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While we were unable to find a MSRP for retail available units, you can currently find a basic LCLC system with a single-fan heat exchanger and support for a single CPU for only $70. For the first time, it is possible to purchase a performance water cooling system for the same price as a high-end air cooling setup.
#Asetek 550lc 120mm liquid cooling cpu cooler making noise install
Given the numerous disadvantages such as higher cost, more involved installation process and increased maintenance, it simply isn't worth the effort for some users to bother with a water cooling setup unless they planned to install it in an especially hot system.Īlthough Asetek isn't the first company to try to bring water cooling into the mainstream and to OEMs by challenging its traditional disadvantages, they are the first company to successfully attack water cooling's primary problem high cost. While water cooling's remaining advantages of better thermal efficiency and flexibility is enough to drive interest and sales for performance enthusiasts, these reasons alone aren't enough for mainstream consumers and OEMs to consider water cooling as an option. This means the performance of an air cooling system would suffer in a smaller mATX enclosures while water cooling would soldier on, oblivious to the size of the case.Īlthough top-end air coolers can now perform nearly as well as a quality water cooling setup, water cooling still remains more thermally efficient. Water cooling systems are generally oblivious to both of these issues since thermal capacity is linked directly to the volume of water in the system, and not the air. Air coolers are also sensitive to the size of the enclosure since cooling capacity is directly linked to the volume of air within the case and the flow rate of air through the case. Air coolers depends heavily on existing airflow within the case and a poorly cooled case can cripple even the best of air coolers. While the performance gap between high-end air coolers and water cooling has closed somewhat, water cooling remains significantly more flexible and scalable. If the two primary advantages watercooling had over air cooling solutions are seemingly a thing of the past, why would anyone still get water cooling? The current crop of top-end super air coolers compete very well with many watercooling systems in terms of both performance and noise, although not necessarily at the same time and not with the same air cooling product. With the introduction of fluid-filled heat-pipe technology to computer heatsinks, both of these reasons for getting watercooling have been eroded by newer, more efficient heatsink designs. Another popular reason to get watercooling, especially in earlier times when air coolers used loud 80mm high-RPM fans, was to build a quiet system that still maintained decent cooling performance. In the recent past, watercooling had long been considered an enthusiast solution, superior to air cooling, for obtaining optimal cooling performance. All with a very quiet 800 RPM fan that was barely audible. It easily outperformed all stock cooling solutions and kept pace with a high-end, heat-pipe equipped air cooler with an extremely powerful (and loud) fan. Overall, we are very pleased with the LCLC's performance. If the LCLC was equipped with a thermally controlled fan connected to the motherboard, which could increase its speed when the system is loaded, the LCLC would have performed better. However, this was largely because the stock cooler is thermally controlled by the graphics card and the fan significantly increases in speed while the graphics card was under load, therefore increasing in noise level as well as cooling capability. While under load, the LCLC performed on-par with the stock cooler. In the case of both the GPU and graphics memory, the LCLC was able to significantly outperform the stock cooler while the graphics card was idle. Graphics cooling performance was also good. Also note, that had we used a more powerful fan, the LCLC's performance would have been even better. This is an extremely impressive result that shows how efficient water cooling is. With an 800 RPM Scythe S-FLEX installed on the heat exchanger, it was able to keep pace with the Silverstone NT-06 using a 2640 RPM screamer. The LCLC outperformed the Intel stock cooler by a significant margin both while the CPU was idle and during the Everest stress test. Performance Summary: The LCLC performed very well in all of our thermal tests.