Re: sebk and one particle at a time.Yeah, was trying to keep it simple and add complexities one at a time. The early example of a single partial impact is what happens before a bow shock forms. All heating is applied directly to the skin.I was thinking about the various species. They're there, they're important but ISTM, irrelevant in assessing the flow impact of a missing tile. Thermal and chemical, but not flow.Something I'm chewing on is charges. That first partial, it's gonna hit hard. Not only will it break apart into constituent atoms, it will also most probably shed an electron or two. In the grand scheme of things charge will be conserved but are there local effects? If there are, this might affect flow.
These results will of course be mostly boring "nothing happens" if it is a good TPS material.
I have been thinking about the way the TPS tiles are made and how they are attached to the hull.If I understand the way the tiles are made, they are baked (sintered) with a Y shaped frame on the back that has 3 holes for the studs that are welded to the hull by robots.So I asked myself why do it in 2 steps? Why not sinter the tile with a frame that already has 3 studs fixed to the frame, no holes needed, then have the robots weld the tile with studs to the hull?To do that the studs on the tile need to be electrically wired to make the welding possible. Then as much of that wiring as possible could be pulled away (or left in place). I was thinking the frame would include the wires.I have seen how studs are welded, but I don't know if that can be done while a stud is behind a tile.If a tile is cracked it will have to be removed as they do now, but the studs have to also be cut off to make place for a new tile. Just a thought that maybe others can improve...or debunk.
So I asked myself why do it in 2 steps? Why not sinter the tile with a frame that already has 3 studs fixed to the frame, no holes needed, then have the robots weld the tile with studs to the hull?
Quote from: RamsesBic on 10/22/2022 09:14 amSo I asked myself why do it in 2 steps? Why not sinter the tile with a frame that already has 3 studs fixed to the frame, no holes needed, then have the robots weld the tile with studs to the hull?AIUI these tiles are designed to be removed from those mouting studs if they need to be replaced. What you're suggesting would likely weld the tile to the stud, as well as the stud to the hull. Coming up with a design that only welds the stud to the hull and leaves the actual attachment mechanism undamaged is likely to prove more trouble than any benefits to replacing the current system. Stud welding in industry is highly automated. Each one taking a few seconds and often done at more than one at a time.
Quote from: john smith 19 on 10/22/2022 05:36 pmQuote from: RamsesBic on 10/22/2022 09:14 amSo I asked myself why do it in 2 steps? Why not sinter the tile with a frame that already has 3 studs fixed to the frame, no holes needed, then have the robots weld the tile with studs to the hull?AIUI these tiles are designed to be removed from those mouting studs if they need to be replaced. What you're suggesting would likely weld the tile to the stud, as well as the stud to the hull. Coming up with a design that only welds the stud to the hull and leaves the actual attachment mechanism undamaged is likely to prove more trouble than any benefits to replacing the current system. Stud welding in industry is highly automated. Each one taking a few seconds and often done at more than one at a time.The studs would not be welded to the tile, but be part of the frame just as the holes are now.When it comes to removing tiles I have noted they drill holes, then use those to break the tile in pieces then they remove the frame that was holding the tile last. With the tiles I am thinking of it would only add one step - grind off 3 studs. The system I am envisioning would also be automated but instead of just welding studs the robot arm would place the tile, with its 3 built in studs, in its exact position then run the current through the frame on the back which would weld the tips of the studs to the hull, then pick up the next tile and repeat.What I am not sure about is if to weld any stud there is a minimum thickness of the electrical wire used for the welding? Would it be possible to use the metal of the frame itself as a section of such a wire?This system would also make it easier to leave all tiling until the ship is fully stacked. Then the robot would run all over the ship in one go. It can be mounted on a frame that can move it vertically and horizontally. Rotating the ship would also help.The point of doing the tiling last is there will be no need to glue tiles at the junctions between sections the way they must at present. That would leave gluing to the tip of the nose cone and parts of the flaps. Maybe also the perimeter of the tiling surface. (Tiles are glued between sections because there is no way the studs on one side will perfectly aligned with studs on an adjacent section.)But it all depends on the welding of the studs when installing the tile. If that for some reason can't be done then my idea is dead in the water. The wire needed for the welding has to be narrow enough to fit between any two tiles without causing damage. An alternative is to have 3 holes on the surface of each tile that connects the wires needed to the built in studs. When they have been welded the wire would be removed as the robot arm moves off the tile. Those holes would not be much more than the gaps between tiles - maybe less. They could even be at a slight angle to reduce exposure on reentry. Robots are good at doing that kind of exact movements and accurate placement.If SpaceX wants to produce a ship every 3 days doing tiles by hand the way they are installed today will be very hard in the long run.
