Conclusion

The Reserator 3 Max Dual is Zalman's trump card in the field of all-in-one liquid coolers and currently the most advanced such cooler that they offer. After they discontinued the Reserator 1 V2, it also is their most expensive liquid cooler, currently retailing for $140 incl. shipping at the time of this review. With the exception of the Enermax kits, which are unavailable in the US and importing them raises their cost dramatically, this makes the Reserator 3 Max Dual the most expensive all-in-one liquid cooler that we have tested to this date, regardless of size and features.

Zalman's Reserator 3 Max Dual certainly has a very long list of positive aspects. To begin with, it sports an impressive appearance that will easily stand out, without being extravagant or overly aggressive. It is very well made, using high quality materials and is free of imperfections. The PWM controlled fans are very handy to have, as their speed can be controlled by the motherboard, essentially emulating a typical CPU cooler and eliminating the need for external speed controllers and unnecessary cable clutter. If quality and appearance are what drives you, the Reserator 3 Max Dual will not be a disappointment.

On the other hand, the Reserator 3 Max Dual is far from flawless. The fancy-looking radiator is bulky and may easily create compatibility problems. Even with the supplied offset installation brackets, the case needs to be wide enough and you might lose a small portion of the radiator's area if the case does not have 140 mm fan openings. Moreover, although it sounds silly and unimportant, the decals on the sides of the radiator are upside down and that will look bad from a windowed side panel of a well-designed system. (Hopefully this is something that Zalman has fixed in their assembly process.) But ultimately, it's the performance of the Reserator 3 Max Dual cooler that confounds us the most.

Every all-in-one cooler that we have ever tested has a thermal resistance that either remains nearly constant or improves slightly as the load increases. Ideally, the thermal resistance of the cooler should be constant, but there are many factors at play in a complex multi-liquid system such as this. However, the thermal resistance of the Reserator 3 Max Dual increases alongside the load, which is inexplicable with what we know about this cooler.

Copper tends to have a thermal conductance that decreases faster than that of aluminum as the temperature rises, but the temperatures that we deal with are low and the change seems rather abrupt, therefore this is not very likely. Although we cannot fully explain why, it seems that the Reserator 3 Max Dual cannot dissipate high quantities of thermal energy quickly enough. This makes it the perfect cooler for the newest generation of processors but, at the same time, a bad idea for anyone who plans to use an energy-hungry CPU (e.g. extreme overclocking).

Our expectations were much higher from a product that is being advertised as the "ultimate CPU cooler". Assuming that the majority of enthusiasts that will buy such a cooling solution will also overclock their systems, we can only recommend the Reserator 3 Max Dual to those that will be using Haswell core processors, as they have very low energy requirements. If you expect the thermal power of your CPU to exceed 120 Watts when stressed, then another product will most likely be both cheaper and more effective.

Testing Results, Low Fan Speed (7 Volts)
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  • garadante - Thursday, August 21, 2014 - link

    Apologies for the several typos throughout. Curse the lack of an edit button!
  • AnnihilatorX - Thursday, August 21, 2014 - link

    garadante I agree with the E.Fyll here actually. It is far more accurate to compare different coolers using a scientific method, that is, isolate the system and controlled for all other variables. The result in this analysis is valid in that the performance delta between different coolers indicate accurately their relative performance across ALL scenarios, this is because ambient variables such as CPU, systems, are controlled for.

    Yes, the absolute temperature values won't be indicative of a real system, but it doesn't matter, as ambient temperature would have affected different users anyway. No matter how the author sets up the real rig, the results would mean different thing to different people. In this scientific way, it is less work for the author and less variables to control for, and more accurate as well (can't accurately control for CPU power load without special equipment like the one used here).
  • garadante - Thursday, August 21, 2014 - link

    But please answer my primary point: testing with uniform fans and uniform thermal paste. Why is this unreasonable to ask for? He's willing to test a dozen and a half CLCs, what I'm saying is there are quite a few people who would be interested in seeing a third of that, just the most interesting ones, with 2 or 3 different types of fans each, focusing on high CFM, high static pressure, and a mixture of the two in order to get a scale of what changes favorably with certain fans for each radiator. Then we can find out if a particular radiator excels at quiet operation with the right fan. Or if another excels at absolute delta T. Or what we can expect to change in performance if we go for a fan a little bit louder but more powerful, or the reverse where it's quieter but a little less powerful. It would show us tradeoffs and illuminate a whole deeper (and extremely relevant) aspect to the world of liquid cooling. Fans with radiators are hugely important but E.Fyll gives it no thought to explore and inform his readers.
  • Death666Angel - Friday, August 22, 2014 - link

    "You're new to working for Anandtech, and so you should know that you've joined a well established community. We welcome you gladly to do what you can to raise the standards here even higher, but you cannot expect to do things your way when its against what the community desires."
    Wow that's condescending. And your assumption to represent the whole of the Anandtech community is quite arrogant as well.
    I personally am fine with his approach and testing methodology. If you want to know the performance of thermal paste, look at one of the tens of reviews that show a difference between the best liquid metal ones and the cheapest of about 5K. And in that narrow a space, differentiating between one thermal paste and another without alternating other factors becomes a problem. I have seen tests where your AS5 performs very badly and others where it is in the middle of the pack. This is due to different application of the paste (distribution and volume) and also the pressure between the heatsink and the IHS. If that varies from one run to another even a little, it can have great consequences when we are talking about fractions of a K determining the position of the paste in the ranking.
    Using a few different fans is a more reasonable request. But then the comments would just shift from "why are you only using the default package stuff" to "why are you not using the fan I am most fond of and instead use these other 3 I don't care for".
  • garadante - Saturday, August 23, 2014 - link

