O.K. folks, I've actually run some figures, based on internal data in all the link-to PDF files.

Land Cost: This seems to use about 50% of the surface for a two year period, as opposed to a conventional well which uses perhaps 1 acre for a 20 year period. If I were a landowner I'd want 50% of the surface value as a bonus and liquidated damages. Because of the nature of the equipment, this process precludes ranching or farming during the construction and production. The production seems to drain about 10 acres, with 500' spacing in between producing wells and a 100 meter (329 ft) horizontal leg. So land costs are very probably $1,000 per acre in the Gulf Coast, plus brokerage and title opinion, plus clean up-say $15,000 per unit.

Geophysical, Geological and Generation. These are probably very high. 3D is going to be required, and since its novel technology and possibly will require some test holes for coreing, I'm going to put on $1,000,000 per unit

Well cost: According to the East-West article, the wells cost $15,000 per barrel per day or $7,500,000.00 per 2 producer pair. In the lower 48 wells should be much less expensive, around $2,500,000 for a short horizontal well and two air injection wells about 1650' deep and a 328 ft. horizontal with 329 ft leg, an air injection pump and a settling tank for the sand. I'm not an engineer so this is no more than a guestimate. I'd certainly welcome any refinement of these figures.

Well life. The Petrobank Annual Report picture of the combustion process indicates the fire front advances about 10" a day. I don't know how variable that figure is, in other words can the combustion be controlled easily to either speed up or slow the process. At this rate the test reservoir should last 14 months.The next wells planned are for 125 meters.If this is feasible, the wells should last about 18 months.

Infrastructure costs. In Texas the produced water must be reinjected into a formation not productive of oil and gas, or trucked to a disposal well. Pipelines are generally available fairly close, and one pipeline should handle several wells. In Alberta the operators are just dumping the water in a pit, but there is a shortage of pipelines.

Expected production. It's indicated that actual producion is around 600 bopd per producing well, but apparently the costs were figured on a 500 bopd basis, so 1,000 bopd per unit.

Oil Prices. These are variable depending on the quality of the oil produced, and world oil prices. For purposes of estimating payout and net revenue I used $60.00 bbl.

Royalties: These are probably going to average around 25% in the lower 48, and are 1% before pay-out in Alberta,the 25%. In Texas there is a 4.5% State Severance Tax on oil, but there is an exemption of for heavy oil. In Alberta I'm using a 12.5% Royalty figure, and Texas a 25% Royalty.

Operating expenses should be quite high, as with an operation of this complexity I'm estimating 5%. Its going to take a pumper 24/7 and an engineer, plus work crews as needed. The air injection pumps will require fuel, plus the submersible pump in the horizontal leg and the transfer pumps, plus office overhead.

Thickness of net pay to acheive production levels: unclear from published reports, but I'm guessing 40 ft., depending on the depletion level of the sand.

So what kind of rough economics do I figure?

Alberta
well cost $7,500,000
G&G 1,000,000
pipeline and infrastructure, 1,000,000
land costs 15,000
10% fudge factor 915,000

total $10,430,000

Gross Revenue
393 day well life, 1200/bbld 4,711,600 bbl
@ $60/bbl $28,296,000.00
royalties 3,537,000.00
lease operating expenses 1,414,800.00

net to investors........................ 23,345,000.00

so, it looks to me about 2.2 to 1 in a two year period
definitely economic, especially since surface mining does not appear to be commercial at this time

Texas
well cost...... 2,500,000.00
royalties 7,074,000.00
everything else, pretty much the same, so about 2.5:1

I don't understand the statement "the air flow is controlled"... once the air breaks through in the far end of that horizontal... how do you ever shut it in to eliminate the cycling of compressed air.

All that matters in a combustion process is the air to oil ratio.... injected air costs money.

If you had vertical wells, you could simply shut in the one that breaks through and let the combustion advance to the next closest well.

Some of these horizontal well applications are a mystery to me.

