Author

Topic: We'd love board feedback on our concept: Combined Heating and Computation (Read 6850 times)

newbie
Activity: 16
Merit: 0
Donating to solar roadways is pretty much admitting engineering is not your thing.
I think your concept is definitely possible and doesn't break any of the laws of physics, but I just cant see it being ever beneficial cost/energy wise.

Well my friend,  Solar Roadways has been chosen by Popular Science as one of the 100 Greatest Innovations of 2014! It's in their 27th annual "Best of What's New" December issue and the department of energy as well as the California IOUs have asked us to submit proposals for grants... Looks like were both on the right path!

Take a look at the new projectexergy.com and let us know if this is any better.

The website looks much more professional than before, however it's lacking information. I'd like to see diagrams/explanations while getting straight to the point and avoiding obfuscation.

As I said before you should really forget about solar roadways and try to distance yourself because it's damaging your credibility. It is undeniably uneconomical to make solar roadways. It's been debunked by so many engineers at this point I'm surprised so many people are still latching on to the concept. If you guys can't figure out why solar roadways is unfeasible then I'm afraid your invention is doomed to fail for the same reasons they are. (hint: it's the cost)

Looking at the "henry-build-log" I am digging the watercooling setup however it looks pretty expensive. I'm guessing your whole cost is at least ~$500 for a ~500W system.

Let's do the math:

I pay ~$10/MBTU ($0.034/kwh) and ~$0.15/kwh.

0.5 kw * $0.034 * 24 * 365 = $148 (possible savings per year)

0.5 kw * $0.15 * 24 * 365 = $657 (cost of using electric heating instead of natural gas)

So you would need to find a computing application that pays at least $509 per year with only 500w worth of hardware before it becomes cheaper than natural gas heating for a maximum savings of only $148 per year.

If you do manage to find an application that pays out that well, then I'm sure it would make more sense to just set up a datacenter with cheaper electricity + more powerful/efficient servers.

Okay jimmothy - we've started our prelaunch for Kickstarter.  Take a look at our prelaunch videos and see if they make sense?

FB forum: rgy]https[Suspicious link removed]rgy

Animated Pre Launch Video: https://lo3energy.wistia.com/medias/zbtaim9o9o

Pre Launch Teaser: https://lo3energy.wistia.com/medias/sxm43ep69m

We're hoping you have more suggestion!
newbie
Activity: 16
Merit: 0
Thanks for the feedback on the website, it's helpful.  I think we'll add an animation or two about how the system integrates with other building systems but we likely won't go into detail about its construction. 

The costs are much higher than your estimates but the benefits and returns are much higher as well.  Sorry, no details to give there but suffice it to say there is a financial model that looks pretty interesting.  These folks from Germany seem to be on the same Path:  https://www.cloudandheat.com/en/index.html
hero member
Activity: 770
Merit: 509
Donating to solar roadways is pretty much admitting engineering is not your thing.
I think your concept is definitely possible and doesn't break any of the laws of physics, but I just cant see it being ever beneficial cost/energy wise.

Well my friend,  Solar Roadways has been chosen by Popular Science as one of the 100 Greatest Innovations of 2014! It's in their 27th annual "Best of What's New" December issue and the department of energy as well as the California IOUs have asked us to submit proposals for grants... Looks like were both on the right path!

Take a look at the new projectexergy.com and let us know if this is any better.

The website looks much more professional than before, however it's lacking information. I'd like to see diagrams/explanations while getting straight to the point and avoiding obfuscation.

As I said before you should really forget about solar roadways and try to distance yourself because it's damaging your credibility. It is undeniably uneconomical to make solar roadways. It's been debunked by so many engineers at this point I'm surprised so many people are still latching on to the concept. If you guys can't figure out why solar roadways is unfeasible then I'm afraid your invention is doomed to fail for the same reasons they are. (hint: it's the cost)

Looking at the "henry-build-log" I am digging the watercooling setup however it looks pretty expensive. I'm guessing your whole cost is at least ~$500 for a ~500W system.

Let's do the math:

I pay ~$10/MBTU ($0.034/kwh) and ~$0.15/kwh.

0.5 kw * $0.034 * 24 * 365 = $148 (possible savings per year)

0.5 kw * $0.15 * 24 * 365 = $657 (cost of using electric heating instead of natural gas)

So you would need to find a computing application that pays at least $509 per year with only 500w worth of hardware before it becomes cheaper than natural gas heating for a maximum savings of only $148 per year.

If you do manage to find an application that pays out that well, then I'm sure it would make more sense to just set up a datacenter with cheaper electricity + more powerful/efficient servers.
newbie
Activity: 16
Merit: 0
Quote
Donating to solar roadways is pretty much admitting engineering is not your thing.
I think your concept is definitely possible and doesn't break any of the laws of physics, but I just cant see it being ever beneficial cost/energy wise.

Well my friend,  Solar Roadways has been chosen by Popular Science as one of the 100 Greatest Innovations of 2014! It's in their 27th annual "Best of What's New" December issue and the department of energy as well as the California IOUs have asked us to submit proposals for grants... Looks like were both on the right path!

Take a look at the new projectexergy.com and let us know if this is any better.
legendary
Activity: 826
Merit: 1004
We are in a very early R&D phase. Submit a contact form and I'll get you on the list to be notified when the Kickstarter sets off.
This is a dumb idea. Don't send them money. Home Bitcoin mining is dead, killed by increasing difficulty.

It's not even a new dumb idea.  Over 30 years ago, there was the Frenette Friction Furnace, an electric motor driving a brake. This is just the Internet-enabled version of an old scam.

People always make this mistake. It's not the difficulty which hurts home miners, it's the difference in the cost of electricity and the lack of volume being ordered. When it comes to BTC mined per Gh/s, someone with 100 Ph/s will mine at the same rate as someone with 1 Th/s. If electricity costs were 0 and the miners all cost the same per Gh/s, the profits would also be the same.
hero member
Activity: 770
Merit: 509
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You've really proven nothing new, especially none of the key concepts you're suggesting are practical.
**All the key concepts are practical, the only thing we've proven is we're not particularly good at explaining them... thanks for cluing us in, when you do this every day it all seems pretty obvious.

I think you mean you hypothesize they are all practical. Until you can demonstrate that you can recover X watts with minimal loss, year round, and without needing 5 times as much hardware as normal I wouldn't consider anything proven.

But I do agree you are completely failing to properly explain your concept and hopefully will have much more to show by time the kickstarter campaign begins.

Your website needs to be completely redone no offense. I'd suggest taking a hint from these guys: http://www.allied-control.com/ . You should include calculations, diagrams, explanations, and cut out the BS.

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**I personally donated to solar roadways, not because it was practical but because it sends a message to manufacturers, developers and governments that this is the kind of change I want to see.  Whether you think it was a scam or not he made a trip to the White House (Bill Nye evidently likes him?) and is building the things at a scale previously not possible.  Interesting thing is he has already taken orders for several of the first systems proving we either don't understand the economic model or that he doesn't need one to sell the product.

Donating to solar roadways is pretty much admitting engineering is not your thing.

I think your concept is definitely possible and doesn't break any of the laws of physics, but I just cant see it being ever beneficial cost/energy wise.

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How can you possibly begin raising funds without a clear business model?
**How can Solar Roadways sell their systems or raise grant money from the DOT without a clear economic model?  Saying you don't understand his model likely points to his inability to explain it well or our inability to understand it - it obviously says little about the product's viability since he is actually building and selling it!

It's quite simple, they are taking advantage of the gullible who want to save teh planet. How they received grant money is beyond me but clearly it wasn't thought out by a professional.

They raised $750,000 to build a 40 square meter solar parking lot. That is $18,000/m2. The same parking lot could have been entirely covered with asphalt for $80 total (~$15,000 if you wanted to cover it with a solar panel roof). I really doubt it costs that much as I'm sure most of the grant money went directly in to the inventors retirement fund, but it's not cheap by any means.

Most people think current solar technology is still far from being cost effective and to add a thick chuck of glass(not cheap), integrated circuits(not cheap), leds, heaters, etc, only makes it that much more expensive. And having solar panels parallel to the ground instead of perpendicular to the sun greatly reduces efficiency.

It's basically just spending ~$1000/m2 so you can combine a road ($2/m2) with a solar panel ($300/m2). It's all just a gimmick.

There are so many much bullshit claims it's impossible to get to all of them in a few paragraphs so I'll just leave you with some videos explaining it more: http://youtu.be/H901KdXgHs4 http://youtu.be/ocV-RnVQdcs

I really hope you guys won't be asking for a ludicrous amount of money so early in the experimental stage.
newbie
Activity: 16
Merit: 0
**If sized correctly to the load it should run far more than the 20-30% utilization rate the typical datacenter sees.  There are about 120 different distributed computing networks out there now (a good Wiki search) and they are growing in number every day.  Bitcoin is a distributed computing network.  The idea idea is to compute whenever there is a need to generate heat, when the system is sized right that need can be pretty consistent.  Again - we would not continue to develop this design, it is just the first prototype.

