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Western Digital Announces World's First 10TB Helium-Filled Hard Drive (techgage.com)
Deathspawner writes: Western Digital today announced a new, helium-filled enterprise HDD that allows for 10TB capacities without using the SMR method, sticking to industry standard PMR. SMR, or Shingled Magnetic Recording drives, can not typically be used natively by the OS or disk controllers, and instead often require extra software and/or firmware updates. This makes their broad adoption limited, since the drives are not drop-in replacements for the far more ubiquitous Perpendicular Magnetic Recording (PMR). WD's latest enterprise drive, sold as the HGST Ultrastar He10, uses the PMR storage method, and as such is a full drop-in replacement for any standard hard drive.
All the audio tracks you store on the drive sound really high-pitched and squeaky when you play them back...
I've abandoned my search for truth; now I'm just looking for some useful delusions.
Tethering yourself to a bunch of helium-filled drives is a great way to get into the cloud.
Thanks to the War on Drugs, it's easier to buy meth than it is to buy cold medicine!
I have an SMR 8TB Seagate drive which is marked as an archival drive. It's worked well so far. The problem with Shingle Magnetic Recording drives which I have noticed is that occasionally the drive will "stall" while it rearranges data. This is probably extremely bad for some raid systems as the paranoid ones might think the drive has prematurely died. Still this drive was inexpensive for its size and stores a LOT of data which is handy for backing up my actual RAID NAS system. Just don't use a drive like this in your Raid or you might run into serious problems.
I worry about these helium drives leaking their helium eventually and dying. They claim to have a sealed unit where the seal will last for years which is hopefully the case but you never know...
Stop promoting this myth.
From http://geology.com/articles/helium/
Some natural gas fields have enough helium mingled with the gas that it can be extracted at an economical cost. A few fields in the United States contain over 7% helium by volume. Companies that drill for natural gas in these areas produce the natural gas, process it and remove the helium as a byproduct
And by 'byproduct' they mean blow it to the wind without a second thought. That's 7% helium by volume, just dumped as we type. Do you think the world's party balloons (or fractional amounts in hds) even come close to this volume?
I agree that Hydrogen sounds like a better approach.
1) orders of magnitudes cheaper
2) even less dense
3) much larger molecules, so leakage should be far less
Not inert, true, but that should be possible to deal with.
Nice thought on #2, but incorrect. Hydrogen diffuses through steel quite quickly.
Hydrogen is the bane of ultra-high vacuum (UHV) systems, which have stainless steel walls 1/2 to 1 inch in thickness. New system? Hydrogen comes out of the steel itself, as it contains some. But with time, that might be depleted, but no —more comes in from the atmosphere, or from any replaced components or new seals.
For UHV systems, helium is quite useful for finding leaks. Microscopic or even nanoscopic pathways for the helium atoms to make their way in. One frequently has poor base vacuum, and must hunt around blowing helium on suspected parts. These could be anything: micro-crack in a weld, stress-crack in a feed-through, an improperly bolted seal, a loose bolt. It can get very fiddly.
and suddenly slashdot was silent.....
Purifying helium is not hard: everything else condenses out way before it does. You just blow "dirty" helium over a sufficiently cold heat exchanger, and everything other than helium will condense on the heat exchanger. See e.g. this excellent reference.
A successful API design takes a mixture of software design and pedagogy.
The real reason is that the heads need some medium to "fly" on. When they rub the disk surface, it's called a crash for a reason.
Why guess when you can know? Measure!
The MTTF makes a big difference to large installations. (I don't know what MTFB is besides a typo in the article -- Mean Time to Fail Badly, perhaps? In any case, MTTF is the better measure of hard drives as they're pretty much not worth repairing, as MTBF would measure.)
We have one installation that operates 60,000 hard drives that spin a total of 24*60000 = 1,440,000 hours per day. A MTTF of 2.5 million hours means I can expect one of these drives to fail every other day. While that would be much better than our current rate of 12 failures per day, and would save us a lot of money on maintenance contracts, it doesn't mean the drives are impervious to failure. It just means that their failures are less expensive than our current drives.
I also have a hard time believing any disk manufacturer's claims for longevity, because we often prove them wrong. We bought a handful of "enterprise class" drives for a dozen workstations that claimed a 1.2 million hour MTTF. We had 8 out of 24 drives fail within 50,000 hours (5 years), for an actual MTTF of less than 150,000 hours (the failures happened after burn-in but before the 5 year mark, which is when the machines were replaced.) Claims of 2.5 million hours MTTF just don't ring true.
John
Then you are not worried about helium leaking. You're worried about oxygen and nitrogen leaking in. Thankfully those are all WAY easier to stop then helium, and a properly designed device shouldn't have trouble.