Secret Tunnel/Garage Update #4

Well i'm Surprised, Pleased and comforted by that discovery. What do you think, is it what you expected?

I’m a bridge engineer. We use uncoated structural steel all the time for weathering steel superstructures and driven steel piles. Depending on the environment (coastal areas, corrosive soils, etc.), you can count on a certain thickness of section loss. However, as long as the steel isn’t disturbed, the outer layer of rust will protect the material beneath. Because you’ve encased all your steel in concrete, you’ve got nothing to worry about.

I suspect the plastic sheet is acting as a kind of humidity trap for moisture, particularly when you consider the heat differential between the cool metal and the dirt/earth. The concrete likely does a better job of sealing against the metal, preventing moisture from entering underground. I'm all for this.

I've been working in concrete technology for the past 18 years. I have always been a fan of keeping things simple. Don't bother with the plastic sheeting, just order a concrete with a cement content at or above 400kgs per M3. Make certain you order one of the following cement types. CIIB-V+SR PFA blend or a CIIIA a ggbs blend. This will help control the temperature that is generated by the curing concrete. The high cement/cement replacement content will stop water even getting to the steel. If your still concerned about rusting you can always go with a waterproof concrete, this is more expensive but it's easy. Things to be aware of. Try and get proper compaction, avoid cold joints in the concrete where possible and don't be tempted to wet the concrete up on site. If you want it to flow just order an S4 so you don't change the water cement ratio by adding water on site. Good luck

Fellow engineer here and newcomer to this 2nd channel - This is fantastic! On the front of rust control, put the steel directly in contact with the concrete and have the moisture barrier agsinst the dirt. Your conclusion about alkilinity and rust corrosion is 100% correct!

I'm a structural steel detailer, I make the drawings that steel fabricators use. We always make sure to note the areas that are in contact with concrete to not be painted. The reason is that when the paint gets scratched water will get through the crack and stay trapped there, causing it to rust faster. Plastic traps water as well, which will lead to more rust over time.
With no coating the water will run right off the steel and through the concrete. That and the chemical reaction you mentioned protects the steel surprisingly well.

Hello Colin, fellow engineer here. I would pour the concrete right on top of the steel. Rebar reinforcements are also poured into concrete without any protection, it is the concrete that seals the metal from oxygen and stops further corrosion. There will be some water content present in the concrete for some time, but it will dry and harden over time (even submerged in water!) In big civil engineering structures they usually inspect the concrete for cracks, as these can lead to water ingress. So I would be more worried about the concrete cracking over time then the steel corroding from the inside.

Hi mate, if you speak to your local concrete supplier ask them about concrete additives they can add to your batch. You can get a totally waterproof concrete mix that they use in construction on projects that are affected by water like bridges, foundations to protect the reinforcement. This may solve the problem at a much lower cost. They should have brochures with typical ranges of different mixes to help you choose the right one👍

I'm a constructions expert and I've been working with steel for about 6000 years. When building the pyramids we ran into some weathering issues when it started raining frogs, but if you stay clear of god's wrath you should be in the clear. Hope that helps.

Hi Colin, I’m a civil engineer. If you are going to use plastic it’s better to put it between the concrete and the soil than between the concrete and the steel.
If you put the plastic between the steel and concrete it will essentially trap moisture between the two which will marginally accelerate rusting.
If it’s between the concrete and the soil it will prevent water from getting to the concrete and seeping in through any cracks that you won’t be able to see.
In other words the ideal solution would be to line the hole with the plastic before pouring the concrete in but it should be fine if you didn’t
Alternatively you could use the more expensive option and use hydrophobic concrete

Hey Colin, I'm in a non-profit association, which restores old Fortresses and bunkers from before WW1. Some of them are rearmed in WW1 and/or WW2 with corrugated iron sheeting.
We were facing a similar problem, because parts of the sheeting was directly exposed to dirt. Thus the restauration requires as minimal change as possible because of it's historical protection, we decided to cover the entire sheeting with bitumen. Now, 10 years later there is still no rust on the outer side.
Also we discovered a bunker from the early WW2 which was covered in bitumen initially. There where only two or three spots of rust, after the farmer who found the bunker hits it with his plow.

I'm a NDT engineer (non destructive testing) and you can get a ultrasonic wall thickness measurement set for not to much money with which you can always check for corrosion on your backwall. The wall thickness itself is a give away as well. Asume you measure around 4.1 for new steel (factory over thickness). But you can also see if a backwall is corroded on your echoes (asuming you pick a ultrasonic wall thickness set that shows you echo's and not just a number. Love the channel!!!