Care to share your calculations?

Only in a perfect world where weather conditions never change throughout the year and people always use the same amount of heating/AC/hot water/refrigeration, this might work well.

**Wont share the calculations but I will give you a clue - the key is in the storage tanks.  

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**Not the model - a valiant effort but, seriously, who would do that?  And... why would we publish the business model on a forum?

Where else would you publish it, the local newspaper? You guys came to this forum asking for feedback without giving us any idea of what your product does. We really shouldn't have to pry this info from you especially when you're weeks from launching a kickstarter.

**We came to see how people react to the idea, not to give them our business model.

What exactly is your business model? Will you be running a monetized distributed network? Selling the rube golberg machines by themselves? Selling hardware+rube golberg machine combos? Designing a chip? Installing/servicing entire home integrated systems?

Not sure how we're supposed to know/discuss your concept while you guys are providing as little information as possible.

**That is a problem but you are obviously smart and think about this stuff, I'm sure you will think of several viable business models if you let the concept sink in for a day or two.

So far here's what you've demonstrated:

- Using a computer creates heat which can then be sent through a watercooling loop to an insulated tank that can store the heat for a few hours and release it when heating is needed. (subtracted the rube golberg part)
- By spending several hundreds of dollars you can match the efficiency of a stock cpu fan+heatsink when it comes to heating your home using a computer.

**No, you removed a key and fundamental element of the system.

Here's what you need to demonstrate:

- You can store 190F water in a tank for hours without significant heat loss.
**I'll do you better - the next set of tanks will be filled with phase change material that actually holds significantly more energy than the water tanks we are using now.  Noodle on that for a bit.

- You can use 190F water from a computer to efficiently and cost effectively power a watertank/AC/refrigerator.
**Already done.  Wait - do you want to actually drink a computation cooled beer?  That can be arranged.

- You can efficiently power each of those appliances at the same time.
**We don't need to - think about energy storage... you'll get it.

- You can do so while maintaining a constant/efficient computing rate throughout the day/year.
**We don't need to.  If the energy source for the computation is free then I care a whole lot less about the efficiency of the computation.

- You can prove the costs are not more than regular gas/electric heating.
**Alright.  Computation produces the same amount of heat for the same energy as a resistance heater.  Computers are, after all, resistance heaters.  If you currently have a resistance heated anything we are 1-1 - if you don't the free computation more than pays for the delta in cost.

- You can give people an incentive to run their computers 24/7/365 (it's not like people are naturally using 1.5KW 24/7. More like ~200W a few hours a day)
**We don't want to run your computer, we'll want you to run our computer and we might be able to do that very inexpensively, from an energy perspective.

Until then you really have no business starting a crowdfunding campaign, but that's just my opinion.
**I don't remember asking for permission but perhaps the above answers have changed your mind?

**Whoa.  Is there a business model in there somewhere?
newbie
Activity: 16
Merit: 0
I think part of the disconnect in this discussion is that in this theoretical stage, we are at the limit if answering a lot of the harder questions (and really great ones I might add) because we have hit the limit of the R&D we can do at the level we want. That's the point of the crowdfunding campaign - so we can address and discover more appropriate ways / places where this concept would be a best fit.

Have you really run out of experimenting funds in the theoretical stage?

Seems like a group of people with access to a national lab and fancy simulation software should have no problem buying an old used refrigerator and hooking it up to a water cooling loop to prove your theory.

I'd even be willing to bet you could have bought a used refrigerator or AC for less money than you wasted on those two hot water tanks.

**Interestingly the only reason to even plug a refrigerator into the thing it to demo for people, the math is done we've hit the temperature targets it'll work the moment its connected.  The hot water tanks are a necessity.  In order to test the performance of the system you have to have a load to run it against and the tanks do that perfectly.  We also have a pretty good approximation of the time we need to get that water from whatever point we want to start to whatever point we need to end while testing different strategies (like over/under clocking/volting) to performance test the system.  We can also draw heat off that load without thermally shocking the system - it acts a a buffer.  As you can imagine they system dosent like to go from 180 to ambient in one shot.

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We've proven a few key (and major) concepts but we need to prove more and as my colleague mentioned, we have a national lab here in the US who is onboard to help us do that.

You've demonstrated that you can keep hot water in an insulated tank and heat the water using a computer but literally nobody thought that was impossible or hard to do.

** your obviously smarter than this...

You've really proven nothing new, especially none of the key concepts you're suggesting are practical.

**All the key concepts are practical, the only thing we've proven is we're not particularly good at explaining them... thanks for cluing us in, when you do this every day it all seems pretty obvious.

It's just like how solar roadways has "proven" you can recover electricity from solar panels on a road but in reality it makes absolutely no sense economically.

**I personally donated to solar roadways, not because it was practical but because it sends a message to manufacturers, developers and governments that this is the kind of change I want to see.  Whether you think it was a scam or not he made a trip to the White House (Bill Nye evidently likes him?) and is building the things at a scale previously not possible.  Interesting thing is he has already taken orders for several of the first systems proving we either don't understand the economic model or that he doesn't need one to sell the product.

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Once we start knocking out the things we can and can't do, the business model that we commit to will become more clear.

How can you possibly begin raising funds without a clear business model?

**How can Solar Roadways sell their systems or raise grant money from the DOT without a clear economic model?  Saying you don't understand his model likely points to his inability to explain it well or our inability to understand it - it obviously says little about the product's viability since he is actually building and selling it!

Or is fleecing kickstarter tards the plan?

**We have a business model, it'll eventually be on the website and (like I said) we're not going to outline it on this forum.  Before we do that we'll obviously have to get a lot better at explaining how this thing works to people... although the business model is slightly easier.  Just because its easy to explain to engineers or people already working in the energy industry doesn't mean we can ignore everyone else.  I want to thank you for pointing that out, we'll use this good information to get our act together a little more before we do the kickstarter - I'll fully expect you to be there to debunk us!
newbie
Activity: 25
Merit: 0
I think part of the disconnect in this discussion is that in this theoretical stage, we are at the limit if answering a lot of the harder questions (and really great ones I might add) because we have hit the limit of the R&D we can do at the level we want. That's the point of the crowdfunding campaign - so we can address and discover more appropriate ways / places where this concept would be a best fit.

Have you really run out of experimenting funds in the theoretical stage?

Seems like a group of people with access to a national lab and fancy simulation software should have no problem buying an old used refrigerator and hooking it up to a water cooling loop to prove your theory.

I'd even be willing to bet you could have bought a used refrigerator or AC for less money than you wasted on those two hot water tanks.

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We've proven a few key (and major) concepts but we need to prove more and as my colleague mentioned, we have a national lab here in the US who is onboard to help us do that.

You've demonstrated that you can keep hot water in an insulated tank and heat the water using a computer but literally nobody thought that was impossible or hard to do.

You've really proven nothing new, especially none of the key concepts you're suggesting are practical.

It's just like how solar roadways has "proven" you can recover electricty from solar panels on a road but in reality it makes absolutely no sense economocally.

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Once we start knocking out the things we can and can't do, the business model that we commit to will become more clear.

How can you possibly begin rasing funds without a clear business model?

Or is fleecing kickstarter tards the plan?

Time, as you know, is money. We need money to pay (more) people for their time (and what they are worth) and for wet lab space, which even at incubators isn't cheap (+/- 22k a year). We've done a lot with a little, but self financing is not an option. Research isn't cheap, and when it is cheap, it often turns out to be bad research.

No one was saying that anything here was impossible to do or that no one couldn't do it. We did it. We want to do more.

While it may seem silly to not have a business model hammered out, 10s of billions of dollars are raised each year for concepts that don't plug into pre-determined business models. I mean.....most medical research dollars are essentially sunk costs funded most often with grants from non profit or government entities. Interestingly, the problems they are often trying to solve end up having commercial applications unrelated to the original target application. We are acutely aware that this could happen to us.

Here's just a few examples:

http://www.businesspundit.com/10-accidental-discoveries-that-generated-great-wealth/





hero member
Activity: 770
Merit: 509
I think part of the disconnect in this discussion is that in this theoretical stage, we are at the limit if answering a lot of the harder questions (and really great ones I might add) because we have hit the limit of the R&D we can do at the level we want. That's the point of the crowdfunding campaign - so we can address and discover more appropriate ways / places where this concept would be a best fit.

Have you really run out of experimenting funds in the theoretical stage?

