Plans for the back building

We've been mostly planning the next renovation phase: the "powder room*", laundry room, kitchen and dining room.

*What a stupidly euphemistic name. In Spanish we call this aseo:  a small room with a WC and a washbasin, literally a place where you tidy up yourself. I guess powdering might be considered "tidying up", but, really? anyway.

Planning is incredibly important, we've found. We go over things over, and over, and over, and over again and we always find something we were mistaken about, or we had forgotten. It also happens that you change your mind 3 or 4 times, I think, mostly for the better.

We've been mainly focusing on the aseo and the laundry. These are immediately adjacent the main house building (the living room which is a temporary kitchen at the moment), and, with a baby on the way, will come in very handy as you can imagine. The kitchen and dining room can wait since we have functioning ones, temporary and super messy, but functional. The laundry is also functional at the moment, with the laundry machine and also the dishwasher connected there.

So we have been planning the distribution of the aseo, which is no easy task since it is a tiny 1 x 1,2 m room, and we are recycling a door found in the house (72 cm wide). And I did not want the door to swing outwards into the narrow passage/laundry, particularly since you'll have to go up a couple of steps to go into the aseo, and that seems very awkward to me.

We finally chose and ordered a WC (I love how easy it must be to clean this one! all stupid crannies hidden in a smooth ceramic column :)), a vessel sink (with overflow, many vessel sinks do not have one! dangerous...), the tiles (going for Winckelmans gres again, which we're loving), the taps and hardware (also very happy with our choice in the bathroom), and the lamps (going for a bit of a fancy-design thing this time). We'll build the counter for the sink ourselves, of ebonised oak and carrara marble. A wall to wall mirror and possibly some led strip lightning over the moulding on the ceiling and that's all that's necessary. We have also ordered the laundry sink, but I'll talk about that later.

• WC: Globo Paestum Monolito with an ebonised oak seat
• Sink: Scarabeo In-Out drop-in
• Tiles: Winckelmans 5x5 cm black and white square
• Hardware: Nicolazzi 1477NO70 nero opaco half dome wall mounted + paper holder / towel bar
• Lamps: Karboxx Escape cube

Obligatory crap-collage
The hardware finish is all wrong! and also wrong tap handles

The colour scheme of the room will be very strictly black and white. I'm quite inspired by razzle dazzle camouflage paint from WWI for this! Really looking forward to it ;)

So far we have received the WC, we will pick up the tiles tomorrow, and we got a dispatch notice for both sinks. Both lamps and taps (bit of a special order) are due in February.

Structural work has already begun, and, as I'm getting large and clumsy, I am not helping with this hard, dusty as fuck work at the moment. Pim's been cutting at the walls with the angle grinder, in all the places where electricity switches & ducts, and pipes of all types have to be built into the wall. No insulation/plasterboard in this building, so lots and lots of cutting!

He's already built the threshold (recycled steel railroad beam + concrete) for the aseo door (this was simply a solid wall before), and begun building the wall that is missing at the moment, between the aseo and the kitchen. He also cut off a chunk of wall between the laundry and the kitchen, because the passage was unnecessarily narrow:

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Kitchen window post

This post was a long way coming. Since I have a lot of images to post, I have been experimenting with some code added to the blogger template in order to have galleries to display the images. It is very clunky but it does the job. I should seriously consider importing this blog into my main website blog, but I have to think how and if I'd still like to keep it more separated.

Meanwhile, let us continue.

It has been cold, wet, and miserable. January and February are not pleasant to work around outside here. Luckily Pim and his father do not seem to mind too much, I have bad joints and I just can't work in these conditions, so besides a coat of paint in a small surface while wearing a Peruvian oversize pullover (what a wuss right?) I have done nothing of this project until the windows were in. By March however I have started gardening ;P

In the gallery below we pick up where we left in the last post:

• Sliding door beam concrete-d, bricks removed, edges redone. First time we can really see some of the garden from the house. In this case, a big pile of bricks :D
• Dining room window (where the shed door used to be) beam placed and concrete-d, bricks removed to widen, bricks added to make door into window, edges redone.
• Bit of wall where the radiator goes gets painted, green of course, and the radiator put up (it was in the way, this is one very large and 100 kg heavy motherfucker).
• Existing door widened, some bricks added between the pre-existing door and window for a stronger structure.
• Existing window narrowed and lowered to be as low as the kitchen counter.
• Outer windowsill stones (Belgian blue sandstone) placed. Some of these are very heavy... unlike other windowsills in the house, we had them delivered, but Pim and his dad installed them. I was able to help moving a couple ;P
• Threshold stones placed, same as above.
• After some delay, windows, door and sliding door/window? placed by the window guys today!
• And now PHEW!