Have you ever looked at a welder? Even the smallest home hobby unit has cables as thick as a finger.Have you ever used a surface grinder? What you call "only one step" would be no more than an irritation on earth but on orbit or transit to mars this would be a major operation and a space suit devouring risk. Admittedly, a safer specialized grinder could be designed and a robot could do the work but there's no reason to think that SX needs to pivot to another design - yet. Yes, the tiles and bayonet clips have been a problem. If you've been following this since the first test tiles were installed you'll know that shedding tiles is not as bad as it once was. They need to keep working the problem and refine the design. If they can't make it work they'll look in other directions.
Quote from: OTV Booster on 10/23/2022 02:54 amHave you ever looked at a welder? Even the smallest home hobby unit has cables as thick as a finger.Have you ever used a surface grinder? What you call "only one step" would be no more than an irritation on earth but on orbit or transit to mars this would be a major operation and a space suit devouring risk. Admittedly, a safer specialized grinder could be designed and a robot could do the work but there's no reason to think that SX needs to pivot to another design - yet. Yes, the tiles and bayonet clips have been a problem. If you've been following this since the first test tiles were installed you'll know that shedding tiles is not as bad as it once was. They need to keep working the problem and refine the design. If they can't make it work they'll look in other directions.I know that those welding wires are thick (I have done some DIY welding), that is why I am asking those who might know more than me. But don't forget that the gaps between tiles are a few mm (I can only compare the size of the gaps on photos to those of a tile). My alternative is to use holes in the tiles that connect directly to the studs. Their small size would be of the same order as the gaps and could easily be tested in a lab to show if they would add to the risks.You mention replacing tiles in space. I would counter that with the cases when workers have had to use crowbars and chisels to remove tiles. Doing that in space will be a challenge to say the least.I know that the installation of tiles has improved a great deal and am pretty sure they will do fine. But what I was looking at was how to automate and simplify the process (and reduce the number of tiles cracked during installation). SpaceX's tile experts could I am sure find better modifications. This idea I had was just one way. One I think could be used and improved on - that's all. (To SpaceX: if you use it or a variant of it give a donation to some charity)It might sound like a complicated method, but really is not, and the benefits of removing the need to glue half the glued tiles is not negligible either.BTW, if the robots used today welded the studs after stacking the ship they would avoid glueing all those tiles at the section junctions. Anyone who has watched the tiling knows using glue takes at least 10 times longer and is pure hell to remove. (I would hate to see an astronaut try using solvents in space to remove the glue behind a tile)
They really need at least one launch and EDL attempt before they can have a clue on refinement or pivot to something different. Once they have a better idea of where they're going they'll refine the mounting process.
Your idea on welding cable holes in the tiles kicked off a thought. There has been talk of small holes to allow injection of hydrophobic chemicals. There are latches that are very robust that release easily when pressed by a thin stiff wire. This might be two birds with one stone.
Don't worry, I am not fixating on my idea. Just wanted to throw it out there and see if others could make something of it. I just need convincing.I admit that using the Y frame to assist in leading the current was not that great. The other one with the three holes is better. BTW, the holes would get almost closed during reentry due to tile expansion - they would also release some of the tension. Can't the welds be tested by measuring conductivity and resistance once the pin is welded? How is it done at present? Is someone checking using X-ray every single stud? (I have never seen it done)As to making the tile with the pins fixed when it leaves the oven, what would be different compared to the tile leaving it with the 3 holes (in the Y frame)? I am assuming the holes are made of some metal, just as the studs would. The thermal blankets are needed to reduce vibrations, but they could also be to act as last resort if a tile is lost, I guess. They could be cut to the right size and made part of a tile's back side. Maybe slightly wider to avoid gaps. That would btw replace the need to add those blankets by hand, and having to push them over the studs, which in turn risks bending a stud here or there.I will stop here. I think I have stated all the points I wanted to make.
Still not sure what this stuff is, but it held back two minutes of butane fury without getting warm on the far side. The metalic film didn't last long, but the stuffing seemed kind of ablative.