FF

I was a reluctant doomer. Been looking for some good news. I'm enjoying my coffee a little more this morning.
And yes, where do I invest?

AntiDoomer,

I am not sure why you take comfort in the thought of increased production from heavy oil. An economy which is constantly striving to increase its short term wealth is sooner or later going to get into trouble with its resource base. If we can leverage heavy oil, tar-sands, and oil shale, along with improved energy efficiency into several more decades of economic growth at the cost of increase carbon emissions is this really a good thing? I understand the temptation to think so as I have succumbed to it myself. Please, Lord, let me have a few more decades of my ‘normal’ life. But in the long (or maybe not so long) run we have to create an economy whose primary purpose is to preserve wealth rather than to constantly increase it. This is not to say that I think scientific and technical progress will come to an end with the end of economic growth. Nor do I think that there will be zero opportunity for wealth increase in the future. It may be that even in the context of an economy which seeks to maintain long term sustainable methods of economic production, opportunities will arise from time to time to increase living standards though increased efficiency. But to make the desire for constant increases in short term output the driving force of our economic system is insanity. In any rational system of economic production developing methods of agricultural production which maintain topsoil and recycle nutrients so that food production is independent of mining finite concentrations of minerals would be a top priority. Such goals are the kindergarten of sustainable economic production and yet they are not even on the radar screen of the current economic system. Clearly a fundamental paradigm shift is needed and not just techno-fixes which will keep the stock market healthy for X-years longer.

I think the doomers say that technology won't "save" us from our energy predicament it might "help" us. There is a difference :)

Consuming 30 billion bbl of oil per year we need all the THAI we can get. Not to mention on going growth in China, India, Russia, Brazil et.. el..

I wonder if there were a Manhattan style project for THAI if we could get 90-100 million bbl per day production? That would be cool.

There are limits to technology, and growth.

memmel, The THAI process requires mobilization of the resource which creates a low pressure sink as the resource vacates into a gravity fed well. This vacating process gives THAI directional control, something that previous fireflooding techniques failed to do. I'm not sure that coal could be mobilized (liquefied) so I'm not confident at all that it could be used for coal.
Don

Here is a link to a company that plans 20,000 BPD production of diesel via Underground Coal Gasification and CTL.

Linc Energy

Their pilot burn was apparently successful and they have access to numerous large, (over 300 million tonnes), stranded coal deposits in Australia.

I'd like to learn more this technology.

Khebab, As far as trusting the company I've found them to under promise and over deliver. Still, I spent many hours researching the process by Googling e.g. "Malcolm Greaves + Toe To Heel Air Injection". The results so far obtained by the company are very similar if not slightly more robust than the many experiments carried out at Bath University in England. I might add that oil is being produced everyday from this process and has been for over a year. That oil is trucked out and delivered to a third party. Whitesands has also been visited by numerous mutual fund managers, one of whom I've known since high school (class of '79) and investment houses. Reports by TD Newcrest, Haywood Securities and FraserMcKenzie verify that the process is in fact working with the sand issue being the only problem so far.

1. What is the range of flow rates expected? can the technology be scale up easily?
2. Can this technology be applied on any type of reservoir? what are the specific constraint on the reservoir features for the technology to be successful?
3. What are the risks? technology success rate.

The original flow rate expected was 630 bpd of upgraded bitumen out of a total of 1000 bpd of fluid. It appears that this number will be higher when the sand knockout vessels are installed which should be soon. Air pressure can then be increased.

Any type of reservoir? Again I would suggest reading Greaves but he does suggest that it will work in a lot of different kinds of reservoirs. THAI needs about 10 or 12 meters to operate which is less than SAGD (only one horizontal instead of two).

The risks. That the sand vessels don't work (extremely unlikely) or that it is not as effective on other reservoirs as Greaves thinks.