Structural engineer here, if you use a moisture barrier, it is best to attach it to the earth side of the concrete so that the water is never going to interact with the concert. If you want to use a sacrificial anode, it is pretty easy to install. You basically just attach it to the steel wall and power. Cost a couple of bucks a year to operate, but not much. But in general you can say that 1mm of Steal can hold about 10 years of normal rust activity, so in your case potentially more.
The garage interior however is a different story as it will be exposed to way more water and salt. There you should probably put a coating of some sort on.

Structural engineer here, its recommended to use the vapor barrier sheets on the dirt side, so you would put up the sheets against the earth , the concrete goes in between it and the tunnel steel. Great project!

As the wet concrete cured, it created heat. From that heat, condensation built up underneath the plastic sheeting. The concrete fully cured, trapping the condensation indefinitely. The trapped moisture is accelerating the rusting process. Which is why you have less rust in the lower test hole, as it is not covered by plastic sheeting. Great job Mr Colin, great work ;))

Hi Colin, dam and tunnel engineer here - As others have said (so I wont go into too much detail) and you stated, the concrete will protect the steel due to passivation. Providing the concrete doesnt crack you will not have an problems. Looking at the ground conditions, you are basing your structure on rock and so teh chance of deformation is low, reducing the possibilities of cracking plus you seem to have compacted the concrete properly during construction. However, you may still encounter shrinkage cracks over time. I do not know your mix ratios supplied by the batching plant, so can not comment on the longevity of the concrete. Dont use the plastic sheet, you want steel to concrete connection for a number of reasons but this is a difficult format in which to explain why. For the interior, if you want to keep it mill scale just spray oil and wipe down. I presume that you are using a humidifier in the tunnels?

Hi Colin, as a structural engineer with a background in advanced concrete applications (all be it in blast applications & not underground tunnels!) I can provide some advice here:
- Ditch the plastic sheet, all this will do is trap moisture between the steel & concrete (especially during curing) which will go on to promote rust.
- Concrete is great at protecting steel from rusting, and time should be spent to perfect the mix design to yield the best protection results for your steel. Things to consider:
1) Cement quantity - more cement typically results in a denser concrete matrix & one with a higher pH (more calcium hydroxide aka CH). Moisture ingress will thus be more difficult & ions that would otherwise react with the iron in your steel (i.e. rust) are more likely to be neutralised by the CH (passivating layer of the concrete).
2) Cement additives - certain additions will bolster the passivating layer (produce more CH to protect your steel from rust) while others will subtract from it so choose wisely (e.g. choose a cement with a higher pH).
3) Proportion of fines & aggregate size - a finer matrix will typically be more dense and again prevent moisture and harmful ion ingress.
4) Water content/use of plastericisers - these can be added to the mix to greatly improve workability while reducing need for water (lower water/cement ratios will again yield a denser matrix).
- With regards to the science of it all that you touched on, concrete is natually alkaline due to the presence of calcium hydroxide (CH) in the concrete matrix which is a cement hydration product. This is what we refer to as the passivating layer which is depleted over the lifetime of the concrete due to actions such as carbonation and acid attack (both promoted by water ingress). Once harmful ions deplete this protection barrier, rust will begin to occur - rust is primarily a worry in reinforced structures as steel expands when it rusts at a much greater rate than the surrounding concrete and thus the concrete cracks.
Hope the above points help.

I worked offshore for 15 years in the salty North Sea and I can honestly say painting Blue Steel Rust Convertor is the best thing ever for putting on bare steel. Looks like milk and so easy to put on using a roller brush and wont change the colour of the steel much. The steel will outlast you I promise you!

I think you've actually chosen quite a good steel for this project, especially combined with it all being buried in thick concrete. You may want to look into more aggressive rust prevention for the garage interior though as that's going to be exposed to far more outside air, salt, and moisture than your other entrances

8 years ago u done the bunker. Time flys ❤❤🎉🎉

I would put the poly on the out side of the concrete to separate that and the ground soil. That is what you do when digging out and pouring concrete for a garage floor or basement. You lay poly down over the dirt then pour your concrete over it. In your case you want the reverse. You pour your concrete and then lay the poly then backfill. That should give you the best protection, and the least amount of moisture to seep into the concrete.

