I didn’t know that LNG was such an Sustainable energy source. As you mentioned, various technology developments are needed to use LNG better. Then, what is POSCO’s solution for the LNG industry?

First, let me introduce POSCO’s lineup of steel materials for low temperature and cryogenic applications. At POSCO, there is a trio fit for the purpose: 9% nickel steel, high manganese steel, and STS304L. Let’s see each one of them in detail.

l Presenting POSCO’s Trio for the LNG Industry

– No.1: 9% Nickel Steel

sss

9% nickel steel? Let me guess! It’s a steel product with 9% nickel, right?

Exactly. 9% nickel steel is the most widely used steel for cryogenic application. This is because nickel maintains outstanding strength and toughness even at extremely low temperatures. 9% nickel steel was first developed by an American company, INCO, in 1944, and its safety was proven through model testing in 1960. Since then, it has been widely used as a material for storage tanks of extremely low-temperature use. However, nickel has a downside: it is expensive, and its supply and demand are unstable.
In addition, 9% nickel steel could only be produced by few steelmakers in the past, so domestic shipbuilders had to depend on imports. Fortunately, POSCO succeeded in developing it for the first time in 1993, and after quality stabilization, production for the material has been accelerated from 2007. Recently, POSCO has been in active cooperation with the Big 3 shipbuilders in Korea — Hyundai Heavy Industries, Daewoo Shipbuilding & Marine Engineering (DSME), and Samsung Heavy Industries — to develop their own technology for LNG storage tanks using this material.

– No.2: High Manganese Steel

High manganese steel? Is it steel with a lot of manganese?

You’re right. POSCO started developing high manganese steel for cryogenic application in 2010, and in 2013, succeeded in creating the new material for the first time in the world. The steel contains 22.5 to 25.5% manganese and is not easily damaged even at minus196 degrees Celsius. Unlike conventional carbon steel, which breaks under very low temperatures, high manganese steel can withstand such a harsh condition.

What’s the difference from 9% nickel steel?

Both steel products are applicable to extremely low temperatures, but they have a huge difference: cost competitiveness. Compared to nickel, manganese is more economical and has a stable supply and demand system, thanks to its abundant reserves. The cost of material is about 30% more economical for high manganese steel than 9% nickel steel, and the cost of welding is also much lower as well. Both 9% nickel steel and stainless steel are excellent steel materials for constructing LNG tanks. But since they were quite costly, POSCO developed high manganese steel as an alternative solution to the problem.
According to the regulations of the International Maritime Organization (IMO), only nickel alloy steel, stainless steel, 9% nickel steel, and aluminum alloy steel were permitted to be used as cryogenic materials for LNG tanks on board an LNG carrier. However, in 2018, high manganese steel also received official approval, which shows international recognition of POSCO’s technical excellence.

– No.3: STS304L

sss

Stainless 304L? I can’t guess this one.

Stainless steel contains nickel as well. 304 means that the stainless steel is “austenitic” at room temperature, and L means that it has low carbon content — under 0.03%. Stainless steel is much more machinable compared to 9% nickel steel and high manganese steel, so it is widely used in thick steel pipes and machinery of LNG plants. However, there are needs from certain clients who wish to use stainless steel for LNG tanks, so POSCO continues to develop technology and provide solutions regarding this steel.

Wow. POSCO developed a new steel product for the LNG industry? That’s amazing. I wouldn’t have imagined that the city gas I use at home was related to POSCO.

Right. But the real solution story hasn’t begun yet. Of course developing a new steel product is significant, but making sure that it is adopted and utilized by clients is much more important. POSCO has been involved in the R&D of LNG tanks with clients for many years so as to make LNG more economical and safer for us. Now let’s talk about our remarkable achievements.

l POSCO’s Solution for LNG!

Among 9% nickel steel, high manganese steel, and STS304L, POSCO’s clients may choose the optimal steel product according to the specifications of the LNG tanks they build. And POSCO provides the best solutions accordingly — regardless of which product it is.

– Solution for 9% Nickel Steel: Reducing Cost for Clients with the World’s Largest Size, Sharing Technology with SMEs!

Following a long period of research, vessels with LNG fuel tanks adopting POSCO 9% nickel steel are finally being constructed. They are none other than ‘HL ECO’ and ‘HL Green’ of Hyundai Samho Heavy Industries. Both vessels are 180,000-ton LNG-powered bulk carriers where POSCO’s 9% nickel steel is applied as materials for their fuel tanks. At the end of this year, both vessels will be delivered to the shipowner, H-Line Shipping. Other than the fuel tanks, POSCO steel plates were used in the body of the ships as well. Put differently, these vessels are the achievements of full localization — from materials to fuel tank technology. And here is another special solution from POSCO. POSCO can produce 9% nickel steel of all thicknesses required for LNG tank production and also “ultra-wide & long” nickel steel as well!