Don

I think some of these things will be better known over time. In particular, I thing the range of flow rates will be better known, as more tests are done, and as the process is fine tuned. This is one of the reasons it is hard to ramp up a new technique like this quickly.

Regarding risks, someone working in the oil and gas industry would probably be better able to look at this than Don and I can. One comment I noticed is that "one of the by-products can be free hydrogen, another indication of the very higher temperature". Could this be a problem? Another comment is that carbon monoxide is part of the hot gas mixture. I am not sure what all else are included (besides the obvious ones). The literature seems to indicate that more of the toxic elements are left underground, but there must be some that are discharged.

Two recent sources used for this article that aren't directly from the company are Unleashing the Potential of Heavy Oil Booklet and East-West Energy Chronicle. These feature interviews with a Vice-President from Petrobank, so aren't a whole lot different.

There a several 2002 references given relating to work from the University of Bath. The reason I didn't use these indications as much is they tend to be more optimistic. They were what was hoped for, before any testing was done. For example, the 2002 information cites 80% to 85% expected recovery, where the company's web site cites indicates 70% to 80% expected recovery.

Since THAI is a patented process that one company is working on, it limits what is published from other sources. I have not looked at the patent information shown in the link. Perhaps a Google search would show additional references.

Khebab,

The formation must be at least 30' thick and without shale breaks. I guess its propritary about projected flow rates. I'm also curious as to the area needed for each well and the optimum size of the units, plus the length of the horizontal leg. I'm going to guess and say that it can't cross very big faults, as the displacement would have a big effect in the location of the horizontal leg in the formation.

Thee sand problem might be handled with a gravel pack or some type of custom designed liner, they weren't specific enough to guess, probably on purpose. And , every oil sand is different and every grade of crude. As I'm sure you know, this will probably have to be redesigned for each field, a whole lot of engineering. Depth should'nt matter much, but its probably not suitable for wells less than 500' deep.

This is a very exciting idea and process. If the figures are right, then its going to make the Alberta sands commercial, plus tertiary development on a gang of old Texas fields, and maybe other parts of the world too.The original production probably got less than 10% of the original oil in place

I'm wondering if the figures include the 3D seismic imaging and test bore holes to see if the prospect is right, it strikes me that you'd need a continuous core through the sand.These are not going to be cheap projects, and its very likely to take 10 years or more to bring much oil online. And there's one really major figure to remember-the United States has never produced more than 10 million barrels of oil per day, we currently use 21 mbopd. Its hard for me to believe that we can ever produce even half as much oil as we produced then by tertiary methods, and this oil is likely to be oil that requires at least a $40/bbl price in constant dollars to break even. The era of cheap oil is over, and we're going to conserve and switch to other transportation modes before this provides much help. Those Hummers are going to be antique and classic cars. I expect the cornucopians are going to hype this as the ultimate solution and saviour of the car cuture and continous growth. And that's very doubtful Bob Ebersole

SontagC, No, THAI will not work on shale oil (kerogen) as it is held essentially in rock. Therefore, no mobilization can occur.

Don

Kerogen is the material in oil shale (think Colorado) and bitumen is the material in the tar sands (now referred to as oil sands). Less than half of the oil sands are close enough to the surfce to be mined for processing into oil.

IS it april 1st?

Can't the heavy ... but unlike Alberta, warm & mobile ... bitumen in the KEY heavy oil source, Venezuela, be lifted by simple screw pumps?

They have so much bitumen there that they might not bother with any form of more efficient technology .. at least initially.

Nate, I don't think the flow rates are affected by the API and for sure no "tinkering" could be done to the API grades in situ.

The energy return should be much higher since much less goes in than other approaches. The real elegance is that the fuel for the combustion (coke) and the upgrading is already present in the reservoir. It's also the part that no one wants at the surface. About 10% of the oil is used to fuel the combustion.

Greaves and Petrobank believe the technology can be used all over the world in many types of reservoirs. The scalability will be much higher than existing technologies because it is much simpler and less costly to implement.

