How Does steel structure frame container house Work?

PTH steel structure container house is a type of modular housing that is constructed from shipping containers made of steel. These containers are typically 20 feet or 40 feet in length and are designed to be transported on ships, trucks, and trains.

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The steel containers are modified to create livable spaces that can be used as homes, offices, or even retail spaces. The walls, floor, and roof of the container are reinforced with steel to provide a strong and durable structure that can withstand harsh weather conditions.

The steel structure container house has become a popular housing solution due to its affordability, durability, and flexibility. They are also considered eco-friendly because they repurpose shipping containers that would otherwise be discarded.

The design of steel structure container houses can vary widely, from simple one-room dwellings to multi-story homes with multiple bedrooms and bathrooms. They can also be customized to suit individual needs, with various finishes and features like windows, doors, insulation, and heating and cooling systems.

The most common types of building frames are timber frames, steel frames, and reinforced concrete frames. Timber frames are typically used for smaller structures, while steel and reinforced concrete frames are used for larger buildings and structures.

Frames can be designed in various shapes and configurations depending on the requirements of the building or structure. For example, a simple rectangular frame may be used for a single-story building, while a more complex frame with diagonal members may be used for a high-rise building to provide greater stability and resistance to wind and seismic forces.

Compare timber frames, steel frames, and reinforced concrete frames

Timber Frames:

Advantages: Timber frames are a sustainable option, as they are made from renewable materials. They are also energy-efficient, as wood is a natural insulator. Timber frames are easy to work with and can be customized to fit a variety of building designs. They are also lightweight, which can reduce foundation and transportation costs.

Disadvantages: Timber frames can be vulnerable to moisture and pests, which can lead to decay and rot. They may also require more maintenance than other types of frames, such as regular staining or painting. Timber frames may also be more prone to fire, though fire-resistant treatments are available.

Steel Frames:

Advantages: Steel frames are strong and durable, and can withstand high winds, earthquakes, and other types of stresses. They are also fire-resistant and low-maintenance, as they do not require staining or painting. Steel frames are also lightweight and can be easily transported and assembled on-site.

Disadvantages: Steel frames are not as energy-efficient as timber frames, as metal is a conductor of heat and cold. They may also be more expensive than timber frames, depending on the type of steel used.

Reinforced Concrete Frames:

Advantages: Reinforced concrete frames are strong, durable, and fire-resistant. They can also withstand high winds, earthquakes, and other types of stresses. They are also energy-efficient, as concrete has a high thermal mass that can regulate indoor temperature. Reinforced concrete frames are also low-maintenance and can be customized to fit a variety of building designs.

Disadvantages: Reinforced concrete frames can be heavy, which can increase foundation and transportation costs. They may also be more expensive than timber frames, depending on the type of reinforcement used. Reinforced concrete frames may also require more skilled labor and longer construction times than other types of frames.

Steel frames can also be combined with other materials, such as concrete or timber, to create hybrid structures that take advantage of the strengths of each material.

Steel frames provide a strong, durable, and versatile building frame option that is widely used in the construction industry.

For some flat packed container house, we use Q355 steel.

Q355 steel has a minimum yield strength of 355 megapascals (MPa), which means that it can withstand a high amount of stress before it starts to deform or fail. It also has good weldability and machinability, making it easy to work with and modify during the construction process.

Compared to traditional carbon steels, Q355 steel has a lower carbon content, which means that it is less susceptible to corrosion and can be more easily recycled. It is also more environmentally friendly than other types of steel, as it requires less energy to produce and generates less waste.

Why Both side steel sandwich panel

Both side steel sandwich panels are commonly used in the construction industry for walls, roofs, and floors. They offer several advantages over traditional building materials such as concrete or brick, including:

Strength: Steel is a strong and durable material that can withstand harsh weather conditions, seismic forces, and other types of stresses.

Thermal insulation: The core material of both side steel sandwich panels can provide excellent thermal insulation, which can help to reduce heating and cooling costs.

Fire resistance: Steel is naturally fire-resistant, and some types of both side steel sandwich panels are designed to be even more fire-resistant, providing an additional level of safety in case of a fire.