Greetings from Phoenix, Arizona! I have over 30 years experience in the construction trades. The plastic sheet is a vapor barrier, and it should be placed against the moisture trying to get in, i.e. the dirt. If it was my bunker/garage, I would be putting the vapor barrier against the dirt, then pouring the concrete in. You could easily accomplish that beforehand, with a very slim chance of actually getting it so hot that it melts from welding. The fact that you have no surface rust on your previously built sections, really tells the tale. I can’t wait to see when the garage is finished! :-)

The polyethylene sheet is definitely holding moisture against the steel. Here in Florida, we don't use moisture barriers in our walls like the rest of the country does, because it will trap moisture and cause mold.
If you want a consult, Grady at Practical Engineering would probably be happy to lend some Civvie Knowledge about rust. He even already has a video on it.

I have a degree in building construction technology.
The reason having a moisture barrier like a sheet over the metal is worse is that you are trapping any moisture between 2 impervious surfaces leaving water contact with your metal. If you were going to go that road you would want to use some sort of spray liner or closed cell foam around your metal so that it bonds to the metal and there is no room for moisture to contact the metal.
Unfortunately I can not speak intelligently about the PH interaction by contact of concrete but I feel like the PH of the moisture itself that gets into contact with the metal is what matters more. Keep in mind that concrete (unless its specially engineered to be) is not impervious and water does move through it at a very slow rate.
To the point though, With the rate of rust you are seeing over 8 years in your climate zone I wouldn't even bother addressing it.

The electrode thing is a good idea.

Definitely get an ultrasonic thickness gauge. You can non-destructively test the thickness anywhere you want. I use one daily at work. You could even get in a local UT NDT inspector to come by. I'm sure they'd love it!

I'd love to see a window out onto the limestone rocks with a light in it in one of the walls! I think it would be a nice funny addition! :D

G’day Colin, I’m a builder in Australia. We use a product called xypex which is an additive for concrete that makes it pretty much water tight. As I understand it, it’s a salt of some sort that expands when in contact with moisture and seals any micro cracks in the concrete… might be a bit of extra insurance…

Ship builder here (cruise ships!)
Floating dry docks use a hard coating as they are designed to be in water for 50+ years, but overkill for this, as is any sort of plating such as nickel or zinc. The polythene barrier used on the bunker may accelerate the corrosion by preventing moisture from escaping. Long and short is that concrete is porous, therefore moisture will get through! An impressed current cathodic protection system will help, but you will need multiple grounding rods around the tunnel and some aluminium or zinc anodes on the outer shell (which you can get to to replace) and a system to control to the current balance (again, overkill).
Cheap and easy is an oil based coating with some minor oxidation ("flash rust") before applying. This will slow to a near stop any further oxidation, but will eventually disappear through the porous concrete. Other ways is to use an additive to the concrete to reduce its porosity.
Either way, you will be dead before you have any issues.

Has it already been 8 years since I followed this bunker build? Man time flies...

Hi Colin, structural engineer here. Ditch the polythene. Because the joints are not waterproof it will trap moisture between the concrete and the steel. You have the proof of this as the bottom hole show no signs of rust. If you want better protection, you could decide to use a better concrete mix, a formula that resist better to salts and/or admixtures designed to reduce cracking. Or, if the frost depth in winter is a couple a feet (5-6 feet here in Montreal), you could use air-entrained concrete (the micro bubbles leaves space for the water to froze, thus reducing cracking). I love to see that you are thinking about the longevity of your tunnel!! Congrats!

Hey Colin,
i think the best way to deal with this situation is, to "cover" the soil walls itself with the polythene and create some kind of "pool" for the concrete. The steel gets covered directly in concrete, but the concrete itself is also protected from the moisture inside the soil and can´t soak in the water.
In germany the baseplate (groundplate) of most houses without basements are build that way.
Sorry, english is not my native language.

Keep in mind that the garage is going to have exposure to the elements through the car lift and having a potentially very wet car inside of it. Might need to have extra strong moisture extraction methods!

Colin, don’t worry, we‘ll be here watching you patching the steel in 40 years!