Seems like a group of people with access to a national lab and fancy simulation software should have no problem buying an old used refrigerator and hooking it up to a water cooling loop to prove your theory.

I'd even be willing to bet you could have bought a used refrigerator or AC for less money than you wasted on those two hot water tanks.

Quote
We've proven a few key (and major) concepts but we need to prove more and as my colleague mentioned, we have a national lab here in the US who is onboard to help us do that.

You've demonstrated that you can keep hot water in an insulated tank and heat the water using a computer but literally nobody thought that was impossible or hard to do.

You've really proven nothing new, especially none of the key concepts you're suggesting are practical.

It's just like how solar roadways has "proven" you can recover electricity from solar panels on a road but in reality it makes absolutely no sense economically.

Quote
Once we start knocking out the things we can and can't do, the business model that we commit to will become more clear.

How can you possibly begin raising funds without a clear business model?

Or is fleecing kickstarter tards the plan?
newbie
Activity: 25
Merit: 0
I think part of the disconnect in this discussion is that in this theoretical stage, we are at the limit if answering a lot of the harder questions (and really great ones I might add) because we have hit the limit of the R&D we can do at the level we want. That's the point of the crowdfunding campaign - so we can address and discover more appropriate ways / places where this concept would be a best fit. We've proven a few key (and major) concepts but we need to prove more and as my colleague mentioned, we have a national lab here in the US who is onboard to help us do that.

Once we start knocking out the things we can and can't do, the business model that we commit to will become more clear.

Our presence on the board is to illicit the types of comments  questions you are all bringing. (Awesome). It's also to test our ability to talk about it in a way that it's understood to various audiences. You guys are an educated and pretty tough crowd. We want that.

If you want a deeper level of involvement / access as we move this thing forward, please submit your contact info on the website and we'll keep you posted on things as they progress.

www.3xergy.com

 



hero member
Activity: 770
Merit: 509
**If sized correctly to the load it should run far more than the 20-30% utilization rate the typical datacenter sees.  There are about 120 different distributed computing networks out there now (a good Wiki search) and they are growing in number every day.  Bitcoin is a distributed computing network.  The idea idea is to compute whenever there is a need to generate heat, when the system is sized right that need can be pretty consistent.  Again - we would not continue to develop this design, it is just the first prototype.

Care to share your calculations?

Only in a perfect world where weather conditions never change throughout the year and people always use the same amount of heating/AC/hot water/refrigeration, this might work well.

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**Not the model - a valiant effort but, seriously, who would do that?  And... why would we publish the business model on a forum?

Where else would you publish it, the local newspaper? You guys came to this forum asking for feedback without giving us any idea of what your product does. We really shouldn't have to pry this info from you especially when you're weeks from launching a kickstarter.

What exactly is your business model? Will you be running a monetized distributed network? Selling the rube golberg machines by themselves? Selling hardware+rube golberg machine combos? Designing a chip? Installing/servicing entire home integrated systems?

Not sure how we're supposed to know/discuss your concept while you guys are providing as little information as possible.

So far here's what you've demonstrated:

- Using a computer creates heat which can then be sent through a watercooling loop to an insulated tank that can store the heat for a few hours and release it when heating is needed. (subtracted the rube golberg part)
- By spending several hundreds of dollars you can match the efficiency of a stock cpu fan+heatsink when it comes to heating your home using a computer.

Here's what you need to demonstrate:

- You can store 190F water in a tank for hours without significant heat loss.
- You can use 190F water from a computer to efficiently and cost effectively power a watertank/AC/refrigerator.
- You can efficiently power each of those appliances at the same time.
- You can do so while maintaining a constant/efficient computing rate throughout the day/year.
- You can prove the costs are not more than regular gas/electric heating.
- You can give people an incentive to run their computers 24/7/365 (it's not like people are naturally using 1.5KW 24/7. More like ~200W a few hours a day)

Until then you really have no business starting a crowdfunding campaign, but that's just my opinion.
newbie
Activity: 16
Merit: 0
Secondly, the 'rube goldberg' device pictured above is about 75% efficient at transferring heat to the loop at low temps and it drops to about 50-60% at higher temps above ~160.  The second prototype is submerged in a silicon fluid and well insulated, Sri (senior scientist) is modeling the device now in Comsol http://www.comsol.com/comsol-multiphysics?gclid=CNnmyLeI2MACFSsV7AodCTsALQ and its looking like we'll easily break into the mid 90% efficiency for heat capture with the device when submerged.

Are you saying that currently only 55% of the heat stays in the loop when you want to use it for refrigeration/AC? 45% waste?

**No, I'm saying the current prototype is not very efficient at managing heat.   All the plumbing that moves the coolant is uninsulated and looses a fair amount of heat - the hotter it gets vs ambient the bigger the loss.  We're not investing in the first prototype anymore, its already proven the parts can manage the heat we need to make.

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As for the economics - free energy for computation isn't going to be economic?  Remember we are using energy once and getting two benefits - heat and computation.  You pay for the heat, the computation is free (from an energy perspective) except for the cost of the device.

Thanks-

Correct, it will not be economic.

Here's a simplified comparison for 1MW worth of computing power:


A: Classic datacenter

Capex:

- hardware: $1,000,000
- Warehouse+infrastructure: $200,000

Opex(yearly):

- Electricity: $570,000 (1.3MW at $0.05/kwh)
- Employees:$100,000


5 Year total: $4,500,000
B: Distributed computing (using your method)

Capex:

- Hardware: $5,000,000*
- Cooling recovery system: $5,000,000* (~$1/W at 5MW)
- Distributing/shipping: $500,000

Opex:

- Employees: $500,000**

5 year total: $13,000,000

*Assuming it would require 5 times the amount of hardware because it's being used 25% of the time due to none of your applications requiring 100% load 100% of the time and a 20% efficiency loss due to the hot chips. This is also assuming the system is 100% efficient at recovering the heat but your post suggest it might be closer to 50%.

**If sized correctly to the load it should run far more than the 20-30% utilization rate the typical datacenter sees.  There are about 120 different distributed computing networks out there now (a good Wiki search) and they are growing in number every day.  Bitcoin is a distributed computing network.  The idea idea is to compute whenever there is a need to generate heat, when the system is sized right that need can be pretty consistent.  Again - we would not continue to develop this design, it is just the first prototype.

**I've got no idea how many people it takes to properly run a distributed computing network but I'm sure it takes more than the 2 people needed top operate a large scale bitcoin mine. (guessing at least 10 employees)


** If memory serves Stanfords folding at home network is 250k distributed machines across the planet and everyone who donates their computer idle time is a part of that network.  They have a handful of techs that keep the software and their server running as well as spend time on the forums to answer questions and talk through bug fixes.  Not too many.

So basically you will have ~$9.3M extra startup costs so you can save ~$170k/year.. In this scenario it would take more than 50 years to pay off.

Overall cool idea, just entirely unpractical like solar roadways.

**Not the model - a valiant effort but, seriously, who would do that?  And... why would we publish the business model on a forum?

Side note: Do you plan on having certified technicians around the country ready to fix peoples heater/AC/refrigeration systems when they stop working? Will you be reimbursing customers for all their spoiled food when the computer crashes for a few hours?

**Nope - there are service models that don't require techs all around the world, at scale this will be more like an appliance, not a computer.  

legendary
Activity: 1456
Merit: 1000
It appears to be video cards (i could be wrong).

Have you tried ASIC's?   I just see price being a big issue.  Getting new blocks for each card i think will sadly make it where it's cheaper to do more traditional cooling. But i give you credit for amazing looking cooling.
hero member
Activity: 770
Merit: 509
Secondly, the 'rube goldberg' device pictured above is about 75% efficient at transferring heat to the loop at low temps and it drops to about 50-60% at higher temps above ~160.  The second prototype is submerged in a silicon fluid and well insulated, Sri (senior scientist) is modeling the device now in Comsol http://www.comsol.com/comsol-multiphysics?gclid=CNnmyLeI2MACFSsV7AodCTsALQ and its looking like we'll easily break into the mid 90% efficiency for heat capture with the device when submerged.

Are you saying that currently only 55% of the heat stays in the loop when you want to use it for refrigeration/AC? 45% waste?

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As for the economics - free energy for computation isn't going to be economic?  Remember we are using energy once and getting two benefits - heat and computation.  You pay for the heat, the computation is free (from an energy perspective) except for the cost of the device.

Thanks-

Correct, it will not be economic.

