this by using hexagonal tiles, however he may have to resign himself to there being a need for something to be positioned between the tiles.
I have a questions based on excellent BCG's photos https://forum.nasaspaceflight.com/index.php?topic=48895.msg2072270#msg2072270There are indications that some tiles on SS SN4 are made by coating bent sheet metal. There are even some areas where there is small surface damage to the coating. Is there any other explanation?
Quote from: Karloss12 on 04/26/2020 01:58 pmQuote from: DusanC on 04/26/2020 01:38 pmI have a questions based on excellent BCG's photos https://forum.nasaspaceflight.com/index.php?topic=48895.msg2072270#msg2072270There are indications that some tiles on SS SN4 are made by coating bent sheet metal. There are even some areas where there is small surface damage to the coating. Is there any other explanation?The Shuttle had thin high temperature pads which would be inserted in the gaps between tiles to prevent heat getting under the tile.Elon is trying to avoid having to do this by using hexagonal tiles, however he may have to resign himself to there being a need for something to be positioned between the tiles.They were called "gap fillers" and were put in to stop rentry plasma hitting the aluminum skin.Then the tiles were glued to thin nylon fabric layers (AIU like the stuff womens tights are made out of) to handle the contraction and expansion. But steels TCE is substantially less than aluminiums so such a support pad should be redundant. Also is it my impression that each tile is on a single point mounting? In principle each tile could tip and tile (slightly) in the airstream. This might be enough to avoid flow separation and any need to curve every tile to match the underlying surface. But this is the easy part. Wrapping that TPS around the wings/drag surfaces/whatever is likely to prove much trickier.
Think that difference is worth noting: How much time-cost-effort-$ does it require to initially fabricate-install , versus how much time-cost-effort-$ does it require to maintain-replace? Obviously robustness of solution affects cost of both. Guess is that SpaceX would prefer a more robust solution that decreases maintenance.
Quote from: DusanC on 04/26/2020 09:31 amQuote from: Keldor on 04/26/2020 09:07 amQuote from: DreamyPickle on 04/26/2020 07:35 amHaving a large number of intricate tile shapes might not be a problem by itself as long as they don't require a manual repairs. Unlike on the Shuttle there is no chance of getting hit by debris during launch.For tiling a rounded cone they could do it using the same slightly warped hexagon at each height point.But they might eventually go for unique shapes of varying thickness anyway in order to optimize mass.It's actually mathematically impossible to tile a rounded cone with any sort of uniform warped hexagon. If you try it, you'll find that it works alright at the beginning, but as the surface continues curving, your hexagons will become more and more distorted until you're forced to add pentagons to the mix. This is a direct consequence of the Euler Identity.There's just no way to avoid requiring a large number of different tile shapes when trying to tile a surface with non-zero curvature. (A cylinder has, mathematically speaking, zero curvature, just to be clear on this. Not so for a rounded cone)Mathematically you're correct.But engineers like to cheat 1 type of tile in 2 forms, whole and cut in half.PS: I'd like to emphasize that only 200deg of SS needs to be tiled.Long straight lines like that are problematic.In the words of Elon when asked why hexagons:QuoteNo straight path for hot gas to accelerate through the gapshttps://twitter.com/elonmusk/status/1107379727302451200
Quote from: Keldor on 04/26/2020 09:07 amQuote from: DreamyPickle on 04/26/2020 07:35 amHaving a large number of intricate tile shapes might not be a problem by itself as long as they don't require a manual repairs. Unlike on the Shuttle there is no chance of getting hit by debris during launch.For tiling a rounded cone they could do it using the same slightly warped hexagon at each height point.But they might eventually go for unique shapes of varying thickness anyway in order to optimize mass.It's actually mathematically impossible to tile a rounded cone with any sort of uniform warped hexagon. If you try it, you'll find that it works alright at the beginning, but as the surface continues curving, your hexagons will become more and more distorted until you're forced to add pentagons to the mix. This is a direct consequence of the Euler Identity.There's just no way to avoid requiring a large number of different tile shapes when trying to tile a surface with non-zero curvature. (A cylinder has, mathematically speaking, zero curvature, just to be clear on this. Not so for a rounded cone)Mathematically you're correct.But engineers like to cheat 1 type of tile in 2 forms, whole and cut in half.PS: I'd like to emphasize that only 200deg of SS needs to be tiled.
Quote from: DreamyPickle on 04/26/2020 07:35 amHaving a large number of intricate tile shapes might not be a problem by itself as long as they don't require a manual repairs. Unlike on the Shuttle there is no chance of getting hit by debris during launch.For tiling a rounded cone they could do it using the same slightly warped hexagon at each height point.But they might eventually go for unique shapes of varying thickness anyway in order to optimize mass.It's actually mathematically impossible to tile a rounded cone with any sort of uniform warped hexagon. If you try it, you'll find that it works alright at the beginning, but as the surface continues curving, your hexagons will become more and more distorted until you're forced to add pentagons to the mix. This is a direct consequence of the Euler Identity.There's just no way to avoid requiring a large number of different tile shapes when trying to tile a surface with non-zero curvature. (A cylinder has, mathematically speaking, zero curvature, just to be clear on this. Not so for a rounded cone)
Having a large number of intricate tile shapes might not be a problem by itself as long as they don't require a manual repairs. Unlike on the Shuttle there is no chance of getting hit by debris during launch.For tiling a rounded cone they could do it using the same slightly warped hexagon at each height point.But they might eventually go for unique shapes of varying thickness anyway in order to optimize mass.