Structural engineer here! Commonly used in the baltics is bitumen on the outside of the steel before concrete or dirt. Recently oversaw excavated underground transformer housing for military installation from the 60s to extend it again for water pump. It was dug, metal struts installed, steel panneling boxed, bottom 10% concreted and the rest just soil and mud compacted down. The oustide and inside of the steel painted with bitumen. The only parts that rusted out were the parts that were later extended in the 80s and it was just concreted around shoddily. Sections of the metal were sent off for spectral analysis from both eras and they were exactly the same Soviet composition yet massively different outcomes. I had a younger engineer working along side us for his phd and that data will be available in 2024. The exact methods of original construction werent documented but would recommend laying your steel out on a hot day, blowtourching the steel to open its pours and apply a thinned layer of bitumen primer (steel should be colder than the flash point of the bitumen primer 😂)

Above the under ground garage, when it is finished, where will rain water go? Normally rain water settles through your grass/dirt. If you are getting rid of the dirt below, and you put plastic and concrete where water would normally settle… your front driveway area (above ground) might turn into a “bog” (very wet area) until water can drain off. So you may want to put a slight slope to the roof of your under ground garage but do it in the direction you want the water to drain to (i.e. you don’t want the water to drain toward your house). You might want to consider making concrete drain tunnels that allow the water to go from ground level to below your metal floor. That way the water can still settle into the earth and off your under ground garage roof. Your bunker didn’t have this problem because your lawn is slightly sloped away from the house. Water naturally drains behind your fence or just into the surrounding dirt/earth. That’s my thoughts. Great work, keep it up! From Florida, USA

giggity 8:17 😂 i can't hahaha

Colin, you should put a window in the wall somewhere that looks out into the rockface. the rock fae looks so cool and it's all covered up!

Hi Colin. I'm an engineer specialising in silos, including reinforced concrete ones. Simple answer - LEAVE OUT THE PLASTIC FOR BEST PROTECTION!
The key, as you said at the outset, is in the chemistry. Steel does not go rusty in an alkaline environment. So as long as the concrete is touching the steel, no rusting will occur. Even when the concrete is buried in the ground below the water table (not in dry rock like you are) the presence of the cement against the steel will protect it. In especially severe environments, like submerged in seawater, you would have to ensure you had a sufficient thickness of concrete to step chlorides permeating through to the steel (a few inches). Without it you can get "concrete cancer" due to the rebar rusting and blowing out the concrete - old bridges, silos etc often need repair if there was not enough coverage of the rebar. The other reason for concrete cancer is the concrete cracking and letting excessive water through to the rebar. This occurs when the concrete flexes and cracks, which is a natural thing for reinforced concrete under tension (eg the bottom of beams). Nowadays we used post-tensioned reinforcements to make sure the concrete is always in compression. However, flexing is unlikely in your case because the concrete is under absolutely minimal load. In addition, your environment is very friendly towards steel - the limestone itself is alkaline, so even any water seeping through the normally dry limestone will also be alkaline, so there is very little danger of rust.
The really important thing is to have the cement touching the steel. DO NOT put plastic in as it can seal in moisture between plastic and steel and actually prevent the alkalinity of the concrete doing its anti-corrosion job. Rebar is never coated! Always provided with a rusty finish and as long as there is enough coverage of concrete and no cracking, rusting is not a problem.
NO PLASIC PLEASE!
Mike

Sacrificial anodes are easy to install. Connect one wire to whatever and leave the anode in moist soil.
I used to build cell tower foundations with bare steel I-beams encased in concrete for the guy anchors. These anchors were often in swampy soil. Sacrificial anodes kept the rust away.
They are also used on earthworks equipment here in Canada and work great.

Nothing better than a Colin furze tunnel video ❤

This video and some comments reminded me of another concern for underground bunkers:
Radon Gas!
The UK Radon map shows your area as having high concentrations, so you will probably want to consider Radon ventilation in the new larger areas. A few simple steps can make a big difference!

Red oxide paint before concreting would probably be the most helpful... I put up a hand made chimney cover 15 years ago for my next door neighbour which was just welded sheet steel painted with red oxide. I can see it from my hallway window and it's not rusted even though the paint seems to be wearing off from the weather.
... and it's slow and heavy for cutting steel Colin! not "hyper speed" you'll melt everything. lol

Love the giggidy you snook in there 😂😂😂😂

Architect here. Who lives above a WW2 bomb shelter. So 80 something years old. The steel beams in the structure arenow completely rusted though but the 400-500mm thick concrete is still holding the house above it up. I'm sure your structure will see you out ! Love your work #keeptunnelling

I've been a welder for over 20 years and made various things but when I used to make silos or storage tanks which went underground of forecourts and petrol stations we used to coat the cradles they sat on with red oxide paint,when they were dug up to be replaced or serviced 15-20 years later the cradles were rust free...In short I think painting the side the concrete is being poured onto with red oxide paint 1st would be a great protective barrier...great content as usual 👍

Holesaw trick: After drilling the centre hole (and JUST marking out the main hole), drill another hole at the edge of the main hole. This will improve the cutting efficiency tenfold as the chips have a way to leave the groove of the main hole.