And now, onto other kitchen things... walls, floor, insulation...

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Next beam + bathroom closet

While Pim and his father were placing the next beam for a window in the back building, I took everything out of the bathroom closet, we took it apart, and then I cut a bit off the back legs. The floor in this room slopes towards the center and so the closet was leaning forward a lot. I guess I must have take a picture of that at some point, but I don't find it now. The top of the closet was 10 or 15 cm away from the wall when the bottom was close to the wall.

I also glued back a decorative leg piece that had fallen off, and some other parts where the hide glue had fractured a long time ago. I softened the glue with wet (warm water) kitchen paper towels, then scraped the excess off, and reglued with Titebond liquid hide glue. I think I am a convert now ;)

We put the closet back together, which is a delicate operation since the three door are caught by the top, and have to all be placed at once. It is a three man job.

This is how "level" it was

Knife wall

Chunks off

Scraping old glue off

Re-gluing

Quality control

Straight up 

Nice and close to the wall :)

On the beam front, Pim and his father encountered more difficulties than last time.

The beam that the roof guys placed over the entire length, on top of the wall, was anchored to the wall with large bolts. This made removing the old beam over the door a little difficult. This opening had to become much wider than the door so the beam had to be replaced. Pim had to drill around the bolts, concrete will later be placed around the bolts to anchor them again.

The beam was again placed over to flat and level pieces of concrete

Another recycled railway track serving as beam

Sliding door beam

I have not been updating, we've been doing many little and finishing things, and I didn't feel like writing about those. Today however, Pim and his dad started something rather big.
We've ordered the last batch of windows for the house, for the future kitchen/dining room. These take a few months of queue and manufacture, and we've now started actually making the holes where they'll go. On the very end of our house, we're putting a large sliding door that will cover most of the wall. This was the shed, and it will be the dining room. On the picture above, you see where the hole for a beam was started. The wall of the building to the right is the neighbour's (I think it's a horse stable). This is the area where we had the hillbilly tomato roof, which we have now removed.

Pim screwed some extra pieces of wood with very large screws to hold the top portion of the wall up while making a hole and installing the beam. It was all done today as quickly as possible, and the structure held very well (the roof is mostly supported on the back and front walls anyway).

Pim's dad working on the wall. 

Above you can still see the beam that we used. They're repurposed "vintage" railroad tracks. There were several of these in the back/shed, holding up a very strong flat ceiling in concrete that we removed some time ago. The space on top of it as you can see was very small, all in all a little puzzling, it was probably the strongest ceiling of the entire house. Maybe they stored gold bars in there, haha.

The leftover beam.

Pim cut off the necessary piece of beam that we had been keeping in place, and they placed it in the hole over two flat and level blocks of concrete they had placed over the bricks.

Beam in place over the concrete blocks.

Beam in place over the concrete blocks.

More cement.

Reinforced with chicken wire.

To fill the gap over the beam again, Pim placed some recycled chicken wire we found in the garden, then concrete. So in a way it is reinforced concrete. A piece of wood and some plastic closes the gap below.

Reinforced with chicken wire.

This is not the way these things are normally done, everything would just come off and the beam placed, but we didn't want to leave this entire part of the building open to the elements in January for who knows how long... once the date to place the windows approaches, we'll remove the rest of the wall.

The same still has to be done for a couple of windows, also. We have other pieces of railroad for that.

Bathroom floor reinforcement

The bathroom is going to be placed in the smallest bedroom, which is still quite large for bathroom standards (about 12 m²), but it was the only reasonable option in order to have a bathroom close to the bedrooms.  This room is on the 1st floor of the house so it doesn't have a concrete base, only the ground level floor has.  The room's floor is supported with wooden beams of about 14 cm x 6 cm, placed about 40 cm apart.   Though the wood is still in good condition, it makes the floor all in all quite 'elastic', which puts some constraints on what kind of floor you can lay.