No straight path for hot gas to accelerate through the gaps
SS SN04 tiles have 2 types of snap mounting:1. On all 6 sides2. On 3 studs
...Also is it my impression that each tile is on a single point mounting? In principle each tile could tip and tile (slightly) in the airstream. This might be enough to avoid flow separation and any need to curve every tile to match the underlying surface. ...
Quote from: DusanC on 04/26/2020 07:46 pmSS SN04 tiles have 2 types of snap mounting:1. On all 6 sides2. On 3 studsPlease provide a definitive reference? We have conjecture as to attachment for both. Caution that what we have seen is not necessarily indicative of final configuration. Thanks.
If there are 100 rows, each with indentical tiles, and each tile has the same fastening arrangement, then every tile on the SS can be cut from the same identical raw tile (using a water jet cutter).It would be to much weight to take 100-200 spare tiles to mars. Instead they will just take half a dozen or so of these raw tiles as spares and use simple hand tools to cut them to any of the 100 or so different shapes (corresponding to 100 different rows).They would have to get some practice in custom making tiles before they left for Mars.
Quote from: envy887 on 04/26/2020 07:01 pmQuote from: Slarty1080 on 04/26/2020 01:01 pmIn my design the tiles get narrower as you move towards the apex. At some point depending on the degree of curvature relative to the size of the tiles it might also be necessary to decrease their height as well.It looks to me like the radius in the in that direction is constant, so you would not need to decrease the height. Getting narrower is enough.Are you considering that the heat shield only needs to be on one side? That is, they only go ~halfway around. That means that the ends of a row of tiles need not align with the previous row. Does that mean that the same sized tiles could be used for adjacent tile rows? Maybe not, but it is an additional degree of freedom to consider.
The problem is that each tile needs to align with those in front and behind it. On a curved surface this means the angles on the hexagons have to change (see my diagram at the top of page 1) unless the intention is for tile overlap, in which case regular hexagons might be tried, but I think it would be very messy. The areas of overlap would change and the zig-zag peaks and troughs between layers of tiles would run out of phase and wouldn't line up.
Quote from: Slarty1080 on 04/26/2020 08:24 pmThe problem is that each tile needs to align with those in front and behind it. On a curved surface this means the angles on the hexagons have to change (see my diagram at the top of page 1) unless the intention is for tile overlap, in which case regular hexagons might be tried, but I think it would be very messy. The areas of overlap would change and the zig-zag peaks and troughs between layers of tiles would run out of phase and wouldn't line up.Practically there are 2 issues here. 1) Finding the minimum number of tile type and sizes that map the surface. Kind of like how you render a CAD image with the minimum number (and type) of polygons.2) How the edges of those polygons line up. 1) is relatively simple (for simple shapes) 2) Gets much more complex. The real question is how good does the polygonal approximation to the underlying surface need to be?Because an exact match would imply thick tiles that can be machined to a curve (which is how they did it with the shuttle, and part of the very high cost of maintenance).My instinct (and the work of DLR sounding rocket test) is that is not necessary provided the discontinuities are a fairly small part of the boundary layer thickness If so you can get away with flat files of the same shape, but multiple sizes, all machined from a standard size billet. That problem gets a lt trickier on the fin leading edges, with high curvature, needing a lot of small (but IMHO still standard shaped) tiles to handle the leading edge. The area between the body and the control surfaces being exceptionally tricky.
Quote from: Eylrid on 04/26/2020 01:08 pmQuote from: DusanC on 04/26/2020 09:31 amQuote from: Keldor on 04/26/2020 09:07 amQuote from: DreamyPickle on 04/26/2020 07:35 amHaving a large number of intricate tile shapes might not be a problem by itself as long as they don't require a manual repairs. Unlike on the Shuttle there is no chance of getting hit by debris during launch.For tiling a rounded cone they could do it using the same slightly warped hexagon at each height point.But they might eventually go for unique shapes of varying thickness anyway in order to optimize mass.It's actually mathematically impossible to tile a rounded cone with any sort of uniform warped hexagon. If you try it, you'll find that it works alright at the beginning, but as the surface continues curving, your hexagons will become more and more distorted until you're forced to add pentagons to the mix. This is a direct consequence of the Euler Identity.There's just no way to avoid requiring a large number of different tile shapes when trying to tile a surface with non-zero curvature. (A cylinder has, mathematically speaking, zero curvature, just to be clear on this. Not so for a rounded cone)Mathematically you're correct.But engineers like to cheat 1 type of tile in 2 forms, whole and cut in half.PS: I'd like to emphasize that only 200deg of SS needs to be tiled.Long straight lines like that are problematic.In the words of Elon when asked why hexagons:QuoteNo straight path for hot gas to accelerate through the gapshttps://twitter.com/elonmusk/status/1107379727302451200All of the verticals are the same size as the standard hex tile and the other lines are shorter.
Then the tiles were glued to thin nylon fabric layers (AIU like the stuff womens tights are made out of) to handle the contraction and expansion.
BTWA few years ago DLR ran a sounding rocket test with the Brazilian space agency.They built a nose cone out of standard sized RCC tiles, mostly triangles, pentagons etc. The key development was the software to confirm despite the segments being flat that the aerodynamics were OK and the flow was smooth enough to avoid turbulent flow (which multiplies heat transfer between 4x and about 6x).