Here's a simplified comparison for 1MW worth of computing power:


A: Classic datacenter

Capex:

- hardware: $1,000,000
- Warehouse+infrastructure: $200,000

Opex(yearly):

- Electricity: $570,000 (1.3MW at $0.05/kwh)
- Employees:$100,000


5 Year total: $4,500,000
B: Distributed computing (using your method)

Capex:

- Hardware: $5,000,000*
- Cooling recovery system: $5,000,000* (~$1/W at 5MW)
- Distributing/shipping: $500,000

Opex:

- Employees: $500,000**

5 year total: $13,000,000

*Assuming it would require 5 times the amount of hardware because it's being used 25% of the time due to none of your applications requiring 100% load 100% of the time and a 20% efficiency loss due to the hot chips. This is also assuming the system is 100% efficient at recovering the heat but your post suggest it might be closer to 50%.

**I've got no idea how many people it takes to properly run a distributed computing network but I'm sure it takes more than the 2 people needed top operate a large scale bitcoin mine. (guessing at least 10 employees)



So basically you will have ~$9.3M extra startup costs so you can save ~$170k/year.. In this scenario it would take more than 50 years to pay off.

Overall cool idea, just entirely unpractical like solar roadways.

Side note: Do you plan on having certified technicians around the country ready to fix peoples heater/AC/refrigeration systems when they stop working? Will you be reimbursing customers for all their spoiled food when the computer crashes for a few hours?

newbie
Activity: 16
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**Thanks for the feedback - its good stuff... except for #4.  We're talking about a minimum temperature difference today of > 100f to ambient which is more than enough to run a single or double effect absorber.  Remember, this thing is running at 180 to 200f right now (with off the shelf parts!), that's more than enough TD to regenerate desiccant or run an absorber.  The ideal range for the absorptive refrigerator is 180 - 200f, if you go above 230f it actually looses efficiency and starts to break down the refrigerant.  The plan is start building chips that hit 210 to 250f.

http://web.stanford.edu/group/narratives/classes/08-09/CEE215/ReferenceLibrary/Chillers/AbsorptionChillerGuideline.pdf
http://www.yazakienergy.com/waterfired.htm


No one is saying that absorption refrigeration is not possible.  When I was very young my parents lived off the electrical grid.  We had an old kerosene powered refrigerator which ran by burning kerosene.  It used absorptive refrigeration.  The refrigerator was replaced as soon as the far cheaper electricity became available.  

We are just saying it is extremely unlikely to be economic running off bitcoin miners.

With your proposed temperature difference of 50C or even 100F the efficiency will be 5 to 10%. The second law of thermodynamics sets an absolute limit to any heat engine.

Lets be really totally optimistic and assume  you are aiming for a 10% efficiency.  If you output 1,000W of heat from a miner you will get at the most 100W or useful work out and still have to get rid of at least 900 Watts of heat.  I just cannot see it even coming close to making economic sense.

Your web site says you have a "Lead Scientist" so I assume there has been some calculations done on expected energy output, on the overall economics, and on waste heat removal to maintain the 100f difference in temperature.

To repeat.  It is the efficiency and economics we question.  Not whether absorption refrigeration exists.



Ahhh... now I understand.  We are talking about 2 seperate issues.  First, we have no intentions of running any of this off of a bitcoin miner.  Were talking about running it off of about 20kW in the appliance.  It seems the biggest hangup might be scale, not science. 

Secondly, the 'rube goldberg' device pictured above is about 75% efficient at transferring heat to the loop at low temps and it drops to about 50-60% at higher temps above ~160.  The second prototype is submerged in a silicon fluid and well insulated, Sri (senior scientist) is modeling the device now in Comsol http://www.comsol.com/comsol-multiphysics?gclid=CNnmyLeI2MACFSsV7AodCTsALQ and its looking like we'll easily break into the mid 90% efficiency for heat capture with the device when submerged.


As for the economics - free energy for computation isn't going to be economic?  Remember we are using energy once and getting two benefits - heat and computation.  You pay for the heat, the computation is free (from an energy perspective) except for the cost of the device.

Thanks-
full member
Activity: 203
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**Thanks for the feedback - its good stuff... except for #4.  We're talking about a minimum temperature difference today of > 100f to ambient which is more than enough to run a single or double effect absorber.  Remember, this thing is running at 180 to 200f right now (with off the shelf parts!), that's more than enough TD to regenerate desiccant or run an absorber.  The ideal range for the absorptive refrigerator is 180 - 200f, if you go above 230f it actually looses efficiency and starts to break down the refrigerant.  The plan is start building chips that hit 210 to 250f.

http://web.stanford.edu/group/narratives/classes/08-09/CEE215/ReferenceLibrary/Chillers/AbsorptionChillerGuideline.pdf
http://www.yazakienergy.com/waterfired.htm


No one is saying that absorption refrigeration is not possible.  When I was very young my parents lived off the electrical grid.  We had a refrigerator which ran by burning kerosene.  It used absorptive refrigeration.  The refrigerator was replaced as soon as the electricity grid became available.  

We are just saying it is extremely unlikely to be economic running off bitcoin miners.

With your proposed temperature difference of 50C or even 100F the efficiency will be 5 to 10%. The second law of thermodynamics sets an absolute limit to any heat engine.

Lets be really totally optimistic and assume  you are aiming for a 10% efficiency.  If you output 1,000W of heat from a miner you will get at the most 100W of useful work out and still have to get rid of at least 900 Watts of heat.  I just cannot see it even coming close to making economic sense.

Your web site says you have a "Lead Scientist" so I assume there has been some calculations done on expected energy output, on the overall economics, and on waste heat removal to maintain the 100f difference in temperature.

To repeat.  It is the efficiency and economics we question.  Not whether absorption refrigeration exists.
newbie
Activity: 16
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Any help you guys have on improving the website so people don't immediately jump to 'scam!' would be a great help.  We need people to see the simple elegance of the solution, not worry that its a scam.

To improve your web site so it looks less like a scam site:

1) Redo your "team" page so it looks less like a teenage gamers attempt to be cool.

2) Sort out what distributed/grid computing has to do with anything.  One example from your web site (http://www.3xergy.com/wp/concept/)  

"The concept innovation proposed is an appliance that is designed to generate heat from a silent, self-contained computer processing unit which acts as a node(s) in a larger distributed grid computing network. The appliance will send a portion of the computational needs locally to common devices such as tablets, entertainment / gaming consoles, and personal computing, and a portion of computational needs globally as part of a distributed cloud computing network."  

What on earth does the above mean.  And why do you keep mentioning distributed/grid computing?

As a general comment the sentences on your web site are too long and convoluted.  You need to rewrite it to use simpler and clearer English.

3) Remove all those graphs that seem to have no purpose but to look impressive.  For example what does your device have to do with a graph showing the percentage of people in single dwelling houses.

4) Stop taking in this thread about "absorption cooling" and using "heat to create cold" as if the second law of thermodynamics does not apply to them.  The efficiency of extracting heat energy from a small temperature difference to drive refrigeration is extremely low, 5-10% with say a 50C difference.  It does not matter whether you are generating electricity or driving a refrigerator, the same laws of physics apply to the amount of energy you can extract from a temperature difference.

5) Make more realistic prototypes.  Don't have passive boxes with tubes that go out of the box and then immediately back in again.  At least describe in detail what the parts of the prototype are doing.  Otherwise it just looks like any water cooled PC.  Even better show the prototype actually doing something useful, making ice or steam or whatever.  A cup of coffee would be nice.


**Thanks for the feedback - its good stuff... except for #4.  We're talking about a minimum temperature difference today of > 100f to ambient which is more than enough to run a single or double effect absorber.  Remember, this thing is running at 180 to 200f right now (with off the shelf parts!), that's more than enough TD to regenerate desiccant or run an absorber.  The ideal range for the absorptive refrigerator is 180 - 200f, if you go above 230f it actually looses efficiency and starts to break down the refrigerant.  The plan is start building chips that hit 210 to 250f.

http://web.stanford.edu/group/narratives/classes/08-09/CEE215/ReferenceLibrary/Chillers/AbsorptionChillerGuideline.pdf
http://www.yazakienergy.com/waterfired.htm

full member
Activity: 203
Merit: 100
Any help you guys have on improving the website so people don't immediately jump to 'scam!' would be a great help.  We need people to see the simple elegance of the solution, not worry that its a scam.

To improve your web site so it looks less like a scam site:

1) Redo your "team" page so it looks less like a teenage gamers attempt to be cool.

2) Sort out what distributed/grid computing has to do with anything.  One example from your web site (http://www.3xergy.com/wp/concept/)  

"The concept innovation proposed is an appliance that is designed to generate heat from a silent, self-contained computer processing unit which acts as a node(s) in a larger distributed grid computing network. The appliance will send a portion of the computational needs locally to common devices such as tablets, entertainment / gaming consoles, and personal computing, and a portion of computational needs globally as part of a distributed cloud computing network."  