Don

Regarding energy return, I think this is one place classical energy return calculations are a little misleading. You certainly want to know how much natural gas is burned, and also how much other energy inputs are used at the surface. The underground oil turned to coke I'm not so sure should be handled in the same way. Burning underground coke is problematic from a CO2 emissions standpoint, but it is not very valuable to society for any other purpose than THAI. So including it in the equation provides the kind of distortion that critics of EROEI who say there are differences in types of energy are concerned about.

One point I noticed in some of Greaves' work was a statement about possibly harvesting energy from the process:

The process also generates power station amounts of energy in the reservoir. If recovered, it could provide most of the energy to run upstream operations and surface facilities, and contribute towards creating a sustainable IOR process.

I'm not quite sure what he had in mind. If this worked, it would seem to improve the EROEI of the process.

They were frozen on the yahoo site as of August 10th. I will check on them and try to get them back.

http://finance.yahoo.com/q?s=CLV07.NYM

They're still frozen...amazing.

redcoltken, The US has heavy oil but not nearly as much as Canada or Venezuela or Russia.

The Board has adopted the estimates of the Alberta and Energy Utilities Board and, according to it; the ultimate volume of crude bitumen in place is estimated to be approximately 260 billion cubic meters (1.6 trillion barrels).
National Energy Board

How much of that oil THAI can extract I do not know but present technologies are supposedly able to extract 178 billion barrels of bitumen. I believe THAI could add to that number significantly.

Don

A quick calculation:
About 67 billion m³ (Athabasca deposits only) are accessible with SAGD technology (recovery factor: 40-60%). A first guess, is that the THAI process has the same resource base. So the URR could increase between 20% and 100%. Assuming 6.3 barrels per m³ of bitumen, we could get an URR increase between 80 Gb and 130 Gb.

Petronbank listed some technology sharing agreements, am not sure what is being shared. The patent on THAI was recorded in 1990. Canada has a 17 year patent period.

There was something about fire flood being used in the Dakotas:

http://www.state.sd.us/denr/DES/Mining/Oil&Gas/Charts/Buffalo.gif

and in this article:

http://www.eandpnet.com/area/exp/520.htm

There are numerous fire flood patents

http://www.freepatentsonline.com/4241790.html

Yes, but a portion of the CO2 will ultimately go into solution in the heavy oil which would serve to make that oil more mobile. [CO2 flooding is a proven enhanced oil recovery technique.] I do not know on balance if CO2 is part of the problem or part of the solution when assessing the viability of this technology.

Euan, After reading your work on Ghawar I'll not pretend to be able to answer the types of questions you need answers for but I will include Petrobank's application to the Alberta Energy and Utilities Board and Alberta Environment. It is about 40 megabytes. I will also add that when I first came across this technology (Thank you WKO) I was skeptical too but the more I investigated the more I believed that THAI would work and it is working. As for the toxic substances underground I think the EUB application http://www.petrobank.com/webdocs/whitesands/whitesands_application.pdf
will help you more than I can.

Don

This places the citizens of Alberta (and Canada) into an unenvious position when it comes to deciding the energy fate of North America. A popular revolt based upon the amount of money it would take to pipe in fresh water to Alberta may delay rapid expansion.

I am glad its the citizens of Canada who get to decide this one.

Euan,

You have a good point about what would be left behind, and where it would go. I certainly have not looked at the big environmental application. Having the "bad stuff" underground sounds at least like a step in the right direction. It is better than in the air or in open ponds.

One of the issues we have in all of these discussions is that we live in a finite world. As we use more and more of the resources, we have more and more pollution problems. I could imagine a scenario where Canada decides to produce only the oil it needs itself, or some slightly larger amount, because of pollution problems. Tough luck if other folks want to buy the oil. They can produce it in their own back yard, and live with their own pollution problems.

Hi Ignorant, The CO2 gases are co-produced and separated at the surface. There has been discussion of eventually re-injecting the CO2 back into the reservoir.

