![[H]ardOCP](/images/blank.gif){kind=small}
- Date:
- Wednesday, December 17, 2014
- Author:
- Marc Adams
- Editor:
- Kyle Bennett
- Share:
Corsair Hydro H80i Liquid AIO CPU Cooler Update Review
As we continue to move up the Corsair All-In-One CPU cooler matrix, today we get to the mid-range Hydro Series™ H80i High Performance Liquid CPU Cooler. This is another cooler that has been on the market for quite a while and we give it another look and see how it compares against today's market in term of cooling and value.
Introduction
Today we take our look back machine to February 2013 and see if the H80i from Corsair held up against the test of time.
The Corsair Hydro Series™ H80i High Performance Liquid CPU Cooler, introduced in early 2013, came with a host of new features that updated the H80 model, such as Corsair’s new cold plate design, smooth no-kink tubing designed to reduce evaporation, and includes new fans with increased static pressure and low noise.
System Setup
Today's review takes place on our fourth generation [H]ard platform. The test bed consists of the ASUS Z87-Deluxe motherboard, eight gigabytes of Corsair 1600 MHz DDR3 RAM and the Intel Core i7 4770K.
Test Methods
CPU
The biggest change you will notice is the removal of hardware testing. In recent years, Intel has shifted their methods of testing to software based and so we find it acceptable to do the same.
GPU
Once again we have an integrated GPU in our processor which alleviates the need for a discrete one. With the removal of a discrete GPU comes the advantage of not having an additional variable to account for.
The iGPU will not create any anomalies in our testing as long as we practice consistent testing methods.
Case
Corsair was kind enough to provide us with their Carbide series chassis. It provides excellent airflow and interior space and is a good reflection on current case design.
Thermal Paste
Noctua's NT-H1 thermal paste was selected as the paste of choice for a few key reasons. The thermal paste has been shown to provide excellent thermal conductivity allowing the heat sinks to better do their job. There is no observed curing time. That is, performance does not get any better over time. Any curing time could have introduced variables into the equation causing at best dubious results and at worst unreliable ones.
Temperatures
Ambient temperature will be kept at 25C for the duration of the tests and measured with a MicroTemp EXP non-contact infrared thermometer and cross referenced with the Sperry Digital 4 Point thermometer. Any variance greater then 0.2C will halt the testing until temperatures return within spec for fifteen minutes.
Idle
Idle temperatures will be recorded after a twenty minute period of inactivity. Any fluctuation during the last sixty seconds will reset the timer for an additional five minutes.
Load
Load temperatures will be recorded after a twenty minute period for air cooled systems, and thirty minutes for liquid cooled systems, at 100% load. To obtain this load we will be using AIDA64 Extreme Edition v3.00.2500. This places an even greater load on the CPU than before and includes some benefits. Because the load is so extreme we see the temperature vary wildly from 72C to 86C in some instances. To get an accurate reading we will utilize AIDA64’s ability to average the temperature over time. Given twenty/thirty minutes at 100% load we arrive at a temperature that accurately represents our heatsink’s performance.
Sound
Sound levels will be measured with a Reliability Direct AR824 sound meter from a distance of four feet away. With everything turned off and the room completely silent the meter registered a sound level of 38dB(A). This is a very quiet room where a simple pin drop could be heard. All sound measurements are recorded in the very late evening to further reduce any ambient noise.