    The simple fact is of my many years spent here I've never, ever seen one of the writers at Anandtech post such hostile and condescending posts towards comments of their readers, especially with such regularity as E.Fyll. Perhaps the way I phrased it came off too strong but that's simply what I see and it bothers me, because E.Fyll -is- new here. He was hired on in the last batch, and honestly I'm sad to see him taking over articles from previous writers who did a better, more friendly job reviewing products.
  • DanNeely - Tuesday, August 19, 2014 - link

    You've captured the utter fail of E. Fylladitakis's thermal testing. Absolutely reproducible and absolutely meaningless.
  • garadante - Wednesday, August 20, 2014 - link

    The only usefulness I can see is relative comparison of CLCs. But other than that yeah, no useful meaning from these results as the test stands now.
  • dragosmp - Wednesday, August 20, 2014 - link

    This "only" usefulness is exactly what's needed to decide the best cooler. It may be because I do this as part of my work, but the °/W is the only thing we need to discern between the different cooling configs.

    I have two points to make:
    1. Such a cooler is a complex system and it is described with a number, the °/W. This is simplistic, but sufficient because nobody will add turns to the electric motor of the pump to boost pressure and modify the flow to change the type of flow from laminar to turbulent (if that was even possible). The slope of the rise in °/W with the load as well as the 7V testing (for the pump too if I got it right) points towards the bottleneck. It's unlikely that's the pressure of the pump, and also the type of flow of the air in the radiator fins; I'd point more towards a lack of °/W of the CPU block or too tight tubes.
    2. The temperature delta is of course between the equivalent CPU heat-spreader and the ambient, how could it be any other way? You agree I think that per any CPU architecture the thermal conductivity between the die and the heat-spreader is within very tight margins, from the hat I'd pull a number such as 0.2°/W ==> 20°C of die temp rise for every 100W.

    To sum up: @E.F. - great article, as techie I understand the methodology, the results are perfectly usable. To "translate" these results into what someone might compare to a CPU die temperature it would be enough to put a table with average thermal resistance per architecture of CPU: say SandyBridge 0.15 °/W, Ivy 0.2 °/W, Haswell-E 0.12 °/W etc etc etc and anyone could compute their die temperature from the results you posted. (I give you no one knows precisely what the thermal dissipation actually is in a CPU so prediction of die temp if fraught with peril even when knowing the Rth, but hey...)
  • kwrzesien - Wednesday, August 20, 2014 - link

    Now that would be the sort of additional analysis and insight that AnandTech is famous for! In fact not just a table, but a few pages running through test setups on an AMD chip or two (APU & FX) and about five Intel’s: Core i3 Haswell, Core i7 Sandy, Ivy & Haswell (i7-x770K) and a 2011 socket chip like the 4930K or the X (sometimes those seem to be more available to you guys, which is just fantastic for you but the K is the part everyone actually buys - and I'd argue would be the better one to test since it isn't a perfect die so it usually runs at a higher voltage).

    To top it off do each of those at stock and overclocked and then chart all of those TRA's (thermal resistance per architecture - nice job drago!). Then do a i7-4790K just to show that it still sucks.

    I think you would find a few very interesting things. One is that at 32nm the cores have more surface area and thus are able to dissipate their heat better, while the change to 22nm AND the TIM of Haswell has combined to create a localized heat transfer bottleneck between the die and the IHS. There isn't a thing that any air or water cooler can do to help that, you need liquid nitrogen or some kind of freon chilled refrigeration unit that could drop the temperature of the heatsink plate and thus IHS low enough to create a much higher delta T for the die-to-TIM-to-IHS interface to increase the heat transfer rate. Nitrogen isn't practical but I honestly wonder if they couldn't make a Reserator 1 v2-like device that was a mini-AC unit with freon. Of course nobody wants a condensate line running out of their PC, but I'm sure someone could figure something out...

    Or Intel could have made Devils Canyon a product worth buying by soldering the IHS the same way it does on the "E" and Xeon chips. They would have had a big win on their hands if they had done that, even if Haswell still couldn't overclock that well for whatever reason.

    We will know more shortly when Haswell-E drops, which will be 22nm, six or eight Haswell cores and built with a proper soldered IHS. If it's a 22nm heat density issue then E should have a little better heat-transfer properties due to the soldered IHS. If it's a frequency limit with the Haswell cores on 22nm then it will stop at 4.7 GHz (or lower) no matter what. Which will leave the question of whether Broadwell will clock better or have we seen the end of those days?
  • bludragon - Wednesday, August 20, 2014 - link

    This is not quite right, since the °/W of the cooler will change depending on the surface area it is attempting to cool. For example, one cooler (lets say with a thin copper base on the water block, but a very large radiator) might work very well across a 30x30mm (900mm2) surface, but if you were to concentrate the heat on a smaller 10x18 (177 mm2) it might work less well than one with a thicker base on the waterblock and a smaller radiator, or even an air cooler which has a thicker base.

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