You could use the Xypex admix product mixed into the concrete as a waterproofing, done in below grade tunnel building applications all the time.

I make below grade waterproofing products. Try to avoid the plastic liner if it isn’t adhered (without gaps) to the steel as it will trap moisture in once it finds its way in.
Paint is always great for steel. Consider a solvent based coating to prevent rust and mineral degradation.
You can also prime the metal, put a polymer modified cement on it, add a water based acrylic membrane, and then the concrete. That would be bullet proof.
Feel free to reach out if you have any technical questions. Family has been doing this sort of thing for over 40 years. CHEERS!

Sacrificial anodes are the easiest thing to test and know whats going on with the steel once it's been in the ground for years. I spent 5 years working on cell towers using these and testing year over year in corrosive soil. They help a bunch feel free to reach out with questions. They are a cheap alternative.

Hi Collin, concrete mix design expert here. At our company we offer concrete chemical admixtures that can waterproof concrete and also something that will act as a corrosion inhibitor, this keeps the rebar in concrete from rusting and will probably work very well for your application.

A coating of synthetic 0w 20 or mineral oil plastic on top of that concrete with calcium chloride to absorb excess water on top of that plastic on top of that then your dirt. Oil is going to add some protection and also give something for the plastic to stick to.

I think a lot of us love the tunnel videos because there’s that almost childlike obsession of building pillow forts or camping in your yard. And for be I’ve thought it’d be really cool to have a bunker or secret rooms behind bookcases. That’s the Maine thing I always loved.

I worked at a submarine base in the middle east, during its construction we did lots of tests on steel/concrete combinations to see which would last the longest as we were dealing with saltwater. We found the best method for support beams was concrete filled steel tubes that we left in direct contact with the salt water. We didn't paint the steel just left it as is. The concrete inside the steel reacted with the saltwater on the outside and created a sort of barrier that prevented any rust at all. For the 10 years I worked there we saw little to no surface rust form on the steel and no loss to the structure.

My wife is a structural engineer and she says:
I've actually been thinking about this a lot since you started the tunnel videos, so I'm glad you brought it up. One of the worst things you can do for steel is put it through wet and dry cycles. All wet is better than cycling, so if the conditions around it are more consistent, then that would be better. I don't advise the plastic sheet for the same reason another commenter mentioned, trapping moisture between the sheet and the steel would accelerate rusting. I also agree with him that using the plastic as a vapor barrier to the soil would be a better use. This is actually why some states in the US will not allow epoxy coated rebar to be used in bridge construction. Little pin holes or gaps in the coating will allow moisture in and keep it concentrated in that specific area. This area is more likely to rust through and cause problems where as, if they just left it as metal, it would have developed a more even thin layer of rust without section loss. You could paint the back if you wanted, but seeing how the uncovered steel is doing after all this time, I don't know if I'd bother. Since this is your drive, I would maybe look into alternatives to salt for melting ice in case it seeps into the soil.
Happy digging!

I could feel that Ryobi crying! Interesting regarding the rust. I worked on a concrete and cathodic rust prevention system on a Marina arm many years ago. They ran low level electricity through a titanium mesh and cathodes inserted into the concrete to prevent the steel inside the concrete corroding further. The marina arm is still standing so im guessing it works! Saying that it was fairly costly enterprise!
Good luck with it all, what a project!

"Asking questions to us, thinking about it, comes up with his own solution."
We are glad to be of assistance, Mr Furze.
Always a pleasure to work with you :D

I'd definitely go with a sacrificial anode. It won't interfere with the construction of the garage/tunnel at all and it should be fairly convenient to do. The entire steel structure is electrically connected so all you'll need is to do attach a cable at one place and link it to a block of zinc at the other end

As a former submariner, we use sacrificial anodes all over the submarine. It should be pretty easy to stud weld the interior and mount the sacrificial anodes to the tunnels and the bunker. My thought on the plastic is it trapped want moisture was in the air before the concrete was poured.

