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IMPORTANT: enter the case-INsensitive alphabetic (no numbers) code AND WRITE SOME SHORT summary of changes (below) if you are saving changes. (not required for previewing changes). Wiki-spamming is not tolerated, will be removed, so it does NOT even show up in history. Spammers go away now. Visit Preferences to set your user name Summary of change: '''Charge-air cooler is the thing people usually think about when saying intercooler.''' Engines with compressors (such as TurboChargers) benefit from cooling the charge air after the compressor has compressed the air (unwanted heat is also produced). The benefit is less tendency to knock, better efficiency, finally higher output from the same displacement. There are 2 types of intercoolers: * '''air to air''' intercooler * '''air to water''' intercooler (which needs another radiator to finally release the heat of the water to the environment) Both are possible to buy or make in the garage. ---- I thought of making a long tube-like water-air intercooler: from a lot of small diameter Al tubes (air inside, water outside), with 4..5 mm internal diameter. Putting them close to each other. Very close at the 2 ends (epoxy could seal?) and a little further from each other along the tube so water can flow between the tubes (water needs smaller cross-section than air). The tube-collection can be embodied in carbon fibre to hold the water back. Maybe the first layer must be fiberglass poliesther to prevent Al + carbon corrosion (I read about that a recumbent builder's page), maybe the whole encapsulation can be done with fiber strenghtened poliesther (cheaper than kevlar). *water can flow opposite direction to air: H2O coolest where air exits *it can be built to follow curves (the small diameter tubes can be bent easily). *in fact very strange shapes can be realized that follow the available space well The hard part is probably the sealing at the ends of the tube. Air-drag due to tubewall thickness of is also an issue, but you can make a small-angle cone driller for this purpose. If you have some numbers for the drag inside a tube, please post it (or link) here. We can put together a sizing-helper program (eg. in perl). I calculated the heat-transfer, but not the air-pressure drop. I haven't done it, just thought about. Marcell It was reported that sg. like that is available on some import (usually means Japanese and Korean I think) turbo engines. ---- '''Intercooler Links''' * http://www.turbomustangs.com/intercoolers.htm * http://home.earthlink.net/~turbogus2/intercoolers.html * http://www.turboneticsinc.com/intercoolers.html * http://212.214.179.144/~berglund/04-10-30/index.htm Intercooler Calculations: http://www.gnttype.org/techarea/turbo/intercooler.html ---- '''See also''' * FluidModeling - especially if you design your own * WaterInjection * [http://autospeed.com/cms/A_0527/article.html?popularArticle nice intro to coolers] Optional: Add document to category: Wiki formatting: * is Bullet list ** Bullet list subentry ... '''Bold''', ---- is horizontal ruler, <code> preformatted text... </code> See wiki editing HELP for tables and other formatting tips and tricks.