What on earth does the above mean.  And why do you keep mentioning distributed/grid computing?

As a general comment the sentences on your web site are too long and convoluted.  You need to rewrite it to use simpler and clearer English.

3) Remove all those graphs that seem to have no purpose but to look impressive.  For example what does your device have to do with a graph showing the percentage of people in single dwelling houses.

4) Stop taking in this thread about "absorption cooling" and using "heat to create cold" as if the second law of thermodynamics does not apply to them.  The efficiency of extracting heat energy from a small temperature difference to drive refrigeration is extremely low, 5-10% with say a 50C difference.  It does not matter whether you are generating electricity or driving a refrigerator, the same laws of physics apply to the amount of energy you can extract from a temperature difference.

5) Make more realistic prototypes.  Don't have passive boxes with tubes that go out of the box and then immediately back in again.  At least describe in detail what the parts of the prototype are doing.  Otherwise it just looks like any water cooled PC.  Even better show the prototype actually doing something useful, making ice or steam or whatever.  A cup of coffee would be nice.


hero member
Activity: 784
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Live Stars - Adult Streaming Platform
It is better to rent out your hot mining place for people to have steamy sex than to have your invention.. will not work.  sex will
newbie
Activity: 16
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You can't extract much energy from low-grade heat.  Maximum efficiency = (T2-T1)/T1, where T2 is the temperature of the low-grade heat (exhaust from the computer system), and T1 is the ambient temperature of where you dump the heat.  All temps are absolute (K).  Typical chip surface temps are 60-80C, and 70C is about 343K. If your cold end is a  cool day (say 15C), then T1 is 288K. The maximum energy you can recover from that heat is 19% of the input. That's a theoretical upper limit. Actual heat engines don't do that well.

Systems for absorption-Rankine low-grade heat recovery have been proposed.. At 120C in, 25C out, it might be possible to get 8% efficiency from a practical system. So yes, you can get some energy out, but it's barely worth it.

We're pushing 180f today - 200 is likely next week.  Our intent is not to make low grade heat it is to make high grade heat, primary heat, from computation.  I really appreciate the comments but this has been vetted by folks with advanced degrees and we're partnered with a national lab, guys.  Its not our intent to pull the wool over anyone's eyes~
newbie
Activity: 16
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You can't extract much energy from low-grade heat.  Maximum efficiency = (T2-T1)/T1, where T2 is the temperature of the low-grade heat (exhaust from the computer system), and T1 is the ambient temperature of where you dump the heat.  All temps are absolute (K).  Typical chip surface temps are 60-80C, and 70C is about 343K. If your cold end is a  cool day (say 15C), then T1 is 288K. The maximum energy you can recover from that heat is 19% of the input. That's a theoretical upper limit. Actual heat engines don't do that well.

It is even worse than the above calculation.  The maximum energy that can be extracted between temperatures Thot and Tcold is (Thot - Tcold)/ Thot.  The above equation should be (T2-T1)/T2 rather than (T2-T1)/T1.

For the above example of 70C and 15C the maximum possible efficiency is 16% rather than 19%.  In reality the efficiency is likely to be between 5 and 10%.

Trying to extract any power from a small temperature difference is very inefficient.  Large power stations get better efficiency because the difference between high and low temperatures is around 500C, not 50C.  Power stations need the biggest possible temperature difference - that's why they need cooling water or cooling towers.  


In summary part of the confusion in this thread seems to be because there are 2 very different ways proposed in this thread, and on the 3xergy site, to use the heat.

1)  Simple use the heat as heat.  This is efficient. Simply use the heat from a miner to heat a room or heat water.  This seems to 'first generation' proposed at the www.3xergy.com site and appears to be nothing more than using a miner's excess heating to do space (or water) heating.  There is nothing new or unusual with this proposal.

2) The second way to use the heat is to use the small temperature difference between the miner and a cool point to extract power, for example to generate electricity or to power refrigeration.  As shown above this is very inefficient with small temperature differences.  Extracting power from the heat (temperature difference) and distributing excess heat via the electrical grid, as proposed on the www.3xergy.com site,  is extremely unlikely to be cost effective.  I won't call it a scam but it may be wishful thinking.  It can be done but is rarely worth the effort.  If you want more information see Carnot's principle or the second law of thermodynamics.    


1) is exactly right and very simple

2) is missing the point, were not generating electricity from heat - that is too many energy conversions and way too inefficient to be viable.  We are talking about using heat to create cold so we don't need to use electricity to make cold.  Almost 100% of the energy that goes into a computer makes heat - (if you can point me to some peer reviewed literature that claims otherwise I would love to see it!)  100% of that heat (minus thermal leakage) can be used for other purposes.  Given heating and cooling our spaces are two of the very largest consumers of energy on the planet and that making cold from heat is a very, very well proven from a technology perspective this is a pretty easy thing to do.  The harder thing to do is making enough heat from computation - we're working on that, it is a hurdle we can overcome.  

We're not distributing heat BTW - that is crazy and left for the likes of NYC's district heating plants to do with horrible inefficiency.  We're talking about distributing computation to make heat where it is needed.  Its not a scam or wishful thinking and it falls squarely within the current boundaries of both physics and today's technology.  Its sitting right next to me now, as I type, putting my answers to you on the internet at 180f in the loop.

"Extracting power from the heat (temperature difference) and distributing excess heat via the electrical grid, as proposed on the www.3xergy.com site,  is extremely unlikely to be cost effective."  Boilers used to run chiller plants are used all day every day around the planet to extract energy from heat, most big buildings on the planet are doing it right now.  We are already making the temps these systems typically do - again, with off the shelf parts.  We are not shipping power over the grid.

Any help you guys have on improving the website so people don't immediately jump to 'scam!' would be a great help.  We need people to see the simple elegance of the solution, not worry that its a scam.
newbie
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Quote
How much do you expect a modified refrigerator/air conditioner would cost/save? I really doubt you will recycle enough energy to justify the costs whatever they may be.

**The refrigerators are mass produced today - every RV, most boats and many, many off grid homes already use absorptive refrigeration... it is safe, economical and completely silent.  When you take into account that your refrigerator is the device that runs the most in your house, you'll likely rethink that last statement.  

They don't use heated water do they? I'm assuming there would need to be some modifications to the house/heating elements.

**Its really just adding a water jacket around the generator (where heat makes the chemicals react) and removing all of the propane/natural gas burners.  Its much les costly to heat them with the coolant than gas from a parts perspective so the units should be less expensive at scale.

They pull a TON of juice dude just to keep them going. You know what else they pull juice for (on a separate input?). Cooling. It's constant and it's REALLY expensive. Do I have to get into the principles of thermodynamics for the cooling part on this? As long as we can produce the heat onsite within a certain range (and also depending on the system type), we can cool the stacks without drawing a separate load to do the same thing. Also, the remaining waste heat can be used to heat the building, water tanks, etc.

Please do get into the thermodynamics. I'd love to know how you can cool something using nothing but heat. I'm sure there are also several multi-billion dollar companies wondering the same thing.

Actually several multi billion dollar corporations build absorptive refrigeration plants every single day.  The majority of high rise buildings in every major city use absorptive chiller plants for cooling.  Absorption cooling was invented by the French scientist Ferdinand Carré in 1858 and predates the direct expansion refrigeration systems you are familiar with by a long shot.  We havent developed any new technology (yet) we're using existing technology to do something new and novel.  This really isn't rocket surgery... its more like shade tree mechanics.

How many of those companies building absorption refrigeration plants are using datacenters as a heat source?

**None.  They run them too cold to make the kind of heat you need to run building absorption refrigeration plants.  We aim to change their minds and show them a different way of thinking about heat and computation.

I know the technology is not new but it's not removing the cooling element. You will still need fans+heatsinks (or cooling towers, etc) to cool the water as well as electricity for the two water pumps required.

**We don't need a cooling tower, the heat is consumed in the work - heating water, making cold, etc.  Our idea is to not waste a single therm of heat if possible, its not getting pumped into the air as a waste stream - it is a primary heat stream.  Also, the 'new' parts of this technology actually address some of these very issues, like pumping specifically.

Thanks again - good thinking!  
full member
Activity: 203
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You can't extract much energy from low-grade heat.  Maximum efficiency = (T2-T1)/T1, where T2 is the temperature of the low-grade heat (exhaust from the computer system), and T1 is the ambient temperature of where you dump the heat.  All temps are absolute (K).  Typical chip surface temps are 60-80C, and 70C is about 343K. If your cold end is a  cool day (say 15C), then T1 is 288K. The maximum energy you can recover from that heat is 19% of the input. That's a theoretical upper limit. Actual heat engines don't do that well.