I have no worries pouring up against steel. Make sure you vibe it well. You always want excellent consolidation. Too much Air is bad. The poly I always put up against the terra, which is where any moisture is going to originate from. I try not let concrete free fall out of the pump for more than a few feet and directly over rebar to avoid as much segregation as possible. Unless you are actually BLOWING YOUR CONCRETE INTO TIGHT SPOTS WITH A MIXTURE CALLED GUNITE. This technique is also used to free form the vertical walls of swimming pools and tunneling when you are not using steel forms. I always poly against the earth side no matter what. Before I put down an exterior slab I put a nice thick 6 ml poly down on my Compacted aggregate base, then steel, then mud.
I am super excited to see how you tackle the next level down ... under the entire foot print of the property. We may need to do arched beams at 20 feet tall spanning the width of the property. A warehouse soccer pitch under the whole existing tunnel system !!! That will be Banananananans !!! And fun !!!

Colin! You could use “Sacrificial Anodes” by attaching zinc anodes to the steel like they use on battle ships. The zinc will corrode instead of the steel.

A piece of advice from a civil engineer: Steel and concrete work really well together. Salts and water should not be a problem if you use proper water resistant concrete. We used to pour C30/37 water resistant concrete for reservoirs for wastewater treatment plant and I can tell you if concrete is well poured, vibrated and treated it will not let any water near your steel.
On the other hand membranes can trap condensation between the steel and membrane surface, making it worse in a long run.
Therefore I would recommend just a steel and a good concrete.
Love your content, keep goin!

In 10 years time I half expect Colin to be digging a tunnel straight down.

It seems like you've summoned the engineering task force on this one. Amazing how many engineers watch your videos

I'm not involved in construction or groundworks in any sense but I had done a fair bit of DIY over the years. I would imagine the best coating you could use to stop rust occurring would be bitumen paint. I've used it for various waterproofing applications over the years & it is yet to fail me.

For me, it's not all just the projects you do. People watch because of you Colin. Your personality and how you explain everything is what attracts all of us to you

It's pretty common to use sacrificial anodes on underground steel tanks and such. They're pretty cheap, like under $50US. Much easier than coating the steel in anything, and can be used on your existing tunnel and bunker as well.

Use magnesium anodes. Make a little offshoot tunnel with a spot to dig down. Anode needs to be surrounded with clean dirt and soaked with water when installed. There's a piece of copper wire that comes off it which you can just weld to the wall. This is what's used to keep steel utility mains from rusting. Anode will be need to be replaced every so often depending on how many you use throughout your system

In construction with reinforced concrete, the rebar has to have at least 1" of concrete around it.
This is to protect the "coating" resulting from the reaction between concrete and rust from incoming water, be it from weather or from ground.
Coworker just built a house and talked to the concrete specialists.

Hey Colin, I use to work in a concrete laboratory at a concrete pipe factory. TBH, I was a little concerned with your original bunker with the polythene, with the thought that water may wick up between the steel and poly, glad to see it looks good so far. Generally speaking concrete protects steel from rust as you mentioned. In areas where we would build pipes for salt water, we would increase the reinforcing cover from like 20mm to 40mm which gave better protection from the salt. You have loads of cover... Interestingly enough, we would sit reinforcing outside for a few weeks to rust before using it as the rust would bond to the concrete much better than the mill scale. The concrete bonding well to the steel will reduce rust, so keep that in mind before pouring concrete. Delamination from the concrete will cause it to rust faster. Being that its in fairly low temperatures will significantly reduce the rusting rate, I think it's roughly log base10 on temperature where 10C increase in temperature will roughly double the corrosion rate. I would have tack welded reinforcing mesh to the walls of the bunker so it would become a big monocoque reinforcing structure. Good work ol chap... great project, have loved watching it.

Two thoughts: Cathodic protection systems are tried and true in the oil and gas industry, but that's steel in dirt or rock. I've torn up a few foundations before, and rebar in concrete revealed after 100 years are still pretty good. Never actually took measurements but I'd say it's still structural at that age.

Owatrol. I've worked with boats for years and this stuff has never let me down. It's like an oil that sets like a paint. Once its applied it penetrates the steel and then you are golden.
Great content brother.

To your question at 4:32 about the plastic sheets on the wet steel, reminds me of videos where mechanics criticize the use of rubberized rust-proofing undercoats. Once hardened, they tend to peel away and crack a bit and leave this thin gap that draws in moisture by capillary action and then keeps it there with no air flow. Once rust starts to form, the rough and crusty steel surface wicks in water even more, while oxide formation pushes the gap wider. So I think you have better longevity on the bare-poured steel with its weather-facing surface chemically bonded and stabilized with the concrete.

