Page 2 - Physical Look - Hardware; Installation
I really enjoy reviewing small coolers because of how dense they usually are. The NH-L9i-17xx is much like other L-series, with a single stack of horizontal fins and some heatpipes going through it. As this cooler shares the same "L9" name as the NH-L9i for other Intel sockets, it is not surprising the NH-L9i-17xx looks similar in size and build. As such, we have two heatpipes that come out of the bottom base and down the sides of the fins. It is also available in chromax.black, which has a full matte black finish on the heatsink and fan instead of our current unit with traditional Noctua colors. The heatsink is made out of aluminum and nickel plated around the entire unit. Noctua's owl logo can be found on each side of the heatsink and is generally hidden once it is installed.
The fan attached to the Noctua NH-L9i-17xx is a 92mm NF-A9x14 HS-PWM, attached to the heatsink with four screws. The fan itself has rubber pads in each corner, which should reduce any noise and vibrations. As we have mentioned, the fan is 14mm thick. It rotates at speeds of up to 2500RPM, with an airflow rating of 57.5 m³/h, static pressure of 2.11 mmH2O, and noise level of 23.6 dbA. Noctua also mentioned we have a SSO2 bearing inside, which is a hydrodynamic bearing for quieter operation and longer life. This results in a mean time to failure of over 150,000 hours, or just over 17 years if operated continuously.
In terms of weight, the whole Noctua NH-L9i-17xx weighs 355g without a fan and 430g with the fan installed. This is quite a bit lighter than the NH-L9i, which is 430g when fully installed. This is a very compact cooler, and the weight makes it feel dense. For some perspective, a typical Intel stock cooler weighs around 330g, while an AMD Wraith Prism stock cooler weighs 582g. Most of the weight can be attributed to the material choices of the heatsink itself, as you will find out later.
From the side, you can see all of the fins are stacked in a rectangular shape. There are several indents and teeth on both sides of the metal fin edges. This optimizes the ability to permit airflow in between the fins while reducing the resistance and noise, all while only negligibly decreasing the heatsink surface area. There is a total of 54 fins on the radiator. The spacing in between each fin is approximately 1.5mm. From my calculation, the total surface area of the cooling fins combined is close to 0.19 square meters. Comparatively speaking, the company's flagship Noctua NH-D15 has a slightly higher 1.2 square meters of surface area.
In terms of dimensions, you can see the heatsink is about 23mm in height, 95mm in width, and 95mm in depth, which is identical to the standard NH-L9i. With the fan attached, the height increases to 37mm, which is much lower than other coolers we have taken a look at in the past. This CPU cooler is small enough so there is no part hanging over into other areas on the motherboard like the RAM slots or VRMs. As such, Noctua mentions this cooler has full compatibility without any interference with memory. Once again, these dimensions suggest to users that this cooler is meant to be used in tighter areas and applications like a home theater PC.
Out of the base of the Noctua NH-L9i-17xx are two heatpipes, splitting to each side. The bend out and go back through the array of fins on each side. While it is not exactly a symmetrical design, you should be able to mount the NH-L9i-17xx in either of the two orientations without worrying of affecting cooling performance. The heatpipes are around 6mm in diameter, and like the base, is a copper core with a nickel plating on the outside. Heatpipes are supposed to efficiently lead the heat away from its source due to the low heat of vaporization, or phase change energy, of alcohol. The heatpipes are aligned in a manner to spread out the heat in the single array of radiating fins. These pipes along with the fins and the fan attached should be able to dissipate heat quite well, but we will see if this is true in our performance tests.
From the photo above, you can see the bottom of the Noctua NH-L9i-17xx CPU heatsink. Unsurprisingly, the base is very flat, which means it should rest evenly on the processor. After a quick inspection, I was not able to see any abnormalities, although you can see the circular milling marks. As such, it is important that you use some sort of thermal grease between the base and your processor to fill in these smaller gaps. This heatsink is composed of copper, nickel, and aluminum as we have seen from past Noctua heatsinks. The base and heatpipes are built using copper for best heat transfer ability with a thermal conductivity of 401 W/mK. The heatsink fins utilize aluminum as it is quite a bit lighter in comparison to copper. This compromise allows the NH-L9i-17xx to reduce its weight and thus reducing the stress on the motherboard. Aluminum has a thermal conductivity of 237 W/mK, which is not as optimal for heat transfer, but the trade-off is understandable.
Visually speaking, the Noctua NH-L9i-17xx conceals the copper color on the heatpipes and base. The electroplating of the base with nickel on top of copper has a thermal conductivity of only 90.9 W/mK. While nickel has a lower thermal conductivity than copper, the electroplated layer is very thin and should not directly affect performance to a significant degree. Instead, this is done this way to keep the base from corrosion. Nickel and nickel-base alloys generally have desirable properties that can withstand corrosive environments and high temperatures, which are especially beneficial for a heat dissipation device. The reason why nickel has such a property is because of nickel's ductility and toughness all the way up to the melting point of 1455c, measured at non-standard pressure. Nickel's face-centered cube crystal structure is virtually unaltered all the way up to that temperature. Nickel, like titanium, is highly resistant to corrosion so corroded material will not build up on the surface in the long run. As a result, the Noctua NH-L9i-17xx will be less prone to losing its cooling performance over time as juxtaposed to a corroded copper surface.
Additionally, all the joints are cleanly soldered at the base while the heatpipes are soldered to the fins. Pressed fins are typical for most heatsinks, but may degrade over time as contact between metals decreases due to thermal expansion and contraption. Overall, the Noctua NH-L9i-17xx appears to be built very solidly. Reliability should also be excellent and Noctua offers a 6-year warranty should anything go wrong.
As you have read in our other Noctua reviews, installation is pretty straightforward. However, this compact cooler uses a different system compared to the traditional mounting setup, despite having the same SecuFirm2 name. As I have mentioned, this is meant for the Intel LGA 1700 socket, but we do not even have a backplate here. Instead, users can place the cooler in the correct orientation and use screws with the mounting holes to fix it in place.
For installation, I would first start by applying thermal paste on the processor prior to mounting the NH-L9i-17xx. For Intel CPUs, Noctua advises to put a small dot measuring in 3 to 4mm in diameter in the middle plus a square pattern of four smaller dots 2mm in diameter surrounding the middle one. Once the cooler is in place on the motherboard side, flip over the motherboard to start screwing in the included screws from the backside. The screws are silver in color, but also have plastic spacers. With your screwdriver, I would make sure you tighten the screws in an alternating cross pattern to ensure each corner is firmly attached to the motherboard. Finally, I would plug the fan into the motherboard. Overall, installation was quite clear, but I would not necessarily say it was easy, especially since you have to access both sides of the motherboard at the same time. As I have noted before, the NH-L9i-17xx does not interfere with my RAM, as the cooler has a very small footprint. With the physical inspection, we can see Noctua is consistent in both its build quality and aesthetics as it has been with past products.
Page Index
1. Introduction, Packaging, Specifications
2. Physical Look - Hardware; Installation
3. Test Results
4. Conclusion