Acoustic insulation: The core material of both side steel sandwich panels can also provide excellent sound insulation, which can help to reduce noise levels inside the building.

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About PTH House

PTH (Putian House) is a company that specializes in the design, production, and installation of prefabricated houses and other modular buildings.

PTH offers a wide range of prefabricated housing solutions, including:

Modular homes: These are prefabricated homes that are built in sections off-site and then assembled on-site. They can be customized to meet the specific needs of the homeowner, and are available in a variety of sizes and styles.

Container houses: These are modular homes that are built using shipping containers as the main structural element. They are designed to be easy to transport and assemble, and can be used for a variety of applications, including temporary housing and emergency shelters.

Steel structure houses: These are prefabricated houses that are built using steel frames as the main structural element. They are designed to be strong, durable, and energy-efficient, and can be customized to meet the specific needs of the homeowner.

Light steel villas: These are high-end prefabricated homes that are built using light steel frames and other high-quality materials. They are designed to be energy-efficient, environmentally friendly, and easy to assemble.

Hi, I'm Ben and this is The House I Built out of Shipping Containers. Now I've been interested in shipping container architecture for quite some time, but I had a really hard time finding good information about how to get building permits or how much would it cost. We did the research. We documented everything that we did and now we're so excited to share with you what we learned. So check it out. This is episode two. We'll show you how we move the containers, cut them open and started the structural reinforcement. After letting the concrete cure for three days, we began stripping the mold and getting ready for the day I was most excited about, which is crane day. This is the single biggest piece of equipment that we rented for this project. It's basically like a giant transformer.

To pick up the containers they use these fabric straps, which are super strong, and each one of them has a hook which can hook into the boxes at the corner of the containers. We started by moving one, the extra 20 foot containers that I bought to store tools and materials on site. This is a specialty type of container that opens up, not just on the short sides, but on the broad side as well. Next, we started moving the other 20 foot container which is going to be the guest bedroom and bathroom. This container is lightweight enough that the crane could actually drive while the box was suspended in the air.

We had the lineup the containers so that it wouldn't break one of the drain pipes that was sticking through the concrete. Next up was a 40 foot container, which is too heavy to drive with. So what they did is we just picked it up, swung the arm around to get it closer, and then repositioned the crane and do the whole thing again. We put some blue painter's tape on the corners of the concrete foundation just to give us a mark to aim for. The second 40 foot container had the farthest distance to travel and it's like watching an inch worm move its way across the desert.

It took a few attempts and three guys pushing on the corners to get it in the right location. If I was designing this again, I would now know that it's possible to get it, not exactly where you want it, but within about half an inch. Crane day was a lot of fun but now it's time to turn these steel boxes into a house. We started pulling up the floors on the containers. These floors are made out of plywood that is about one and an eighth of an inch thick. The steel structure underneath and underside of this plywood is coated with a thick black tar like substance which is there for waterproofing and they keep the steel from rusting. The majority of the plumbing for this house is going to go in this layer right amongst all the steel beams. Of course, things never line up properly so we're going to have to cut out a few of them. The pipe that Robert the plumber is working around is going to be the main drain that goes out from the container to the septic tank.

Originally, we had left this a lot longer, but once we saw that it wasn't going to align perfectly with the structure inside the container we had to cut it down so it wouldn't break when we drop the container into place. This meant that Robert would have to use a jackhammer to expose a little bit of the pipe by removing some of the concrete so we'd have enough room to fit an elbow on it. When I first learned we'd have to do this, I was worried it would take a really long time, but it actually only took about 45 minutes. We then cut holes in the other beams so that we could run the smaller drain pipes which will receive the water from the bathroom sink, the shower, the toilet, and the kitchen sink. The cut edges of the steel are quite sharp so the plumbers put some 20 minute hot mud and spray foam in between the pipes and the steel beams, just to keep the pipes from sliding around and potentially getting damaged.