Colin, if you were ever in any doubt as to whether people cared or loved your work, you hit a million views in under 7 hours in your second channel. Your audience is as dedicated as they come and you deserve it.

I'm looking forward to watching Colin Furze for the next 40 years not only for the great content but also to see how the tunnel is doing. Colin if your looking for ideas, what about putting an infinity mirror in the foot of the tunnel leading to the bunker, it would look like a shaft in the floor. Keep up the great work. God bless

I applied to work in tescos 15 years ago and I can confirm you’ve got nothing to worry about 👍🏻👌

As a former engineer on a diesel-electrical submarine for 7 years and a civil engineer for pipeline operations for 15 years, I have the following comment:
Although, submarines and any metal boat / ship must have sacrificial anodes (various materials have been used), that is not always the case with buried pipes (or bunkers for this matter). Cathodic protection is mainly used to and one of the most effective methods for preventing corrosion on a metal surface. Due to the potential difference between the anodic (less noble) and the cathodic area (steel), positively charged metal ions leave the anode surface, while electrons leave the surface at the cathode. This results in reducing the thickness of metal. The simplest method to apply cathodic protection is by connecting the metal to be protected with another more easily corroded metal to act as the anode (passive cathodic protection). Zinc, aluminium and magnesium are the metals commonly used as anodes. For buried steel pipelines with large diameter we also use active protection that uses an external source of electrical power provided by a regulated DC power supply, often referred to as control panel. The control panel provides the current necessary to polarise the surface to be protected.
With all that said if we use Reinforced Concrete Pipes (RCP) for buried applications, there is no need to provide cathodic protection for the steel rebars used inside the concrete, but the rebars must be properly galvanized preferably by the hot dip method and then given a protective coat of bitumen or epoxy paint to give you years of corrosion free service.
In your case, you should benefit from investment in passive cathodic protection with zinc anodes directly connected to the steel inside. I can help you to calculate the amount of the anodes (by weight) for free if you need help with that.
Amazing work Colin! Can't wait to see your new videos.. Keep up the good work!

Hi Colin, was intrigued to see you talking about rusting steel in concrete and how to prevent it because this is what I do for a job! If you are worried about the condition of the steel there is a method of non destructive testing you can do (known as a half-cell survey) that will tell you what condition the steel is in without having to visually inspect it. If you were looking to protect it there are several methods like you stated, but the one I and my company deal with is a Cathodic Protection system. (This is the method you mentioned) there are two main types of CP systems, Galvanic anode (sacrificial anodes) and Impressed current (the electricity one). both are viable options for protecting the steel. Both methods have their merits and draw backs. the galvanic anodes will run out eventually and will need replacing after time. Where as impressed current can be expensive to install and requires a constant power supply to ensure that it is working. There are many other factors that would affect the effectiveness of a CP system and how easy it would be to install on the tunnels and i'm not going to go into all of them in the comment as that would be too long. Good luck with the rest of the tunnels

Conrete that is 30 cm or more in thickness, is always waterproof. The plastic sheet on the outside is building up humidity and the moisture rusts the metal. We always put the plastic sheet between the concrete and the diret/sand to prevent the concrete losing water to the dirt/sand before its hardened.
But steelbars that are surrounded by concrete don't rust. I think you need to worrie more about the moisture coming from inside the room (wet car, bad sealing of the carlift, etc)

Collin, I look at bridges! I am by no means a concrete expert, but what would be best is to pour the concrete directly against the raw steel. Attempting to then waterproof the concrete is the way to go, bitumen etc. I'd then look to paint the inside. I've been in some confined space box beam structures, they're painted inside and most of them are like new even today, most of them are pushing 60 years old now.
The 'Bunker' it's difficult to tell. You could try some ultrasonic testing to find the residual thickness of the steel sheeting and determine if any section loss/corrosion has occurred.
I'm sure some proper engineers can tell you more!

the hole saw giggity was the best insight into your feelings about the rust lol

Cathodic protection will look after your steel, sacrificial anode will do just fine (basically a bit of metal that is more reactive than the steel that floods the ground with electrons to protect your bunker. This will need a connection to your bunker). Although if you want to go fancy you could use an impressed current type which involves a transformer rectifier. My background - Gas pipeline engineer, looking after big bits of steel in the ground for years successfully. Hope this helps Colin, love the content. All the best, Joe

Man, I would love more of this type of content on this channel. Answering questions and such, providing some science, because that was awesome to learn about concrete and steel.