Don

Well antidoomer, My belief is that THAI could be ramped up considerably but it will take a massive, coordinated effort on the part of other oil companies to implement THAI as soon as they are comfortable that it is a legitimate and sustainable technology that can operated profitably. They also must forego the "not invented here mindset" so prevalent in older industries. This will take time. As to the total bpd I don't know but there is a lot of oil in the tar sands and there are lot of heavy oil assets on the planet. My guess is that if pursued diligently, THAI could very well change the nature of the down slope in production. In other words, we could perhaps see oil production decline at much lower rates using THAI than would otherwise have been possible. This would greatly assist society transitioning into a sustainable economic future if indeed that state is even possible.

Don

Hi peter, I do not know the EROEI of the process. But even to a layman such as myself it would seem to be higher, perhaps significantly so, than existing technology. Petrobank has talked of US$8 to $9 lifting cost per barrel if that is any help to you. As a comparison, SAGD requires anywhere from 1000 to 1400 cu ft of nat. gas per barrel for steam heating. With near term gas at US$7.50 a thousand cu ft you can see how much more efficient THAI is in just this one area.
Don

What is called Arabian Heavy crude isn't actually that heavy by world standards - close to 30 api from memory, and getting it to flow through the fabulous Cretacous sandstones reservoirs it is hosted in is not a problem. The high Sulphur content is a problem creating refining / marketability issues.

The Ghawar tar mat is another issue. This is a massive bitumen layer along the E (?) boundary of the field.

Once you light a fire it has a life of its own.

Bitteroldcoot, I most respectfully disagree. Please read my explanation as to why previous fire flooding is fundamentally different from THAI. It was added by Gail soon after the article was posted. I also suggest that you peruse the links provided carefully before comparing this process to prior in situ combustion failure. It really is quite fascinating and worth the effort.

Don

These are the important questions - what is the cost, in energy, economic and environmental terms, to keeping liquid fuels as center of society. Is this cost greater or less than changing infrastructure? My fear is it is much greater, but if energy and environment are removed from the equation, then it will still appear cheaper.

(Note: Im an agnostic on THAI - because I know very little about it.)

Hi ace, No, THAI is not new. In fact that was one of the factors that I found so encouraging. It had to go through a lot of insightful questioning and testing before it got to the pilot stage. As far as other majors not using THAI they would have seek permission from Petrobank first. As to why they didn't buy it petrobank's answer is

Q : Why is Petrobank the first to try to apply this technology?

A : Petrobank recognized early that THAI™ could be substantially more economical than SAGD because it uses single horizontal wells, does not recycle water and did not depend on low gas prices, and so it acquired the patents to the technology. Unlike larger companies, Petrobank has no sunken investment in SAGD. New technologies are often pioneered by small or medium- sized companies.

http://www.petrobank.com/hea-faq.html
As an investor by trade, I understand this implicitly. Big companies are not often good innovators. They are not entrepreneurial either. Too many vested interests and too much bureaucracy stifles THAI like potential not to mention "not invented here syndrome".
But you're right, Petrobank has a conflict of interest which is why I included so many other academic links. And I still hold to decades of investment experience that tells me that if THAI was unlikely to succeed it would be apparent now to the "smart money". Of course smart money can be wrong too whereupon it becomes "new money" otherwise known as "old money that got away". I do not mean to be flippant. It is of course possible that environmental concerns will overwhelm the technology. There is however, no evidence so far that that is the case. The fact that Petrobank is producing near industrial grade water is encouraging. So, I too remain hopeful.

Even if injecting enriched air causes a significant increase to recovery rates, would the cost of using enriched air be so high that the business model, using THAI, is no longer economically viable?

First of all I'm not sure but believe that Petrobank is using oxygen or partially enriched air to fuel the process.