The basic options are wood (solid wood, not laminate, since it's still a bathroom) and tiles.  Putting a tiled floor is not advisable because tiles are not flexible and although thinset has some elasticity to it, it won't be enough to bend as much as the floor underneath would.   We then considered putting a wooden floor and treating it with a decent water-repellent oil, but we also wanted to have an open walk-in shower so it's quite difficult to estimate how the wood will react over the years with all the humidity.  

We are concerned with durability and don't want to start renovating everything all over again in 10 years, so tiles were back in the picture.  This also means that the floor structure underneath will need to be made much more rigid, but hey, sometimes you gotta roll the hard six.

This will actually be the first time since I graduated that I will ever put one of my engineering subjects to practical use.  The problem with the wooden floor is not the strength - it is probably still strong enough to carry an elephant - the problem is that it bends too much while carrying weight, as opposed to concrete which hardly bends at all and is therefore much better to put a tiled floor on.  Looking up what modern building standards say about how much a floor should bend I found out that the floor is at least a factor 4 too elastic.  Although you would think that the beams look quite big and 40 cm apart is not too much, a little bit of introduction into the physics of it will explain better what the problem is.  

To understand what makes beams carry load, you need to understand that next to size and material, the shape of the cross-section is important, it determines something called the "second moment of area".  The second moment of area is a useful concept because it is only determined by the cross-section of a beam, so once you have calculated this, you can apply it to any beam of any length and any material.  The beams have a rectangular shape and are 14cm high and 6 cm wide, as stated above.  A quick look at this list teaches us that for this shape the second moment of area is width x height³ / 3.   This means that when the width increases 2x, the strength of the beam increases 2x.  However if the height increases 2x, the strength increases 8x (= 2³).  The beams in our floor are not very high compared to modern standards, which would rather use narrower and taller beams. (e.g. 3 cm x 26 cm) and put them closer together.  Just increasing the height from 14 cm to 26 cm would already make the floor 6.4x more rigid.

So the problem is identified, we need to be able to take some measures to increase the rigidity.  Using wood again was our first choice, but proved to be quite challenging, as there are only 2 options:  Either raising the floor 10 cm and use taller beams, or put 4x more beams .  The first would be unacceptable because the room would need a step just to get in, the second would be a ridiculous waste of material.  A beam of 6 cm every 10 cm would mean that the floor would be more than 50% beam. Another option would be to put a concrete floor with lewis dovetail sheeting.  Although this system allows for using little concrete to get a strong floor, it is still a big and heavy slab of concrete adding to the load of the aging beams.  No, the problem is that the beams are not strong enough and pouring concrete over it will make the surface more rigid, but weaken the beams.

There is another material though that has a much better weight to strength ratio than concrete: steel.  I wouldn't have thought of it first but I got the idea from a colleague who had a similar problem and who's friend, an architect, proposed to use this approach for old wooden floors (and took it to another level).  If it can keep the empire state building up, it can surely keep our bathroom floor up.  To know why steel is doing better than wood, you need another factor for calculating the strength of a beam: the elastic modulus.  It is dependent only on the material being used and relates directly to the strength of the beam.  A quick look at the list here shows that construction steel, with a modulus of 200, is about 22 times better than wood (pine along the grain), with a modulus of about 9.  Wood is also a natural material which makes it quite unpredictable, so you might have some very good and very bad pieces.  This translates quite simply to the fact that steel would give the same strength with 22x less material, so the cross section of the beams (if they would be steel) could be 22x less.  

If you look at steel beams used for construction, their cross-section is always I-shaped.  The reason is quite simple: the further away from the 'center of bending' the material is, the more it contributes to the strength of the beam (it's the same as the leverage you get using a crowbar or pliers).  So to save material (and therefore useless weight), the beam is made wide far away from the center and thin close to the center.  The idea is to mimic this behaviour and create I-shaped beams out of the old wooden beams by attaching steel C profiles (in fact half an I-profile, cut vertically) on each side of the beam.  

