Corsair Graphite 760T Case Review
by E. Fylladitakis on March 27, 2014 1:10 PM ESTCorsair Graphite 760T Interior
Most of the interior of the Graphite 760T is black, with the exception of the top and bottom panels, which are white on our sample (with black as an alternative). The mechanical strength of the case is well above average; Corsair could not cut corners with a design that receives no mechanical support whatsoever from its side panels. The thickness of the metallic chassis is sufficient and extra supports have been installed to reduce flex at nearly all the panel junction points. There could have been some extra support between the motherboard tray and the front panel, as they are essentially connected only with the 5.25" drives cage, but we cannot really complain about it since there is no apparent structural weakness to be found on the chassis.
The Graphite 760T has a large, all-black motherboard tray permanently attached to the chassis. It can hold up to Extended ATX and XL-ATX motherboards, as well as all the smaller compatible versions, down to Mini-ITX; however, even a full ATX motherboard looks small inside the Graphite 760T, so smaller motherboards will look very out of place. There are openings on the side and top of the motherboard tray for the routing of cables, with the former featuring rubber grommets. There is ample clearance between the motherboard tray and the top panel, ensuring that liquid cooling radiators will fit without issues.
Although it is possible to use a PSU of virtually any length with the Graphite 760T, we strongly recommend to not select a unit with a chassis longer than 175mm if you do not plan on removing the first HDD cage. The PSU sits directly on the metallic panel itself, which has been embossed to raise the unit slightly.
There are two HDD drive cages installed in the Graphite 760T, out of the four possible total (sold separately). Each cage has three trays and thus can hold up to three 2.5" or 3.5" drives. 3.5" drives are secured by simply flexing the tray to make the metallic studs go into the screw holes of the drive, but screws are necessary for the installation of 2.5" drives. The cages are removable and stackable; they can be installed in any combination, some of which are depicted in the above gallery.
By removing the rear drive cage, an additional 120mm fan mounting point is revealed. It is also possible to leave only the rear drive cage where it is and remove the front cage, allowing the installation of a large liquid cooling radiator. When installed at the bottom of the case, they are placed on a plastic stand, which can be removed from the bottom of the case. Actually, it will have to be removed alongside the attached cage if you wish to remove it from the case, as the frame of the case blocks access to the front screws required to release the cage from its plastic stand. This is not an ingenious approach if you ask us; at least holes should have been punched on the frame where the screws are located, allowing a screwdriver to fit through. Furthermore, if you decide to connect two of the cages, connecting them will instantly scratch some paint off the sides that are brought together.
Corsair provides ample clearance behind the motherboard tray for the routing of cables. There are many cable tie mounting points and several openings for additional flexibility. The most prominent feature on this side of the case however is the four plastic 2.5" drive slots, which are placed sideways across the edge of the motherboard tray. These mini-trays are removable and very easy to use, as they will simply lock any 2.5" device (presumably SSDs) inserted into them. Screws can be added for extra safety, although it seems extremely unlikely that a drive could come out of the tray if someone does not pull the plastic locking latch intentionally.
The doors can be removed by simply pulling them upwards once they are open. Although that will not be necessary when performing small upgrades, we strongly recommend doing so when you want to build a new system or to perform a major overhaul.
Black cables and parts are easily hidden inside an all-black chassis; therefore, for visual clarity, we are using an AX760i PSU with a red cable pack and white SATA cables for our pictures. Building a system inside the Graphite 760T is a seamless procedure, aided by the large size of the case. Most of the time required to build a system inside this case will most likely be for the routing of the cables. There are no sharp or dangerous points about the Graphite 760T that we could locate during our experience with it.
As exhibited in the pictures of our test build, a full ATX motherboard is a little short for the tray of the Graphite 760T, creating a gap between the cable openings and the board itself. The EPS connector and other cables that may have to reach the top side of the motherboard can be easily routed through the openings at the top of the motherboard tray. Graphics cards of virtually any length can fit as long as there is no HDD cage placed in front of them. The addition of a second cage at the front of the case will limit the length of the graphics cards down to 340mm, which is still adequate for the vast majority of GPUs, but ultra-long performance monsters will not fit. Also note that the plastic 2.5" trays will have to be removed if a HDD is to be installed in a cage beneath them and reinstalled after the cables have been routed out of the way.