It is even worse than the above calculation.  The maximum energy that can be extracted between temperatures Thot and Tcold is (Thot - Tcold)/ Thot.  The above equation should be (T2-T1)/T2 rather than (T2-T1)/T1.

For the above example of 70C and 15C the maximum possible efficiency is 16% rather than 19%.  In reality the efficiency is likely to be between 5 and 10%.

Trying to extract any power from a small temperature difference is very inefficient.  Large power stations get better efficiency because the difference between high and low temperatures is around 500C, not 50C.  Power stations need the biggest possible temperature difference - that's why they need cooling water or cooling towers.  


In summary part of the confusion in this thread seems to be because there are 2 very different ways proposed in this thread, and on the 3xergy site, to use the heat.

1)  Simple use the heat as heat.  This is efficient. Simply use the heat from a miner to heat a room or heat water.  This seems to 'first generation' proposed at the www.3xergy.com site and appears to be nothing more than using a miner's excess heating to do space (or water) heating.  There is nothing new or unusual with this proposal.

2) The second way to use the heat is to use the small temperature difference between the miner and a cool point to extract power, for example to generate electricity or to power refrigeration.  As shown above this is very inefficient with small temperature differences.  Extracting power from the heat (temperature difference) and distributing excess heat via the electrical grid, as proposed on the www.3xergy.com site,  is extremely unlikely to be cost effective.  I won't call it a scam but it may be wishful thinking.  It can be done but is rarely worth the effort.  If you want more information see Carnot's principle or the second law of thermodynamics.    
legendary
Activity: 1204
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You can't extract much energy from low-grade heat.  Maximum efficiency = (T2-T1)/T1, where T2 is the temperature of the low-grade heat (exhaust from the computer system), and T1 is the ambient temperature of where you dump the heat.  All temps are absolute (K).  Typical chip surface temps are 60-80C, and 70C is about 343K. If your cold end is a  cool day (say 15C), then T1 is 288K. The maximum energy you can recover from that heat is 19% of the input. That's a theoretical upper limit. Actual heat engines don't do that well.

Systems for absorption-Rankine low-grade heat recovery have been proposed.. At 120C in, 25C out, it might be possible to get 8% efficiency from a practical system. So yes, you can get some energy out, but it's barely worth it.
hero member
Activity: 770
Merit: 509
Quote
How much do you expect a modified refrigerator/air conditioner would cost/save? I really doubt you will recycle enough energy to justify the costs whatever they may be.

**The refrigerators are mass produced today - every RV, most boats and many, many off grid homes already use absorptive refrigeration... it is safe, economical and completely silent.  When you take into account that your refrigerator is the device that runs the most in your house, you'll likely rethink that last statement. 

They don't use heated water do they? I'm assuming there would need to be some modifications to the house/heating elements.

They pull a TON of juice dude just to keep them going. You know what else they pull juice for (on a separate input?). Cooling. It's constant and it's REALLY expensive. Do I have to get into the principles of thermodynamics for the cooling part on this? As long as we can produce the heat onsite within a certain range (and also depending on the system type), we can cool the stacks without drawing a separate load to do the same thing. Also, the remaining waste heat can be used to heat the building, water tanks, etc.

Please do get into the thermodynamics. I'd love to know how you can cool something using nothing but heat. I'm sure there are also several multi-billion dollar companies wondering the same thing.

Actually several multi billion dollar corporations build absorptive refrigeration plants every single day.  The majority of high rise buildings in every major city use absorptive chiller plants for cooling.  Absorption cooling was invented by the French scientist Ferdinand Carré in 1858 and predates the direct expansion refrigeration systems you are familiar with by a long shot.  We havent developed any new technology (yet) we're using existing technology to do something new and novel.  This really isn't rocket surgery... its more like shade tree mechanics.

How many of those companies building absorption refrigeration plants are using datacenters as a heat source?

I know the technology is not new but it's not removing the cooling element. You will still need fans+heatsinks (or cooling towers, etc) to cool the water as well as electricity for the two water pumps required.
newbie
Activity: 16
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They pull a TON of juice dude just to keep them going. You know what else they pull juice for (on a separate input?). Cooling. It's constant and it's REALLY expensive. Do I have to get into the principles of thermodynamics for the cooling part on this? As long as we can produce the heat onsite within a certain range (and also depending on the system type), we can cool the stacks without drawing a separate load to do the same thing. Also, the remaining waste heat can be used to heat the building, water tanks, etc.

Please do get into the thermodynamics. I'd love to know how you can cool something using nothing but heat. I'm sure there are also several multi-billion dollar companies wondering the same thing.

Actually several multi billion dollar corporations build absorptive refrigeration plants every single day.  The majority of high rise buildings in every major city use absorptive chiller plants for cooling.  Absorption cooling was invented by the French scientist Ferdinand Carré in 1858 and predates the direct expansion refrigeration systems you are familiar with by a long shot.  We havent developed any new technology (yet) we're using existing technology to do something new and novel.  This really isn't rocket surgery... its more like shade tree mechanics.
newbie
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Hey there, no one is asking you to buy anything and, as a matter of fact, your reaction is exactly what we were hoping to elicit.  This isn't a scam, its a working device that heated my 1100sf apartment over the New York winter while it was mining Doge and folding for Stanford during testing.

This is a scam in the same way solar roadways is a scam. It is a neat idea that doesn't make sense economically.

**Not really.  Its been reviewed by several PhDs - in fact our senior scientist has his doctorate.  There is a very sensible and viable business model to this, I'm sure you can come up with it if you spend a minute or two.

Quote
As for the technical questions, here's a shot: what will it do when the room is heated, it'll heat water for your shower, what will it do when the room and your water is heated, it'll run your refrigerator.  What will it do when your water is heated, your refrigerator is cold and the house is too hot - it'll regenerate (heat) a desiccant air conditioning system and cools the house.  

How much do you expect a modified refrigerator/air conditioner would cost/save? I really doubt you will recycle enough energy to justify the costs whatever they may be.  

**The refrigerators are mass produced today - every RV, most boats and many, many off grid homes already use absorptive refrigeration... it is safe, economical and completely silent.  When you take into account that your refrigerator is the device that runs the most in your house, you'll likely rethink that last statement.  

You might be able to save a few hundred dollars if you heated your water tank for a year using an asic, but your contraption cost would probably negate those savings. Not many people mine for more than a few months and those who do have very low electricity costs which makes recycling pointless.

**The energy you recovered alone would likely reimburse the cost of the system in under 3 years once they are in full production, remember you are using this energy already, we're just talking about using the same energy for two or more purposes - Heating/Cooling/Computation.  If you take into account Moore's law we'll very likely have good reason to replace the units every 3-4 years, as computing gets smaller and more efficient we can pack more and more of it into the same appliance.  I'm really not interested in heating water with ASIC - there is a much more robust business model in selling distributed computation that doesn't rely on a race to the bottom from a technology perspective.

The real savings would come from space heating but you don't need a rube goldberg machine for that.

**The savings can come from far more than space heating - take a look at the website and think about the energy balance of the house.  We will eventually address more than 70% of the load in the average house through space heating, water heating, air conditioning and refrigeration.  You don't have to be rube goldberg to see that.

Quote
The economic model - your a whiz, maybe this will make sense: instead of spending 60% of the energy bill in a data center somewhere cooling the machines think about moving the machines to where there is a need for heat

Ignoring the fact that most modern datacenters use ~10-30% for cooling and that converting all their air cooled hardware to water cooled would cost an obscene amount of money, how do you plan on moving several hundred KW worth of heat from a datacenter to a place that needs it?

**Lets not ignore the fact that 'modern datacenters' make a very, very small portion of the overall population of datacenters which have been around since the 90s at scale.  The vast majority of datacenters are embedded in office buildings and rely on the HVAC system or CRAC units for cooling... you can bet they are not using 10-30% total energy for cooling.

I don't doubt it can be done but I really doubt it can be done cost effectively.

**That's our job to figure out, not yours.


Quote
The cool (figuratively speaking) part is, now you aren't paying an gas/electric bill (or a portion at least) just to heat your house/water/etc

The question is what portion? Have you done calculations on how much electricity you might be able to recycle? I'd love to see a cost/savings breakdown.

**We have - think along the lines of 70%  to start with and then think about how many of the appliances that make up the remaining 30% could be completely obviated if you actually had a house with a super computer built into its core.  We're not there... but we will get there.

Quote
Do you think this might extend the payback of the mining rig a bit when you offset the roughly 3k a year the average residence spends a year to heat or cool water/space in your house?  Do you think it makes even more sense since you are no longer running the AC to cool the miner... like the data centers do 24/7?  There is a pony in there... think it over.  Talk about an absurd idea, sticking a miner in your house and turning on the AC to keep it cool was one of the most absurd ideas of all - yet how many people were doing that last year?