Ultra-wide & long? What’s so special about that?

LNG tank producers manufacture the tanks with 9% nickel steel in flat form and weld them piece by piece to build the tank. However, welding is costly and takes a long time, which has a significant impact on the overall process. So, the issue for POSCO clients was this: ‘How do we reduce the number of weldings?’ Also, the welding material for 9% nickel steel is especially more expensive than conventional steel. That’s why POSCO developed large-sized products to reduce welding points and costs.

When making a tank of the same size, welding 30 sheets of steel would definitely be much more efficient in terms of time and cost than welding 50 sheets of steel.

POSCO currently produces the world’s largest 9% nickel steel for shipbuilding. After six months of R&D, POSCO established a system to produce a product of up to 4.3m x 20m, which previously was limited to 3.85m x 15m. POSCO’s own R&D was important, but what mattered more were the many tasks and regulations to be resolved so as to apply this product in the actual field. So POSCO proactively discussed the quality of nickel steel with the British LR (LLOYD’S REGISTER OF SHIPPING) classification and based on the result, carried out the tank design, structural feasibility review, and performance testing with Hyundai Mipo Dockyard. The COVID-19 pandemic almost precluded the joint research, but POSCO installed a conference calling system for the client and continued cooperation. As a result, the first batch of ultra-wide & long 9% nickel steel could be supplied successfully to Hyundai Mipo Dockyard in April!

So those LNG tanks must be under production now.

POSCO’s ultra-wide & long 9% nickel steel is used in producing LNG fuel tanks for Hyundai Mipo Dockyard’s 25,000-ton DWT carrier for petrochemicals. This carrier is equipped with a dual-fuel engine that can utilize both bunker fuel and LNG. It is like a hybrid car at sea. The vessel will be completed in March next year and delivered to the ship owner, Bermuda’s MERIDIAN.

I’ve heard that Korea is an LNG carrier powerhouse. I also heard that Korean shipbuilders received orders for 118 out of 124 LNG-powered vessels from shipping companies around the world in the last three years — from 2017 to 2019. Now with these LNG tank materials and technology, Korea’s competitiveness is bound to become stronger!

You’re right. POSCO is looking for ways to keep growing together with SMEs who are producing LNG tanks as well as major shipbuilding companies. To help SMEs overcome the long-term recession in the shipbuilding industry, POSCO is providing them with the application technology of 9% nickel steel and high manganese steel on LNG fuel tanks free of charge. POSCO shares processing and welding technologies of 9% nickel steel and high manganese steel and invites global shipping companies to promote the products by SMEs in Korea. Thus, a stable industrial ecosystem where the mill, SMEs, and shipbuilding companies work jointly is created.

– Solution for High Manganese Steel: Breaking New Ground in the LNG Industry with New Material!

So you said that high manganese steel is a new product developed by POSCO, right? Then its application technology must have been developed from scratch.

Since high manganese steel was not a certified material in the LNG industry, it could not be applied to commercial projects in the beginning. So, POSCO worked on getting the material approval first, starting from the Korean Industrial Standard (KS) in 2014 to the American Society for Testing and Materials (ASTM) in 2017 and the International Organization for Standardization (ISO) in 2018, respectively. The first case of high manganese steel applied successfully to LNG tanks is “Green Iris,” Korea’s first LNG-powered vessel, built in 2017. This vessel was built jointly by POSCO and Hyundai Mipo Dockyard and was spotlighted since it was the “world’s largest” LNG-powered bulk carrier that adopts POSCO-developed high manganese steel for the “first time in the world”. Currently, the vessel is in operation on the sea, transporting limestone from Gangwon Province to Gwangyang Works.

So LNG tanks made of high manganese steel are already being used? The progress has been made rapidly!

Recently, an onshore LNG storage tank made of high manganese steel has also commenced commercial operation. In its initial stage, high manganese steel was not registered on the domestic standard or LNG terminal-related design code, so it was necessary to revise the standards first. To verify the safety of these onshore LNG storage tanks adopting high manganese steel, POSCO even constructed and operated a pilot tank.
The test was conducted supposing that the life of the tank is 50 years. The process of filling the tank with LNG and draining it was repeated more than 1,000 times. After the test, the tank was disassembled, and technical evaluation confirmed that there was no problem with the performance of the high manganese steel. In 2019, the Korean Gas Technical Standards Committee listed high manganese steel on the KGS code as verified material for onshore LNG storage tanks, thus enabling commercialization. Soon after, tank No. #5 at Gwangyang LNG receiving terminal was constructed with high manganese steel, with a storage capacity of 200,000 ㎘, and it has been under operation since last April.

