Reflections on watercooling: Difference between revisions
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I've been watercooling my primary personal machine since [[Schwarzgerät_II|2020]]. It started off simple—a waterblock on my Threadripper 3970X, an EKWB reservoir+pump combo, and a Hardware Labs GTR360 radiator. A total of about $480 (not including fans), less than my motherboard cost. It is no longer so simple: the same machine in its [[Schwarzgerät_III_upgrade|current incarnation]] boasts a monoblock, a GPU block, a custom GPU backplane, four radiators, two reservoirs, four D5 pumps, two temperature sensors, two discrete inline sensors, and about twenty attachments of all kinds. There's <i>at least</i> $1000 worth of watercooling crap in there, and another $500 of fans. I guess you could say things are getting serious. | '''[[Dankblog|dankblog!]] 2022-04-17, 0836 EDT, at [[Viewpoint|the danktower]]''' | ||
I've been watercooling my primary personal machine since [[Schwarzgerät_II|2020]]. It started off simple—a waterblock on my Threadripper 3970X, an EKWB reservoir+pump combo, and a Hardware Labs GTR360 radiator. A total of about $480 (not including fans), less than my motherboard cost. It is no longer so simple: the same machine in its [[Schwarzgerät_III_upgrade|current incarnation]] boasts a monoblock, a GPU block, a custom GPU backplane, four radiators, two reservoirs, four D5 pumps, two temperature sensors, two discrete inline sensors, and about twenty attachments of all kinds (note that this is an almost laughably overpowered setup). There's <i>at least</i> $1000 worth of watercooling crap in there, and another $500 of fans. I guess you could say things are getting serious. | |||
I've put together some thoughts having watercooled for over two years. | I've put together some thoughts having watercooled for over two years. | ||
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* <b>It's less risky than you think.</b> I rejected watercooling for many years because the entire premise seemed ludicrous: one might as well fill one's box with powerful magnets, or fragmentation grenades, or alligator snapping turtles. Water doesn't belong in machines. It's why we have them in a case rather than just sitting around in the front yard. So first off, your watercooling components needn't come anywhere near your storage, which is where the irreplaceable stuff lives. My M.2 drives are all sealed away, and my spinning disks are located far away from any water. Any leak is almost certainly going to be your fault, and will be detectable before turning on any other components: this is the <i>leak test</i>. Hook up your power supply and watercooling components, but <i>leave everything else unpowered</i>. Fill and run your loop, ideally for several hours at maximum levels. Put paper towels underneath all loop components. If the paper towels are dry, go ahead and turn everything else on, hurrah. If they're wet, you have a problem. <b>Getting water on components <i>while they're powered down</i> is no big deal.</b> | * <b>It's less risky than you think.</b> I rejected watercooling for many years because the entire premise seemed ludicrous: one might as well fill one's box with powerful magnets, or fragmentation grenades, or alligator snapping turtles. Water doesn't belong in machines. It's why we have them in a case rather than just sitting around in the front yard. So first off, your watercooling components needn't come anywhere near your storage, which is where the irreplaceable stuff lives. My M.2 drives are all sealed away, and my spinning disks are located far away from any water. Any leak is almost certainly going to be your fault, and will be detectable before turning on any other components: this is the <i>leak test</i>. Hook up your power supply and watercooling components, but <i>leave everything else unpowered</i>. Fill and run your loop, ideally for several hours at maximum levels. Put paper towels underneath all loop components. If the paper towels are dry, go ahead and turn everything else on, hurrah. If they're wet, you have a problem. <b>Getting water on components <i>while they're powered down</i> is no big deal.</b> | ||
* Avoid particulate coolants. They gunkify components over time, making them look like shit and reducing flow. Distilled water ought be treated with biocides and anticorrosive agents (easily available as coolant concentrates), which will be included in any premixed cooler. | * Avoid particulate coolants. They gunkify components over time, making them look like shit and reducing flow. Distilled water ought be treated with biocides and anticorrosive agents (easily available as coolant concentrates), which will be included in any premixed cooler. | ||