But if 90% of that energy is spent on space heating, why not use a $25 heatsink+fan instead of a $300 rube goldberg machine and another ~$1000 for a modified AC+refrigerator?

**Only 40% at best is used for space heating with another 18% used for water heat.  Of course we'll start there, its the easiest and most cost effective loads to get to in a house!  But, if you are going to purpose build a house around a super computer why exactly wouldn't you install the $1000 refrigerator or the $2000 air conditioner?  Remember, the more you use these computation powered devices the more computation that has to be done in order to create the heat... if we are selling the computation to Cloud Services Aggregators & Brokerages then that makes everyone happy.

Basically you can recycle ~$2700 without modifying your hardware by space heating, or you can spend an extra ~$300 to save $3000(~$300 extra) by incorporating water heating.

If you can do that we have some friends at NREL who would love to have a talk with you.  Remember, computers aren't designed to run hot they are built to be run as cool as practicable (dont worry, NREL couldn't get their heads wrapped around the concept at first and they are ALL engineers and PhDs) and today's computers certainly aren't optimized to get to the 180-200f that we need to do refrigeration or air conditioning. 

Thanks much for the good questions, we need to get prepped for these conversations as we start to roll out the prototypes.

hero member
Activity: 770
Merit: 509
They pull a TON of juice dude just to keep them going. You know what else they pull juice for (on a separate input?). Cooling. It's constant and it's REALLY expensive. Do I have to get into the principles of thermodynamics for the cooling part on this? As long as we can produce the heat onsite within a certain range (and also depending on the system type), we can cool the stacks without drawing a separate load to do the same thing. Also, the remaining waste heat can be used to heat the building, water tanks, etc.

Please do get into the thermodynamics. I'd love to know how you can cool something using nothing but heat. I'm sure there are also several multi-billion dollar companies wondering the same thing.
hero member
Activity: 770
Merit: 509
Hey there, no one is asking you to buy anything and, as a matter of fact, your reaction is exactly what we were hoping to elicit.  This isn't a scam, its a working device that heated my 1100sf apartment over the New York winter while it was mining Doge and folding for Stanford during testing.

This is a scam in the same way solar roadways is a scam. It is a neat idea that doesn't make sense economically.

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As for the technical questions, here's a shot: what will it do when the room is heated, it'll heat water for your shower, what will it do when the room and your water is heated, it'll run your refrigerator.  What will it do when your water is heated, your refrigerator is cold and the house is too hot - it'll regenerate (heat) a desiccant air conditioning system and cools the house.  

How much do you expect a modified refrigerator/air conditioner would cost/save? I really doubt you will recycle enough energy to justify the costs whatever they may be.

You might be able to save a few hundred dollars if you heated your water tank for a year using an asic, but your contraption cost would probably negate those savings. Not many people mine for more than a few months and those who do have very low electricity costs which makes recycling pointless.

The real savings would come from space heating but you don't need a rube goldberg machine for that.

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The economic model - your a whiz, maybe this will make sense: instead of spending 60% of the energy bill in a data center somewhere cooling the machines think about moving the machines to where there is a need for heat

Ignoring the fact that most modern datacenters use ~10-30% for cooling and that converting all their air cooled hardware to water cooled would cost an obscene amount of money, how do you plan on moving several hundred KW worth of heat from a datacenter to a place that needs it?

I don't doubt it can be done but I really doubt it can be done cost effectively.

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The cool (figuratively speaking) part is, now you aren't paying an gas/electric bill (or a portion at least) just to heat your house/water/etc

The question is what portion? Have you done calculations on how much electricity you might be able to recycle? I'd love to see a cost/savings breakdown.

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Do you think this might extend the payback of the mining rig a bit when you offset the roughly 3k a year the average residence spends a year to heat or cool water/space in your house?  Do you think it makes even more sense since you are no longer running the AC to cool the miner... like the data centers do 24/7?  There is a pony in there... think it over.  Talk about an absurd idea, sticking a miner in your house and turning on the AC to keep it cool was one of the most absurd ideas of all - yet how many people were doing that last year?

But if 90% of that energy is spent on space heating, why not use a $25 heatsink+fan instead of a $300 rube goldberg machine and another ~$1000 for a modified AC+refrigerator?

Basically you can recycle ~$2700 without modifying your hardware by space heating, or you can spend an extra ~$300 to save $3000(~$300 extra) by incorporating water heating.
legendary
Activity: 1512
Merit: 1057
SpacePirate.io
This is probably more suited for the Project development board. https://bitcointalk.org/index.php?board=12.0

This is probably more of a solution for a cold climate area that needs these kinds of solutions. It needs to be cheaper than propane though as well as used in an area where electricity is cheap. Running my hot water heater costs $12 a month, so not exactly worth it for me. Interesting concept though, good luck taking it forward.

Oh yeah, watch the fumes coming off of your plastic. Heating plastic can be really and circulating water in it will cause leeching of the chemicals into the water.  Check out this link on how to identify which plastics to avoid:
http://io9.com/how-to-recognize-the-plastics-that-are-hazardous-to-you-461587850

newbie
Activity: 16
Merit: 0
This....is nothing like what we are doing.

Did you visit our site? Or are you knee jerking it?

For one, everything you and your website says is worded like a scam.

For two, this is the most absurd idea I've heard in my life.

This is a rube goldberg machine disguised as a futuristic innovative cooling/heating thingy.

Subtracting all the bullshit and obfuscation this is how I understand your contraption: A watercooling loop delivers heated water to an insulated tank which then goes through a radiator to heat the air when you need it.

What happens when the tank is full of hot water and the cpu needs cool water? Will it shut off the cpu? underclock? heat the room when it's is already heated?

Why would anyone buy this contraption for presumably hundreds of dollars when a $20 cpu+fan does essentially the same thing?


Hey there, no one is asking you to buy anything and, as a matter of fact, your reaction is exactly what we were hoping to elicit.  This isn't a scam, its a working device that heated my 1100sf apartment over the New York winter while it was mining Doge and folding for Stanford during testing.  

As for the technical questions, here's a shot: what will it do when the room is heated, it'll heat water for your shower, what will it do when the room and your water is heated, it'll run your refrigerator.  What will it do when your water is heated, your refrigerator is cold and the house is too hot - it'll regenerate (heat) a desiccant air conditioning system and cools the house.  

The whole point of this test bed is to test.  The current unit makes a solid 180F in the heating loop (today) with off the shelf parts - you are right a 25$ fan is a better idea for cooling... but were not cooling... this thing is built to make heat.  The economic model - your a whiz, maybe this will make sense: instead of spending 60% of the energy bill in a data center somewhere cooling the machines think about moving the machines to where there is a need for heat.  When we do this the heat you needed (wherever that is) is made by computation... not electric resistance heat (the link to the friction heater which is the exact mechanical equivalent of a resistance heater found in most electric water heaters today or the space heater you sit on the floor to keep your feet warm - which is pretty Rube Goldberg if you ask me) not burning gas and not running a compressor to pump the heat from outside your house to the inside of your house or vice versa when cooling.  

The cool (figuratively speaking) part is, now you aren't paying an gas/electric bill (or a portion at least) just to heat your house/water/etc, you are using electricity and computation to make that heat.  And, in a bit coin forum, I would assume you all know that you can make money on the computation that is being created for virtually the same energy spend you were using to heat water/air/etc.  

Do you think this might extend the payback of the mining rig a bit when you offset the roughly 3k a year the average residence spends a year to heat or cool water/space in your house?  Do you think it makes even more sense since you are no longer running the AC to cool the miner... like the data centers do 24/7?  There is a pony in there... think it over.  Talk about an absurd idea, sticking a miner in your house and turning on the AC to keep it cool was one of the most absurd ideas of all - yet how many people were doing that last year?

How do I keep it alive at those temps?  Not only do I keep it alive it runs like a champ at those temps, never misses a beat... well, it took a couple years of development to get it to those temps with off the shelf parts.  Give me a compelling reason and I just might tell.


https://lh4.googleusercontent.com/Vrt-wU3oyExwpz3abH_nTnghoLfnaX3T4IFG66qtfA=w317-h207-p-no
newbie
Activity: 25
Merit: 0
For one: Scams usually ask for stuff ($ mainly). We don't. We're just looking to talk with people. If an investor comes along, we'll talk to them too (we are). So let's settle down on that. If you are someone who doesn't want to give your money, rest assured, we don't want it.

In the coming weeks, we'll be starting a KS campaign to raise money for R&D. Ideally, we'd actually like to crowd source a lot of the R&D particularly as we develop the distributed networking capacity.

Wise of you to go with kickstarter. This is exactly the type of scam they eat up.