▲ POSCO high manganese steel was applied to the LNG fuel tank of Green Iris (left) and the tank No. #5 at Gwangyang LNG receiving terminal (right)

– Solution for STS304L: Developing Independent LNG Storage Tank Model with Stainless Steel!

Another significant achievement is an independent LNG storage tank model made with POSCO STS304L. This model is ‘SOLIDUS’ of Daewoo Shipbuilding & Marine Engineering Co., Ltd. SOLIDUS adopts double stainless steel barriers to prevent LNG leakage and maximize safety. This design technology also obtained certification — to be suitable for application in actual LNG carriers — from the top 5 major global ship classification companies, such as LR (U.K.), ABS (U.S.), and DNV-GL (Norway). POSCO conducted various performance tests of STS304L in an LNG storage environment to support the development of SOLIDUS by Daewoo Shipbuilding & Marine Engineering Co., Ltd.

The cooperation between POSCO and its clients is bearing fruit. It seems that POSCO has succeeded in capturing eco-friendliness and technical competitiveness at once! Will there be more to expect?

POSCO is participating in a study to construct the 6th LNG storage tank at Gwangyang LNG receiving terminal by upgrading its high manganese steel technology. The company also plans to utilize the technology for overseas projects once the international design code has been revised. Recently, a major European oil company that reviewed the application of high manganese steel showed a favorable response for its competitiveness at “Gastech 2020,” an international gas conference. In addition, POSCO is joining forces with its clients so that 9% nickel steel and STS304L can also be the key to the development of LNG tank technology.

When it comes to energy, the first things that come to mind would be fossil fuels, coal and oil in particular. These two most common energy sources aren’t considered Sustainable. On the contrary, the next most frequently used energy source is Liquefied Natural Gas (LNG), and this is referred to be Sustainable!

l Liquefied Natural Gas Emerging as a Major Energy Source

Do you know anything about LNG? I heard that LNG is made by liquefying natural gas and also that this LNG will become the next generation energy source. Am I right?

Yes, you are right. At present, there are many POSCO’s customers engaging in the LNG industry, ranging from LNG vessels, LNG tanks, to LNG equipment. And they strongly insist that LNG will become the next ‘major’ energy source. In fact, the International Energy Agency (IEA) announced that, in the future, LNG will overtake coal as the second dominant energy source following crude oil. In 2019, the global demand for LNG reached 359 million tons, a 12.5% increase compared to 2018, and some predict that it will increase to 700 million tons by 2040.

What is the reason for all this?

sss

What matters are environment and safety. These days, we are slowly getting rid of products and technology that aren’t Sustainable. Coal and crude oil — the most commonly used energy sources — are fossil fuels and emit fine dust (PM 2.5), sulfur oxides (SOx), and nitrogen oxide (NOx) when utilized. Hence, both energy sources are far from being Sustainable. In the case of nuclear power plants, safety became an issue after the Fukushima nuclear disaster. Of course, there are other renewable energies like wind and solar power, but they are still insufficient to replace fossil fuels entirely.
In the case of LNG, dust, sulfur, and nitrogen are removed during the liquefaction process, so when it is burned, pollutants can be significantly reduced compared to other fossil fuels. It is also lighter than air, so in case of a leakage, it can be blown away easily. The chances of an explosion are also low since its ignition temperature is high. Those are the reasons why LNG has been spotlighted these days.

l LNG, How Helpful Is It to the Environment?

I heard that demand for LNG-powered vessels has increased dramatically in the shipping industry because of the new regulations issued by the International Maritime Organization (IMO) 2020. I guess that is why?

You know that EV, hydrogen cars, and hybrid vehicles are popular these days, right? But did you know that the amount of SO₂ emitted by the top 15 large vessels adds up to more than all vehicles combined worldwide? No wonder why the transition from bunker fuel-powered vessels to LNG-powered vessels is in progress.

Then can you compare the environmental impact of LNG-powered vessels and bunker fuel-powered vessels? I want to check whether LNG is indeed Sustainable.