A lot of pipe lines use the 'zinc anode' for protection. If done correctly it will also let you know the general condition of the actual metal of the pipes. (and usually it's a simple matter of replacing the zinc if needed) Refineries use it quite a bit for when the pipelines transition from above ground to underground. (This is a very over simplification of the process but it works.)

I was a concrete technician back in the late 80’s and have concrete technology quals, where did your concrete supply come from, down here in South Wales we use sea dredged sand which contains chlorides and salt, pit sand doesn’t contain as much chlorides so will not react as fast, cement has chemicals and silica’s in which react with moisture, I’d say it will outlast your lifetime Colin👍

I've seen a lot of uncoated rebar in concrete structures used to store/treat wastewater last well over 50 years here in the States. I would say you should be good to go with just steel/concrete. As others have said, galvanized steel would be a better long term solution, but it should be fine buried. However, I would roll on an asphaltic waterproofing coating on the outside of the concrete you put on top of the underground garage portion. Love the 2nd Channel, Colin!

I'm sure this has already been said, but Grady from practical engineering has all of these answers in several videos. It would be fun to see him make an appearance on your channel.

I know a civil engineer and will forward this video after I comment. You can run a DC current through the whole steel structure as you mentioned. I've heard this helps with corrosion on bridges. Not sure what polarity but imagine it's like electroplating. You want to add ions to your metal. Another option might be a waterproof additive to your concrete. I know they use this on floating homes when making massive pontoons. Love this series Colin it's proper entertaining and most fellas would love to build something like this deep down 😂

Concrete & steel love each other, mineralised water is what mucks it all up. Additives into the concrete to minimise water ingress and poly liner between concrete and soil. No liner between the steel sheet and concrete.

It feels like just yesterday as a teenager that I started watching your tunnel series. It doesn't feel like its been years and here you are, now building a secret garage. This type of content NEVER gets old and it will never not be fun to watch.

I was just thinking about this with the last episode as you will probably have more moisture coming in depending on how well sealed the lift garage and how often you use it

Hi, Colin. I'm an architect. Definitely the best option in the long run is to put the waterproofing between the concrete and the soil. Putting the plastic layer between concrete and steel could cause moisture problems. But more importantly, not putting any waterproofing would still allow water to penetrate through the micro-cracks in the concrete and eventually get to the steel. Which will rust, then expand adding stresses to the concrete which will see the micro-cracks widen, thus allowing more water to pass through, and so on.

hey Colin, love your content. I would encase the steel with the concrete and then cover the concrete with an additional water barrier (sheets or brushed on.) Perhaps some French drains for whatever comes. Since this will be under your driveway/deck, I assume there will be much more water penetration from rain then your previous tunnels. It does rain in your part of the woods.
How thick will the finished roof be? Maybe one of your fancy elevation drawings to show your roof structure in the next vid. metal, concrete, sheeting, dirt, sand. pavers, surface
thanx again

You could add an additive like MasterLife CI 222 which makes steel last longer within concrete. There are other additives as well that can help add more protection for the steel.

As I’m sure you know, the technical terminology of the chemical interaction between iron and concrete, the part where they neutralize each other, is called passivation. It’s good to learn how that works, to know that your tunnel will likely survive for a long time. I love your videos.

After sanding your buggy for new paint you spray the steal with an acid water mix and let it dry on then paint you do not rins or wipe it off. This pasivates the surface potasium in the steel slowing rust. I recomend this then use a paint roller to apply slow set roofing tar thinly befor pouring the cement against the steel.

You are spot on, no sheeting. When you pour the wet concrete the water seeps between the sheet and the metal, then is heated as the concrete cures. All that rust was from 8 years ago. So you're sorted! If you really want to make sure, you could paint the outside first with a waterproof polymer and that would seal off the steel completely. Even better I hear you say!

Usually when constructing a basement they will have to go for two methods of water protection, some sort of traditional tanking with a sump and probably a membrane!! Waterproof concrete has got a lot better though and is seen as a genuine second method of protection these days! Might be worth looking at

I definitely recommend looking into using sacrificial anodes. Galvanic corrosion protection is way simpler than people think. You just need to bolt a chunk of metal with a more negative reduction potential to your steel every so often and it will passively protect it from corrosion. Zinc and aluminum work well, you can either buy them purpose made or just find some scrap.

That is so awesome to know! Thank you for digging a secret tunnel and updating us on it!