* Order of components doesn't matter <i>assuming sufficient flow</i>. If your flow rate is very low, you can get significant localized heating, at which point heat-generating components without intermediary heat-expelling components can be suboptimal. With sufficient flow rate, your loop will reach effective equilibrium. This question comes up because if you're watercooling both a CPU and GPU (or multiple GPUs) | * Order of components doesn't matter <i>assuming sufficient flow</i>. If your flow rate is very low, you can get significant localized heating, at which point heat-generating components without intermediary heat-expelling components can be suboptimal. With sufficient flow rate, your loop will reach effective equilibrium. This question comes up because if you're watercooling both a CPU and GPU (or multiple GPUs): they're generally close together, and it's unwieldy to separate them with a radiator. It's certainly not worth running distinct loops (which would require multiple pumps, which ought be able to achieve the necessary flow rate when placed in series). | ||
* Increasing flow rate is pretty much only useful up to rough temperature equilibrium. Running your pumps higher will add more heat to the loop (assuming they're immersed, as they usually are), and reduce their lifespan. | * Increasing flow rate is pretty much only useful up to rough temperature equilibrium. Running your pumps higher will add more heat to the loop (assuming they're immersed, as they usually are), and reduce their lifespan. | ||
* Tubing kinks reduce flow, as does transport (especially vertically), as do attachments (especially angled ones), as do radiators and waterblocks. | * Tubing kinks reduce flow, as does transport (especially vertically), as do attachments (especially angled ones), as do radiators and waterblocks. | ||
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* SSDs are meant to run hotter than hard drives. You don't need to watercool them, nor RAM. Please don't try to watercool your hard drives. | * SSDs are meant to run hotter than hard drives. You don't need to watercool them, nor RAM. Please don't try to watercool your hard drives. | ||
Every pump I'm aware of runs off 12V, with a maximum draw no greater than 30W. You can thus power them with any combination of Molex, SATA, or even PCIe cables, so long as you match the final form factor. I use PCIe cables with Molex converters; [https://www.performance-pcs.com/cables/power-supply-adapter-cables/pci-express-to-molex-adapter-cable-sleeved-pcie2molex-c.html PerformancePCs] sell a nice sleeved one. Almost all pumps are either D5 or DDC; the former is quieter and more powerful, but slightly larger. I roll exclusively with | Every pump I'm aware of runs off 12V, with a maximum draw no greater than 30W. You can thus power them with any combination of Molex, SATA, or even PCIe cables, so long as you match the final form factor. I use PCIe cables with Molex converters; [https://www.performance-pcs.com/cables/power-supply-adapter-cables/pci-express-to-molex-adapter-cable-sleeved-pcie2molex-c.html PerformancePCs] sell a nice sleeved one. Almost all pumps are either D5 or DDC; the former is quieter and more powerful, but slightly larger. I roll exclusively with Laing D5s. PWM models can be controlled on the fly, while "Vario" models have a physical potentiometer which almost always ends up being a bitch and a half to get to. I recommend going with PWM. Varios will typically have a 3-pin hookup reporting tach, while PWM will have a 4-pin hookup. | ||
As for soft vs hard tubing, I use soft tubing, and don't intend to ever do otherwise. Soft tubing is trivial to cut, cheap, has plenty of give, bends without a heating gun, doesn't shatter, and is already quite enough of a pain in the ass. Old types of soft tubing were prone to plasticizer leeching, but newer types don't have them. I recommend [https://www.ekwb.com/shop/ek-tube-zmt-matte-black-19-4-12-5mm EKWB ZMT] (zero-maintenance tubing), so long as you don't mind it being opaque. Cheap anti-kinking coil can wrap your soft tubing to give it more resistance, and also provide some color. (Some) hard tubing can survive higher temperatures than soft tubing, but such high temperatures are bad for your other components, especially pumps, and ought be avoided. | As for soft vs hard tubing, I use soft tubing, and don't intend to ever do otherwise. Soft tubing is trivial to cut, cheap, has plenty of give, bends without a heating gun, doesn't shatter, and is already quite enough of a pain in the ass. Old types of soft tubing were prone to plasticizer leeching, but newer types don't have them. I recommend [https://www.ekwb.com/shop/ek-tube-zmt-matte-black-19-4-12-5mm EKWB ZMT] (zero-maintenance tubing), so long as you don't mind it being opaque. Cheap anti-kinking coil can wrap your soft tubing to give it more resistance, and also provide some color. (Some) hard tubing can survive higher temperatures than soft tubing, but such high temperatures are bad for your other components, especially pumps, and ought be avoided. | ||