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Black Obsidian - Friday, March 28, 2014 - link
So you agree that your thermal load has no meaningful relationship to the object it's supposed to be a proxy for (an active system), but that you see this as in any way advantageous is the part that I'm having difficulty comprehending.I'm going to cut down a much longer reply by simply bringing us to my ultimate point, which is that you appear to be starting by assuming a spherical cow in a vacuum (http://en.wikipedia.org/wiki/Spherical_cow for the reference, in case it's too obtuse).
A static thermal load, like a spherical cow in a vacuum, virtually eliminates variables and simplifies the problem, which absolutely meets your stated goal of achieving repeatable results. But in so doing, it fails to emulate real-world situations (your other stated goal), because nobody, to my knowledge, actually HAS vacuum-breathing spherical cows (or static thermal loads in need of computer cases to house them).
If your static thermal load is any easier to translate into the performance of an actual active load than one particular active load is to translate into a different active load, I'm clearly failing to understand how that is so.
E.Fyll - Friday, March 28, 2014 - link
I fear that you understood little of what I said. I will consider the "spherical cow" mention as a joke, since it only applies to highly simplified theoretical studies, not laboratory testing. As a matter of fact, the "spherical cow" approach is a much better description of what you refer to as "real-world testing". Since you are referring to the results generated by a single system and you are actually trying to make comparisons with it, you are making half a thousand guesses and assumptions in order to make a guess about how a change of a single component would affect the thermal performance of a single case, let alone the comparisons between different cases or between different systems.What I said is that my thermal load is not directly comparable to that of an active system. It can however be used to compare the thermal performance of different cases and displays the true performance of a case, unaided by external factors. I cannot tell you how a case will perform with every possible configuration that could be installed inside it; however, I can tell you which case has better stock thermal performance regardless of the configuration that will be installed. On the other hand, testing with an active system creates results that again are not comparable to that of any other system and, as it adds a ton of variables, it also is obsolete for comparisons between different cases. If I were to do something like this, I would only be showing you some numbers that cannot be used to compare cases and cannot be used as a reference for any other system, even if it is almost entirely identical to the test system; it does not get any more useless than that.
By what you are saying, you are suggesting to drop a methodology that can generate repeatable results and display the actual performance of the cases, in order to replace it with a "testing" procedure that will produce results impossible to compare them to other systems and useless for the comparison of different cases; in other words, meaningless and misleading.
Let me try another, far too simple argument. I would need much less time and a fraction of the energy required to perform such testing if I were to simply press the power-on button with the system depicted in the review, run some applications and write down the numbers. Actually, it would reduce the time needed to test a single case from 2-3 days to about...30 minutes. I could essentially double my output (and my income, plus the energy cost). So, unless you actually believe that I am mentally deranged, take my word for it; there is no "real-world" testing that could produce any results meaningful to anyone.
As you said so yourself, I strive for scientific vigor and repeatability. If you still believe that "real-world" testing is in any way better than testing done with lab equipment and by someone who at least understands the basics of the scientific method, then by all means, feel free to discard these results as "pointless" and refer to other sites for "meaningful" testing.
MarcusMo - Sunday, March 30, 2014 - link
Agreed on every point. To those that cringe at the notion of reading the two full answers above, would you agree with the following summary:- "Real world" testing does not give any real world insight since the variance between individual systems is too great.
- Gaining any absolute knowledge about how your system will perform in a certain case is thus impossible. Let it go people.
- The best we can hope for are accurate comparisons between cases, but that is not going to happen as long as we cling to the flawed "real world" testing methodology. This is the rational for using a synthetic load method in case reviews from now on.
I think part of the acceptance problem lies in the lack in any comparative data at this point. Once you have a couple of relevant test points as a reference I think people will see the upside to your awesome work. Keep it up!
britjh22 - Thursday, April 3, 2014 - link
"I cannot tell you how a case will perform with every possible configuration that could be installed inside it; however, I can tell you which case has better stock thermal performance regardless of the configuration that will be installed. "I understand why the change in methodology was made, but I think part of the issue that people have with this new format is that it is too technical/scientific. I think most of us come to AT to read articles about various hardware because we are interested consumers and possible buyers, not interested engineers.
While the new format is more scientifically rigorous, you yourself indicate above that the data you end up with is not representative of any system that the reader may install, so what use is it to us? Yes, we can see what the stock cooling with a simulated load may be, but is that any less or more helpful then the previous methodology of a fixed system tested across the cases? It may be more valuable from an engineering standpoint, but it may be less useful from a consumer who is comparing cases.