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For two: thanks for the feedback. It's why I'm here.

It's a proof of concept: not a product ready for sale, distribution, etc. The question really isn't where do you get more cold water - it's how do make sure the material components heating the water through heat exchange can handle that type of long term stress AND make the thing work over a larger distributed network so when the demand for heat is there, there is data to fire up the components to provide heat.

I'm not sure what concept you are proving or even what you are trying to say. Seems like you're just circumventing the question.

Watercooling is a widely proven technology. You've just added a water tank that stores the hot water and cools it later.

Why not just heat the air by computing when you need heating instead of when you don't? (via a $20 heatsink+fan combo)

Honestly what's the point?

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The concept also has really strong applications with datacenters, but I think that's a different discussion.

Please do share. Preferably without the obfuscation.

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I actually have some good build pics and screen grabs of testing....but I'm at a loss as to how to post pics on here. Lil help? Anyone?

Code:
[img]imageurl.jpg[/img]

I think you are missing a major point, which is probably my fault - The concept is that this (or a future version of something like it that doesn't use water cooling technology) replaces the furnace (separate gas / oil input), water heater tank (separate gas / electrical input), or AC unit (electrical input). All of those things bring in energy for the sole purpose of doing one thing - heating, cooling, whatever. We are talking about having energy coming in to do multiple tasks at once....Combining heating needs and computation. When you couple something like this with say, solar and battery storage technology, it can get real interesting.  The idea is to reduce the number of energy inputs and increase (or at the very least maintain) the productive outputs.

re: data centers:

They pull a TON of juice dude just to keep them going. You know what else they pull juice for (on a separate input?). Cooling. It's constant and it's REALLY expensive. Do I have to get into the principles of thermodynamics for the cooling part on this? As long as we can produce the heat onsite within a certain range (and also depending on the system type), we can cool the stacks without drawing a separate load to do the same thing. Also, the remaining waste heat can be used to heat the building, water tanks, etc.

Stand by on the pics - sorry you have to hold my hand here - do I have to have an image hosting serve?




hero member
Activity: 770
Merit: 509
For one: Scams usually ask for stuff ($ mainly). We don't. We're just looking to talk with people. If an investor comes along, we'll talk to them too (we are). So let's settle down on that. If you are someone who doesn't want to give your money, rest assured, we don't want it.

In the coming weeks, we'll be starting a KS campaign to raise money for R&D. Ideally, we'd actually like to crowd source a lot of the R&D particularly as we develop the distributed networking capacity.

Wise of you to go with kickstarter. This is exactly the type of scam they eat up.

Quote
For two: thanks for the feedback. It's why I'm here.

It's a proof of concept: not a product ready for sale, distribution, etc. The question really isn't where do you get more cold water - it's how do make sure the material components heating the water through heat exchange can handle that type of long term stress AND make the thing work over a larger distributed network so when the demand for heat is there, there is data to fire up the components to provide heat.

I'm not sure what concept you are proving or even what you are trying to say. Seems like you're just circumventing the question.

Watercooling is a widely proven technology. You've just added a water tank that stores the hot water and cools it later.

Why not just heat the air by computing when you need heating instead of when you don't? (via a $20 heatsink+fan combo)

Honestly what's the point?

Quote
The concept also has really strong applications with datacenters, but I think that's a different discussion.

Please do share. Preferably without the obfuscation.

Quote
I actually have some good build pics and screen grabs of testing....but I'm at a loss as to how to post pics on here. Lil help? Anyone?

Code:
[img]imageurl.jpg[/img]
newbie
Activity: 25
Merit: 0
This....is nothing like what we are doing.

Did you visit our site? Or are you knee jerking it?

For one, everything you and your website says is worded like a scam.

For two, this is the most absurd idea I've heard in my life.

This is a rube goldberg machine disguised as a futuristic innovative cooling/heating thingy.

Subtracting all the bullshit and obfuscation this is how I understand your contraption: A watercooling loop delivers heated water to an insulated tank which then goes through a radiator to heat the air when you need it.

What happens when the tank is full of hot water and the cpu needs cool water? Will it shut off the cpu? underclock? heat the room when it's is already heated?

Why would anyone buy this contraption for presumably hundreds of dollars when a $20 cpu+fan does essentially the same thing?


Woooooow. I can feel your affection. ... The love is swelling in you now.

For one: Scams usually ask for stuff ($ mainly). We don't. We're just looking to talk with people. If an investor comes along, we'll talk to them too (we are). So let's settle down on that. If you are someone who doesn't want to give your money, rest assured, we don't want it.

For two: thanks for the feedback. It's why I'm here.

It's a proof of concept: not a product ready for sale, distribution, etc. The question really isn't where do you get more cold water - it's how do make sure the material components heating the water through heat exchange can handle that type of long term stress AND make the thing work over a larger distributed network so when the demand for heat is there, there is data to fire up the components to provide heat.

The concept also has really strong applications with datacenters, but I think that's a different discussion.

I actually have some good build pics and screen grabs of testing....but I'm at a loss as to how to post pics on here. Lil help? Anyone?




hero member
Activity: 770
Merit: 509
This....is nothing like what we are doing.

Did you visit our site? Or are you knee jerking it?

For one, everything you and your website says is worded like a scam.

For two, this is the most absurd idea I've heard in my life.

This is a rube goldberg machine disguised as a futuristic innovative cooling/heating thingy.

Subtracting all the bullshit and obfuscation this is how I understand your contraption: A watercooling loop delivers heated water to an insulated tank which then goes through a radiator to heat the air when you need it.

What happens when the tank is full of hot water and the cpu needs cool water? Will it shut off the cpu? underclock? heat the room when it's is already heated?

Why would anyone buy this contraption for presumably hundreds of dollars when a $20 cpu+fan does essentially the same thing?
newbie
Activity: 25
Merit: 0
This....is nothing like what we are doing.

Did you visit our site? Or are you knee jerking it?
legendary
Activity: 1204
Merit: 1002
We are in a very early R&D phase. Submit a contact form and I'll get you on the list to be notified when the Kickstarter sets off.
This is a dumb idea. Don't send them money. Home Bitcoin mining is dead, killed by increasing difficulty.

It's not even a new dumb idea.  Over 30 years ago, there was the Frenette Friction Furnace, an electric motor driving a brake. This is just the Internet-enabled version of an old scam.
newbie
Activity: 25
Merit: 0
We are in a very early R&D phase. Submit a contact form and I'll get you on the list to be notified when the Kickstarter sets off.
newbie
Activity: 25
Merit: 0
In it's simplest form, yes. Pretty much. The difference being the thermal energy is stored and available for use on demand. Goodbye furnace, AC unit, etc.

There could be some cool applications for gamers as well.
legendary
Activity: 4256
Merit: 8551
'The right to privacy matters'
okay I see the idea. have a bunch of miners cooled by a liquid cooling system.

once a radiator  of coolant reaches a certain temp. it pumps that hot liquid into a thermos. then the heated liquid is used to run a electrical power source.

you use the setup to save on power costs. Has potential but it needs to be fully developed now. Mining is being taken over by large companies in countries like China power subsidies are  already in place.
newbie
Activity: 25
Merit: 0
Hello Bitcoin/Crypto Currency world!
 
First time listener, first time caller...first....timer.  

I'll be as brief as possible. I am a part of a team that has developed a prototype machine that essentially captures, stores, and when necessary, distributes the waste heat generated from high capacity computing. The prototype and the concept is mostly being pushed out over Energy Efficiency related networks. The idea is that the computational load across a larger distributed network essentially becomes the "fuel" to keep the components hot and transferring heat. There's also local computational demand, so theoretically, the device could control anything in your house with a CPU or GPU. Globally, the collective computational power could be tapped by you, or third parties for whatever it's needed for - advanced math, research, whatever.
 
Although we have some members of our team that are mining and active in the crypto currency space, we thought it was time to start engaging the Bitcoin community and the crypto currency community at large as well.
 
In a nutshell, the system is a node in a larger distributed network that is sending high capacity computation back out to the grid for others (maybe you?) to use. In putting that data out to the grid (presumably to similar type machines) the waste heat is locally captured and directed accordingly.
 
While there are a ton of applications for that extra computing power, your community seems to have the greatest immediate use and quite frankly, the most available source of expertise.
 
In the coming weeks, we'll be starting a KS campaign to raise money for R&D. Ideally, we'd actually like to crowd source a lot of the R&D particularly as we develop the distributed networking capacity. There is R&D related to materials as well, but that's wet lab based and will address different issues.
 
www.3xergy.com (pronounced Exergy)
 
Would love your comments, comments and feed back in this thread, but please feel free to reach out directly via the website's contact form.

 
Thank you for your time.
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