Wherever you have drains, you also need to have venting pipes and these go all the way up through the walls and out the roof. The black ABS pipe is fine for wastewater going out of the building, but for all the clean water coming in, we want to use copper. This was more time consuming because the copper has to be sweated with a torch whereas the ABS plastic pipe can just be glued together. In the floor areas that don't have pipes going through them, we started filling those places in with rigid insulation. We packed in two layers of two inch thick rigid insulation, and then you spray foam to seal up all the gaps. Even though the insulation has excellent R- value. It's not going to be super effective in this location because the conductivity of the metal is going to create a thermal bridge around it, but still we added it in to keep that space full, keep critters out of it and to just give us a little bit of extra thermal protection.

This foam insulation cuts pretty easily with a box cutter so we just cut pieces that would also fit around all the pipes. After sealing it all with spray foam and testing to make sure the pipes are water tight, we then put the floorboards back on. This insulation is just so we can cover up the floors and get to work on the framing. We'll show the full installation details, including how we did continuous insulation over this plywood in next week's episode. While the rest of the crew was working on the insulation and the floors, I began making the structural frames for the doors and windows. After double checking the dimensions of the windows, I began making the 45 degree cuts so that I can make a mitered frame. The shipping container gets its strength from the continuous corrugated panels so whenever you cut one of these panels, you have to reinforce it. For these first few windows I decided to use two inch tube steel. It works great and it's plenty strong. But as you see, for some of the later frames, I switched to angle sections.

I did all the welding for the doors and windows using this little Forney welder. It's an inexpensive machine that's easy to use, great for beginners and powerful to build a house with. Now for the moment of truth, I was ready to cut into the container for the first time. I was pretty nervous about this because, you know, I paid a reasonable amount of money for these things, and we'd spent all this time to get them in the right position. I really didn't want to screw this up. I drew out the square that I'm going to cut out that will allow the frame to fit in using a silver Sharpie, a level and a piece of cardboard so I could draw straight lines around the corrugation. We didn't have electricity from the grid available on the construction site. I set up one of my little gold zero power packs with a solar panel, and that was enough to keep my batteries for my battery powered angle grinder nice and charge.

I've seen people cut containers open using a plasma cutter, but I'm really accurate with the angle grinder. It's a much easier tool to use and less expensive. I just went slow, made sure that I was following along the lines. I went through quite a few discs, but it only took about an hour and a half to cut out this entire window. The paint on these containers is really thick so I wire brush it away to expose the bare steel in preparation for welding. I needed a way to hold the frame in place while I welded the frame to the corrugated metal. I built these sliding supports out of two by fours that would allow me to clamp the two by fours to the corrugation and hold the frame nice and flush to the corrugation. This is important because when you cut into these big panels of corrugated metal, they can bow and flex quite a bit. With this technique it&#;s pretty important that the hole you cut into corrugated metal is just the right size because you don't want to be having to bridge across with the welder to connect the pieces. You don't have to do continuous seams all the way around. I just tried to get about two to three inch welds about every six to eight inches. I screwed up and over cut on this piece, but I just filled it in with my welder.

The second one went a lot smoother. I took more time in making sure that my initial drawing on the container was perfect and I went a lot slower with the cutting as well, making sure to stay right on the line. It was about 120 degrees inside these steel boxes and cutting open the window was a great experience. Not only can you see the view, but you get this rush of cooler, just 105 degree air coming in. It's definitely worth it to go really slow and get your initial cut out as accurate as possible. The welding for the second one was a lot easier because I wasn't bridging as big of a gap between the frame and the corrugated steel. On the first window, I ended up making seams that were a little bit too long. On the second one, I got it right and was sticking to seams that were just about two to three inches long. If you try to weld seams that are too long and continuous, the heat buildup from all the welding can start to deform and bend the corrugated metal.

For the two big 10 foot long bi-folding doors I wanted a frame that was a little bit stronger so I went with three inch by two inch tube steel. I glued some blocks of wood to the underside of a steel square and then I used that to clamp my tube steel pieces at nice right angles. I learned that grinding things once they're installed is a little bit more difficult especially if you have to get up on a ladder. I made sure to grind out all my welds as I welded them. The frames for the doors don't need a bottom piece, but I didn't want to move this without one because it might bend so I just welded in a temporary support. I also didn't cut the vertical pieces to length until I had welded the whole thing together. This way I can make sure that both sides were even. Working close to the ground is great because you can keep everything nice and flat, but it did make it so that we'd have to flip the frames over in order to cut all the way through from the other side with the angle grinder.