While I understand the desirability for a single test that can be applied to any case regardless of form factor, a tiered system that represents more buyer expectations may be better. This could be something like a standard mATX system, an ITX system, an ATX system with tower cooler, and an ATX system with CLC for the CPU. While I realize this is not as easy to keep on hand for a reviewer, that is what you are "up against" with the other review sites. When a consumer comes to a case review, and sees the AT review with some simulated thermal load, and a competitor review with a system that is a close approximation of what they have or are planning, which do you suppose they are more likely to take to heart?
You did make the point that there are significant differences between OEM's for similar items, and with different sensor points, etc. However, you provide no actual evidence of this, while stressing your knowledge, education, and that apparently, unlike your readers, you "at least understands the basics of the scientific method", which just make you look arrogant. I think a great article, to support this new testing methodology, would be to show just how much of a difference switching just a motherboard with different/differently placed sensors makes.
Additionally, to help shore up the consumer value of these articles, I think more space/effort needs to be paid to how the case is while building. There are basic statements like "Building a system inside the Graphite 760T is a seamless procedure, aided by the large size of the case. Most of the time required to build a system inside this case will most likely be for the routing of the cables", but it doesn't seem to ring true with any personal experience or flair, something that Dustin did quite well that I would guess readers are missing, myself included.
creed3020 - Friday, March 28, 2014 - link
Wholeheartedly agree with the above, especially the last paragraph. Scientific value and rigor have been added to the reviews but real-world, comparable metrics are arguably absent.I also don't see how results from one review are going to be compared to another with the style of these graphs. Obviously we don't know exactly what the graphs/charts/data grids will look like in advance but the Thermal Load graph for instance already has 4 different series worth of data. Overlaying another 4 series for just one other case is going to look very messy, never mind what it would look like with 10 others.
JarredWalton - Friday, March 28, 2014 - link
I'd suggest that if you look at the final CPU/GPU/etc. temperature at the end of the test sequence, that's an easy figure to compare with other test systems. "System A has 55C on the CPU, system B has 60C on the CPU -- A is better." Hopefully we'll have enough cases to work from in the next week or two so that we can start showing additional (useful) charts.BlakKW - Saturday, March 29, 2014 - link
Ok, I guess you've convinced me that you know what you're talking about, and will try to stay open-minded as more results are compiled. But one thing that bothers me is after all your efforts to create uniform methods, why not use a nice set of the same fans in every case?Doesn't using stock (supplied) fans introduce a huge variable from case to case, both in thermal and acoustic testing? I would rather know how the case itself performs, as opposed to the possibly cheap fans that are included...
Aikouka - Thursday, March 27, 2014 - link
I skimmed a bit of it, but this sentence stuck out at me..."Corsair provides ample clearance behind the motherboard tray for the routing of cables."
If I had to give just one rule in regard to technical writing, then it would be to avoid subjective analysis. In other words, how do I know that his idea of what's "ample" is the same as mine? An actual measurement would be best, and possibly a comparison of that value to competing cases.
Also, I miss the ability to compare cases to each other. Heat and noise are huge factors to me when considering cases, which is one reason why the lack of a side fan-mount is a no-go for me. However, we only get heat values for the current case in the reviews.
E.Fyll - Friday, March 28, 2014 - link
I am not really sure if I should take that as a compliment. I am usually getting bashing because my writing is "too technical". :)You are right. The clearance however is not even across the entire section and people hardly care about a few mm's difference, for which reasons I believed that a qualitative evaluation would suffice. It is 21.6 mm between the panel and the motherboard tray, which falls down to 15.2 mm at the rising sections near the openings and goes up to 27.9 mm behind the 5.25" bays. It also is practically zero where the 2.5" slots are mounted.
I will consider adding precise measurements in my future reviews.
Aikouka - Friday, March 28, 2014 - link
I probably wouldn't worry too much about reporting varying differences unless said difference causes a problem. I think most users know the offending cable is typically the ATX power cable. The reason why I'm so picky about space is because of another Corsair case: the Obsidian 800D. The 800D was a decent case with a lot of interesting design choices, but a not-so-good one was the lack of clearance in the back. I used a Corsair HX750 with it, and the bulky ATX power cable caused the solid side panel to bow out as there just wasn't enough room to accommodate it. In my 900D, I actually use the same cabling kit that you are.Although, another issue is usually power cables connecting to hard drives. That's where this cable comes in handy: http://amzn.com/B0086OGN9E . Those plugs can be moved on the wire, which means you can get them exactly where you need them without trying to contort your poor power cables and stuff them in between drives.