Without making too many calculations in detail, the following should be true: the elastic modulus of the material multiplied with the second moment of area determines the strength of the floor (since the only other factor is the length of the beam, which is not free to choose).  The result of this multiplication for the wood, currently, is 4x lower than the what we want.  Using an online calculator for calculating the second moment of area for I-profiles I found out that the C-profiles in steel should be 13 cm high and 2 mm thick, with the top folded out for 1cm, as shown in the drawing below.  

These shapes can be cut and folded out of sheet steel and are therefore quite cheap and easy to produce, with holes pre-drilled in them every 10 cm to be able to screw them to the wooden beams.  The picture above is the technical drawing I used to have them made to measure.  The second moment of area of this shape is about 12x smaller than that of the original beams, but then again steel's elasticity is 22x less.  This means that the steel in itself, despite being just 2 mm thick (compared to 60 mm for the wood) is actually nearly 2x as strong as the wood.  Together they will make the beam structure almost 3x as strong as it used to be.  Still not the 4x factor we wanted, but we will achieve that with the top layer of floorboards which will also be thicker as it used to be.

The original floorboards were just plain independent planks of about 18 mm thick and 10 cm wide.  The problem with this is that one plank is carrying your entire weight if you step onto it, the others are not contributing anything to the rigidity.  It's not so weak that you'll fall through, but it's still too elastic to tile upon.  For the surface I therefore opted to put 3 layers of boards in perpendicular orientation.  The bottom two layers are OSB boards of 12 mm, the top layer is plywood of 8 mm.  The reason why the top layer is plywood is because we need to bridge a gap of 8 mm and OSB doesn't come in any arbitrary thickness.  The reason for the gap is that we're using tiles of a different thickness for a decorative mat pattern  For these we make a small cutout in the top layer.  OSB and plywood are similar in strength but OSB tends to be cheaper.  Anyway, the result is a floor that is 32 mm thick, all layers glued and screwed solidly to each other.  This configuration is much more solid (I don't have any calculations ready here) than the original floorboards because it acts like a single, solid piece of material.  Putting pressure on a single point (e.g your foot, or the leg of a bath tub) will cause a lot less bending this way than with the old floorboards.

So far for the boring (or exciting, if you want) theoretical part.  Up next is putting it all together.  It starts with taking the old floorboards out and clearing all the wooden beams of any nails or other stuff sticking out so the steel plates can be tightly attached, trying not to fall through the plaster ceiling below.

We decided to treat the plates against corrosion although it is already corrosion resistant (as it is steel), with a special oil-based paint. To do this, we first needed to wash off the oil that came with them (which is put on to ward off humidity and therefore corrosion).

Drying in the sun after washing with detergent.

Since the steel plates are smaller than the original beams (13cm vs 14cm) it is not so difficult to fit them.  A bigger size would have been even stronger but would also have been a pain to install, as the original beams are not clear on the bottom, due to the plaster ceiling of the room below.

The white stuff you see between the wood and the steel is a universal glue we put in between to make sure that the different parts don't move at all relative to each other so that the combination of wood and steel acts as a single beam.  I also opted for using a lot of small screws instead of fewer but larger bolts to spread the load more equally and to be able to get the steel fit more tightly to the wood.  It's more work but the result should be better.

Once all the beams are done, we move on to the surface.

First layer of OSB boards screwed to the beams

The first layer of OSB boards is put perpendicular to the beams and screwed well into them with long screws. This layer gets covered with wood glue over the full surface (using a notched trowel) before putting the second layer.  This layer of OSB is also screwed with long screws into the same beams, as well as to the bottom layer (with short screws), mostly to clamp the two layers well to each other for the wood glue to act optimally.

Second layer perpendicular to the first one, screwed and glued.

As a third layer we used the 8mm thick plywood as shown below.  This layer is laid the same way as the second: wood glue all over the board (as seen on the right of the picture below) and screwed together tightly with small screws, perpendicular to the previous layer.

Glueing multiplex boards over OSB boards

All boards glued and screwed in place

 The result is a reinforced floor that acts like a solid piece of wood of 32 mm (as compared to the independent floor boards of 18mm that where there before), on top of steel-reinforced beams.  This floor is now ready to be tiled upon, which will be covered in another post.