OK! Let’s take the ‘Green Iris’ vessel, propelled by LNG, as a model vessel and compare the two following cases: a) when operated on LNG with a fuel tank made of 9% nickel steel, high manganese steel, and b) when operated on conventional bunker fuel with a fuel tank made of regular steel plate.
Let’s suppose that the vessel takes a round trip from Busan Port to the Port of Singapore once a month for 25 years. The environmental impacts include not just the operation period but the manufacturing stage with 9% nickel steel, high manganese steel, and regular steel plate as well. Setting the conventional bunker fuel as 100%, let’s take a look at the level of acidification, global warming, and resource consumption of LNG.

Wow. The acidification effect of LNG-powered vessels is almost halved compared to that of bunker fuel-powered vessels. While the level of global warming and resource consumption goes down to 73% and 64%, respectively.

Can you see how beneficial it is to use LNG in the long run? The main reason why regulation was enforced on bunker fuel is because of SOx, and, in LNG, the amount of SO₂eq emission — including SOx — is slashed to 630 tons, the half of 1,220 tons emitted by the bunker fuel scenario’s.

SOx? Doesn’t it precipitate fine dust? So, utilizing an LNG-powered vessel can help reduce almost 600 tons per ship!

Also, the emission of greenhouse gases (CO₂eq), such as carbon dioxide, a major cause of global warming, amounted to 360,000 tons in the bunker fuel scenario and 264,000 tons in the LNG applied scenario. It shows that an LNG-powered vessel can reduce carbon dioxide emissions by about 90,000 tons compared to a bunker fuel-powered vessel. Imagine that this 90,000 ton is discharged into our planet. One pine tree can absorb about 6.6 kg of carbon dioxide per year, so 90,000 tons is equal to the amount that can be absorbed by 13.6 million trees for a year.

What? 13.6 million trees? That’s a LOT. Then, what is this resource consumption impact?

sss

Resource consumption indicates the degree of natural resources depleted due to the consumption of fossil fuels. The index is not simply based on how much natural resource is consumed quantitatively, but it also takes into account how many of these natural resources remain. Hence, it could provide us with information beforehand so that no excessive resources are consumed. The higher the number, the greater the degree of depletion. And as demonstrated here, LNG has less impact on resource consumption than bunker fuel.

l LNG, How Helpful Is It to the Environment?

sss

If LNG is that good, why do we keep using coal and oil until now?

That’s because we lacked the technology to apply it. A downside of LNG is that its liquefaction process, transportation, and storage are quite tricky. Since LNG required enormous investment to create a value chain such as processing and transporting, it did not receive much attention in the past. Natural gas needs to be cooled down to below -163 degrees Celsius to become LNG. And it took quite a long time to develop technologies and materials suitable for this condition.

You mean that we produce the gas in gas fields, liquefy, and use it in liquid form? I heard that the city gas we use is LNG, but isn’t this in gas form?

Well, the supply chain of LNG is quite complicated. First, the natural gas produced at gas fields is shipped to the LNG liquefaction plant via pipeline. Here, the gas is liquefied and formed into LNG. This LNG is then transported with a specialized vessel called an LNG carrier, and when the LNG arrives onshore, it is stored in the LNG storage tanks at the LNG terminal, where it is vaporized into gas once again. Finally, it is sent to power plants or city gas companies through a pipeline.

sss

Wow. I didn’t know that LNG goes through so much before we get to use them. So I guess it requires advanced technology as well?

Yes, it does. The core technology is about tank design. And among other things, the material would be the most crucial part. The first LNG plant to be built on a commercial scale was the Cleveland plant in the U.S. in 1941. However, the plant was shut down in 1944 due to the destruction of the LNG tank during operation. The material used in making the LNG tank was known to be vulnerable to low temperatures, and it was one of the reasons why the LNG tank was damaged.

sss

I guess research on LNG tank materials wasn’t active back then. So we need a material that is strong enough to be used at very low temperatures.

When you apply force to an object, it withstands to a limit, deforms, and eventually breaks. Most materials become weaker at low temperatures. You must have seen that when an object quickly freezes, it tends to break easily. When LNG is unloaded and stored, its temperature changes rapidly — ranging from room temperature to below -163 degrees Celsius. And of course, the LNG tank should be able to withstand such dramatic temperature changes. Also, the material should have excellent machinability and be cost-efficient so that it can be fabricated into the desired structure.

Then we cannot use normal steel to make LNG tanks, right? What should we use then?

This is where POSCO’s steel solution steps in! Let me introduce you to the details from now on.

sss

☞ See [GPS] #2 POSCO’s Solution for the LNG Industry! (ep.2)