First frame is done time to make a second one exactly the same. For these big doors we started cutting out the openings from the inside, since it was easier to get up on a ladder with the nice flat floor. The black Sharpie line showed up real strong against the light beige interiors so it was easier to cut from the inside. I could see the line really crisply even through all the sweat and fog on the safety glasses. No matter what side you're in, though, it's easy to cut the part of the corrugation that's closest to you so I did do some of it outside as well. It's also easier to cut real close and flush to the support beam from the outside because from the inside, it's hard to get the angle grinder at the right angle because the floor gets in the way. Now, one thing to be careful for is that when you're cutting the container, the walls are under some pressure and all of a sudden, every once in a while they will jump or move and this can pinch the angle grinder or snap off a blade. These big pieces of metal are bendy, heavy and have jagged edges so it's a little bit tricky to handle them without cutting yourself up.

Some containers have welded on steel loops that are used to strap down cargo. I just cut these out as well. The corrugated metal was welded to this base beam along the container. I switched to a heavier angle grinder and just ground this all down. I stripped away the paint in preparation for welding and we lifted this 10 foot by seven foot frame into place. Remembering the lesson from the windows about bridging the gaps, we cut a little bit more on the conservative side and it wasn't quite big enough. We just ground away until the frame fit in perfectly. We started by tacking the frame to the base beam at the bottom corner, and then slowly worked our way up, making sure everything was still level.

The three inch wide tube steel was a lot easier to weld to the corrugation than the two inch steel because there was just a lot more surface area to connect the welds to and the radius of the tube steel wasn't sloping away from the corrugation. As soon as they got the frame tacked in and secured to the container, I cut away the temporary support. In retrospect, I should have welded this about six inches higher than I did just to give myself a little bit more room to cut it off. While I was welding in the first frame, the guy started cutting the opening for the second one. Now you might think that shipping containers are quite strong and don't need any additional structural support, but that's not actually the case if you're doing a fully permitted code approved building. Our structural engineer had to design an interior support system out of two by lumber and plywood that would meet all the structural requirements from the permitting office. This required substantial headers over these large bi-folding doors.

We were figuring this out as we went along and we knew that the doors and windows would be the trickiest parts. We made sure to frame around those and get that all set relative to the drawings before filling in all the wall spaces around them. Once you have the key structural elements in place using a nail gun to add into by fours, isn't too hard. On most of the projects that I have been involved with the header is directly over the door itself. But in this case, the header has to be tied in to the square steel tube that runs along the upper length of the container. Therefore we had to push the header up and then frame out underneath it. The purpose of the header is to provide support over large doors or windows. You don't want the flexion down onto these frames, which either cause them to break or could make them very difficult to open. The framing was going pretty quickly, but nothing was really tied into the container yet except for the two by four that runs along the bottom of the wall that was attached to the plywood that is a part of the container floor.

The stretches of walls that don't have doors and windows or plumbing features went a lot faster because we could panelize and build the walls and sections outside. We could then drag these into the container and then shoot nails down through this bottom two by four sill plate and into the plywood deck below. I've had a lot of people ask why any sort of additional structure is needed. I mean, aren't these steel boxes? Shouldn't they be strong enough by themselves? The problem isn't that these boxes aren't strong enough, it's where they get their strength and it's from these continuous corrugated panels. That strength is compromised when we cut into them, even though we are reinforcing where we cut. But the more important problem is that this steel is exposed to the outside and it's only about an eighth of an inch thick. If you're relying on exterior steel that's relatively thin for the structural support of the building, if someone doesn't maintain the paint and it starts to rust out, the whole building could collapse. You don't really want buildings that can have structural failures due to owner neglect. The most annoying part of the framing was attaching the walls to the steel containers. We nailed these galvanized steel brackets to a two by four, and then nail this on top of the walls to create a double top plate and then drive self-tapping screws through the holes in the brackets and into the square steel tube that runs along the top of the container. Putting this many self-tapping screws into steel is not fun and this took a minute. Our walls are taller than eight feet, and we're going to have to add plywood sheathing. We added additional pieces of two by four in between the studs so we'd have a surface for nailing on the plywood.