Quote from: RamsesBic on 10/23/2022 08:48 pm Don't worry, I am not fixating on my idea. Just wanted to throw it out there and see if others could make something of it. I just need convincing.I admit that using the Y frame to assist in leading the current was not that great. The other one with the three holes is better. BTW, the holes would get almost closed during reentry due to tile expansion - they would also release some of the tension. Can't the welds be tested by measuring conductivity and resistance once the pin is welded? How is it done at present? Is someone checking using X-ray every single stud? (I have never seen it done)As to making the tile with the pins fixed when it leaves the oven, what would be different compared to the tile leaving it with the 3 holes (in the Y frame)? I am assuming the holes are made of some metal, just as the studs would. The thermal blankets are needed to reduce vibrations, but they could also be to act as last resort if a tile is lost, I guess. They could be cut to the right size and made part of a tile's back side. Maybe slightly wider to avoid gaps. That would btw replace the need to add those blankets by hand, and having to push them over the studs, which in turn risks bending a stud here or there.I will stop here. I think I have stated all the points I wanted to make.A misconception. The holes will not close on heating. They will enlarge. This is any material. The mean space between molecules becomes greater over the entire object. All dimensions increase.The current Y bracket, or at least the last one I remember seeing, has three slots for the clips, not holes. The tile can expand over the clips without binding and cracking. If not the Y bracket, some other mechanism is needed to allow for the expansion differences of tile and hull. Three clips without this would lead to failure, most probably of all the tiles. I was also wondering about how they test clip welds. It may be that they did extensive testing to find the exact setting needed for a good weld and measure current draw during the weld process to point out anomalies. I'm old school enough that I always want to see my work product. Even dogs and cats do it. This, and every other test I can think of other than imaging of some sort becomes murky through two interfaces (pin to hull and pin to Y bracket). The thermal blanket is a, well, thermal blanket. It is a backup. TBH, I don't know if there is anything solid on this or if it's NSF lore. AIUI, it also reduces scuffing from vibration as you point out, and it is (speculated? known?) that it puts a bit of springiness behind the tile to keep the pins mechanically loaded, which sorta overlaps on the vibration thing. Think through the idea of a patchwork thermal blanket a bit larger than a tile. Lay down tile number 1. Assume the intended gap is 5mm. Assume the extra fringe of blanket is 10mm. Lay down tile number 2. Hmm. It overlaps the fringe of tile 1 but it's fringe can only lap on top of tile 1. Ah ha! We can modify the blanket to stay flush on three faces and extend out 10mm on three faces. We now have a tile that can only go on with only one specific orientation. Bummer. It just got more complicated.Next, picture loosing one tile. Hmmm. The blanket is pinched under three tiles and being held in place but is flapping in the breeze around half its circumference. And why exactly is this a good thing?To my knowledge, however imperfect, I know if no time a stud was bent while pushing the blanket over them. It looks to be roughly the texture of a dense fiberglass insulation batt.Really, honest to mergatroid, cross my heart and pinky promise, welding the pins as you suggest would make it harder, more expensive, and more prone to breakage. Did I mention it wouldn't work?Are you sure you aren't in love with this idea? I know a good counselor...In a more serious vein, you're new here. I strongly suggest starting at the beginning of this thread and at least skimming through to see what the discussion has covered. It's a lot to digest but if you're here because you're curious about the topic, you will come away from your reading with a reasonable education on the general issues and the specifics of what SX has has done to address these issues. And you would be doing the rest of us a curtesy by not hammering on something that has already been hammered to death. You haven't done that last. You've hit on something new. Bravo!
At the back end of the X33 programme the metal tiles were being mounted by (IIRC) 4 screws, 1 at each corner, with a superalloy cap backed by high temperature insulation. However at the very end of one of the reports there were notes about a better proposal. An adaptation of some kind of commercial tool. Very thin head that could slide between the tiles and squeeze some kind of spring that would allow the tile to come off very easily while being very light as well. Unfortunately that's all I can remember about it. . IIRC the actual TPS contractor was Rohr, who are (or were) quite big in building parts of ships.
The most innovative and effective modification, however, is the use of quick release fasteners. The fastener uses a simple wire clip that snaps into a groove of a stud attached to the structure. The fastener is released by sliding a special “scissors-like” tool into the gap between panels and squeezing the ends of the wire together. A thin slot or notch in the gap cover allows the tool to be inserted into the gap. When the panels heat up and expand the gaps begin to close and the slots slide over the adjacent panels. This fastener concept has no loose parts, is quick and simple to operate, and eliminates the costly and troublesome fastener access tubes and covers.