Different Types of Air Separation Processes for Different Applications

The various separation technologies that produce commercially useful products from air are based on differences in boiling points (cryogenic distillation) or on differences in molecular weights, molecular size and other properties (non-cryogenic separation processes)

Non-cryogenic plants are less energy efficient than cryogenic plants (for comparable product purity) but may cost less to build, in particular when the required production rate is relatively small. They are most suitable when high purity product is not required by end-use applications, and when product is not needed full time.

Non-cryogenic processes employ membranes or adsorbents (PSA/ VPSA) to remove the unwanted components of air. They produce oxygen which is typically 90 to 95% pure, or nitrogen which is typically 95 to 99.5% free of oxygen.

At high production rates, cryogenic processes are the most cost-effective choice. Cryogenic processes can produce very pure end products; and must be used to produce liquid nitrogen, oxygen and argon.

Within each technology family - cryogenic and non-cryogenic - there are numerous choices which can be made regarding the specifics of process design, machinery configuration and system control which have capital cost / energy cost / and operational flexibility / plant reliability tradeoffs to define and build the most suitable overall supply system for a specific application.

http://www.uigi.com/compair.html
Now, will this possible cryogenic or non-cryogenic air separation process overwhelm the cost structure? I do not know. Others more versed in this area will hopefully comment but I sincerely doubt that the cost to produce oxygen on site is a deal breaker. The rest of the economic metrics are so favorable to THAI that when I originally came across this issue I did not see it as a major concern. Hopefully this is correct. Thanks for the good questions.

Don

Thanks for all your work and insights!

This analysis is really only a first cut. If there are scientific papers, applications of various kinds, and other documents which shed more light on THAI, we certainly should dig deeper. If you have time to look at these and do a post, it would be great.

The oil sands industry has had too much hype - up to 315 billion barrels of reserves!

Western Canada is becoming an environmental disaster due to unregulated expansion of oil sands production.

Acid rain threatens Western Canada, government warned
http://www.canada.com/topics/news/national/story.html?id=7d3f260b-f135-4...

http://www.worldchanging.com/archives/007166.html

Join the Sierra Club of Canada in our call for a moratorium on new developments in Alberta's tar sands
http://www.tarsandstimeout.ca/

http://www.aenweb.ca/taxonomy/term/52

I wouldn't be surprised if government places an upper ceiling on oil sands production, say 1.5 mbd or 2 mbd, until all environmental impacts are addressed and fully understood.

Does anyone know what Hasbenaro Resources has done with their project using Thai or a very similar method. I first heard about it over a year ago. Field test were done and supposed to be released this spring or very early summer.I have not heard anything and can see no word on their site other than a referece to THAI,

Petrobank-- WHITESANDS

Has an estimated 1.6 billion barrels of bitumen in place. Recently completed an 87,750,000 dollar financing. Testing the THAI (tm) (Toe-to-Heel Air Injection) patented technology on this prospect that may revolutionize current oil sands recovery methods.

Does Habenaro have part or all of this? If this is the same project I heard of I am confused as to why I see no results for those test that were to be released this last spring.

I have a few hundred speculative shares in Habenaro that have lost 2/3 of their value since last year, so wonder if this new method is new or just a rehash of something that has so far failed. Maybe it's all part of the game and Habenaro has passed the ball to Petrobank... Companies win and Speculators lose.;)

They'll list there eventually, but overcoming millions of dollars in Sarbanes-Oxley expenses is a real barrier to smaller companies. Considering the state of the markets, perhaps your decision will work out for the better anyway.

Don

Hi mkwin, Greaves thinks THAI can work in many different reservoirs and even depleted wells. In fact, THAI was designed to work in the North Sea as a secondary extraction method. Heavy oil assts are plentiful on the planet so I think it could have an impact. How big and how fast that impact can be ramped up is the question. Yes, THAI upgrades the oil in situ but nowhere near WTI levels. Refiners will have no choice but to modify their operations so as to handle heavier grades of crude because the world is rapidly running out of the sweet, light grades.

Don