The ceiling will be supported by two by fours on joist hangers. We didn't nail in the two by fours yet because we still have to add insulation and sprinkler systems and other things, but we just cut them and set them in place for now. To recap, we have a two by four at the bottom vertical two by fours with stiffeners; some additional pieces for attaching the plywood and eventually dry wall; hangers to support the two by fours that'll support the ceiling and a double top light with brackets attached to the container. Another tricky structural requirement was that we had to tie down some of the shear walls to the foundation. We have to have a steel bar coming up from the concrete. We can get in there one of two ways. We can either cast it in place and use a coupling nut, or we can drill a hole and epoxy it in there. In either case it has to come up through the container through a top plate where this galvanized steel bracket can be bolted to it and then that bracket can be attached to a four by six or four by four post. Tony wrestled with that, but we didn't want to lock the post in place until we knew how the window installation would go.

After cleaning all the welds with wire brush, I then sprayed a few coats of rusty metal primer over the welds, the exposed steel that I brushed away on the container and the frames themselves. We ran a heavy beat of caulk around the inside of the frame and then pressed the window into place. The nailing flange on the window is going right up against the inside of the frame. Then we drove self-tapping screws through the flange and into the steel frame. This wouldn't be an ideal building detail in anything but a dry climate like this because you really have to rely on the silicone caulk from the exterior between the window unit and the steel frame to be your rain protection. With the window in place Tony then felt comfortable adding in the post.

Here's how the whole framing for this end wall looks. We have a steel rod going into the foundation that attaches to a bracket that connects to a post, which is tied into the rest of the two by four framing. I recommend drilling holes and using anchoring epoxy to fix the steel rods into the concrete it's way easier than trying to cast them in perfectly. You may have noticed that the part of the floor that the steel rod went through was steel and that's because this is part of the container where forklifts can come in to lift up the container from the end. You may notice that our building details are different throughout the project and that's because we were learning as we go along. The frames, I made out a tube steel for the first set of doors and windows worked just fine, but I noticed that it was very difficult to hold them perfectly in place. It was a really unforgiving detail where you had to cut the window hole perfect so for the next set of doors, I used angle steel to make the frames.

In this way, I would have a flange that could catch on the hole in the container, which would make it easier for clamping, getting it straight and it would give us a little bit of overlapping connection where we could caulk it from both sides. I used an angle grinder to notch out the ends of these pieces of angle steel so that they'd fit together and have a nice flat flange. These frames are going to reinforce the openings for the swinging entry doors

We welded the corners, added a temporary support piece, and then flip the frame over and welded from the other side. The 20 foot container which is going to house the guest bedroom has two swinging doors that are parallel to each other that's going to create opportunities for cross ventilation. My buddy Eric was visiting so we had ourselves a dueling angle grinder situation. Eric is a really talented metal worker and be sure to check out his work. I'll put a link to his Instagram in the description box below. I feel like this is a much better way to frame the doors and windows. Not only does the flange catch nicely on the corrugation, it actually gives you a really clean aesthetic from the outside as well. You also get two different areas to weld the frame to the corrugated metal. On the outside you weld right along the opening, but on the inside, you're welding the edge of the flange to the surface of the corrugated metal.

It's also nice because it gives us two seams to caulk one on the inside and one on the outside. I'll show finished drawings of the different window framing details next week, as I show how I finished trimming out all the windows and doors. Also in the next episode of the modern home project, we'll show how we did the insulation, installed the doors and windows and start having a little bit of fun along the way. Be sure to check out the first episode and don't forget to subscribe and turn on notifications. Oh yeah. And our new website's app. So check it out. We'll still be adding more information as we go, but it's worth taking a look now.

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