Saturday, 19 September 2015

An Interview with Dr. Jan Emblemsvåg

Jan Emblemsvag
(Image Courtesy: www.emblemsvag.com)
"The dichotomy of theory versus practice is an artificial one – all practice is based on theory whereas not all theory is based on practice, which is why this dichotomy arose. The difference between modern approaches to leadership and management and other approaches lies in their relation to reality. Modern approaches are fact-based and driven by reality, and so am I." says a note on his website

Jan Emblemsvåg is the SVP of Ship Design and Systems at Rolls-Royce Marine. The acclaimed corporation which has delivered the most ship designs over the years for the world offshore market, major designs in fishing vessel technology and merchant vessels. The corporation has also ventured into special purpose vessels and ship conversion projects.

In this interview with Learn Ship Design, we get to know about Rolls Royce Marine and it's operations. He speaks about Managerial challenges, his work on the Life Cycle Costing Approach, keeping pace with changing trends and what makes Rolls Royce Marine a leader in it's game.

Rolls Royce Marine seems to provide top notch solutions, be it with regard to pure raw power of drill-ships or the demanding precision of research vessels. But, it also amazes to witness the prowess in mainstream application of alternate fuels and the proposed mass automation (drone ships) in ship design. What drives this immense initiative? Please tell us about your experience.

Rolls-Royce Marine (RRM) has a large network in the market so we quickly hear about new ideas, new needs or new trends in general.  This, in combination with highly skilled employees, we have a very good breeding ground for innovation.  Why there are so many, is a good question. It is probably a mix of a willingness to try out new things and the fact that RRM indeed has very wide product portfolio so that there is a large opportunity for innovation.

Would you like to comment on how your work at Rolls Royce Marine and the unique challenges faced in the shipbuilding industry is honing your managerial skills in its own unique way?

The shipbuilding industry, for which we deliver ship design and equipment, is a volatile industry with focus on personal relations (due to the risk level – do you trust your business partner to deliver?) and complex projects with significant risks. RRM is a wholly owned subsidiary of Rolls-Royce plc which is traded at the Financial Times index in London. Stock markets typically want steady growth etc. This creates a unique mixture of apparent contradictions, which I personally believe is a great opportunity of innovations.  As a manager I must therefore try to handle a very large variety of issues – something I find very challenging, interesting and stimulating personally.  My level of performance must someone else talk about. 

Can you give our readers a brief gist about the Life-cycle costing approach and the Monte Carlo method and how we can use them in the maritime industry?

Activity-Based Life-Cycle Costing builds on Activity-Based Costing (ABC) and Life-Cycle Costing (LCC) and it uses Monte Carlo methods to power the approach, so to speak.  From ABC we get the focus on process, correct cost assignment, correct handling of overhead costs and more, from LCC we get the life-cycle perspective and the importance of handling risk and uncertainty and the Monte Carlo methods allow us to make huge models and realistically model risk and uncertainty as well as tracing key success factors.  The approach can be used for all kind of applications to calculate costs, profitability and so on.  Concrete examples can be to calculate the profitability of a contract for a ship owner, use the model and tie it to design changes so that design can be improved before they are built.  This can concern ships, oil rigs and any asset expensive enough for the cost of creating such a model.  The most important aspect of what it can be used for, however, is the availability of data.  This said, the Monte Carlo methods reduce the need for accurate data as long as the data is somewhat consistent. 

What are the main aspects one should keep in mind while evaluating the profitability of a ship/offshore design?

The single most important element in this industry is risk due to its volatility, and therefore flexibility/robustness is critical in the design particularly for offshore- and special purpose vessels.  The risk element is the reason why personal relations are so important – ship owners must feel they can trust the shipyard, the designer and the equipment maker.  There is too much at stake – this is critical the more expensive the assets. 

Given a possibility in the future, how would Rolls Royce Marine respond to providing solutions for a cruise industry linking India, knowing its untapped potential and exciting challenges?

We have had projects in India for several decades so it is a very interesting market.  With my experience with the maritime sector in India, however, cruise vessels do not seem to be a wise place to start.  We are developing designs that are medium spec’ed and easier to build while maintaining many of the quality hallmarks.  We are happy to assist Indian shipyards building UT- and NVC designs. 

While Rolls Royce Marine has been doing reasonably well like we said earlier, there is still a lot of potential remaining to be tapped. Will it be able to match the prowess of the aerospace division in the coming years?


The two markets are fundamentally different.  Aerospace is an industry with very high entry costs so that once you are established you are among very few.  This makes the industry easier to be big in, then in the marine industry where entry costs are much lower and margins are under heavy pressure these days due to the low oil price.  However, we have a lot of untapped potential but matching aerospace will probably be hard.  

Ship design is still transitioning from a rule based design methodology to risk based design methods. How far has your organization been able to adopt the factors of risk assessment into the process of ship design?

We use it to some extent, but the adoption rate varies considerably except where it is mandated by class for which we fully comply, of course. Class notations are vital in our business. 

On a different note, please tell us about your time with students of Management Science. Especially about the skills you deem are vital among management personnel in the field of ship design.

Irrespective of industry, I think an important trait of a good manager is the willingness to always learn something new, constantly reading and updating himself so that he does not become outdated and falls behind. Another important trait is the ability to use facts to solve problems instead if going with the guts all the time. Sure, gut feeling will be an element in many cases, but it has to be aided by facts.  However, what must never be underestimated is the ability to handle people.  Brilliance in subject-matter, but lack of people skills, will imply that this person is suitable for technical work and not management.  Therefore, I look for students that are fact-based and willing to question things and learn new things.  Good humour at own expense and humility are also important traits. Leadership potential is severely restricted in people that constantly have to prove how smart they are because I know from experience that such people will fail as leaders. 

Last question to you, the questions for this interview have been framed by eager students and budding engineers in the field of Naval Architecture, who have looked forward to interacting with you through this interview. What message do you have for them?

I hope you all find something useful in my answers, but more importantly; keep on learning the rest of your lives about management, philosophy and other topics NOT related to engineering or naval architecture– then you can contribute more widely as well and build your career.  

To know more about Dr. Emblemsvåg and his work, you can visit his website:  www.emblemsvag.com

The picture used above does not belong to LSD, and full credit for the same goes to the respective owners. 

Sunday, 6 September 2015

Types of Offshore Structures

Last time, we were introduced to the design and operational considerations of offshore structures. Now, we will take look at the different types in existence today. Before we go into that, take a recap of the previous article here. Also, you might want to see how fierce the environmental conditions can be in this video given below:



Broadly, offshore structures maybe of two types:

  1. Floating - These offshore platforms are floating in free surface and are movable from one location to another. Examples include semi-submersibles, SPAR platforms, Floating-leg platforms, drill-ships, FPSOs(Floating Production, Storage and Offloading systems)
  2. Fixed Platforms: They are immobile and fixed permanently to one place. These sorts of offshore units have greater strength and relative durability as compared to floating ones. These are operationally irreversible as once installed they cannot be relocated . Examples are Concrete/Gravity Platforms, Jacket Platforms,Tension-leg platforms(TLPs), Jack-Up Rigs etc. 
Fig.1:Image of  a deep-sea offshore installation (Courtesy: www.nyborgfan.com/)
Surveillance of the sea-bed and that of the underlying rocks helps in the development of the strategic sites for the optimum extraction of the resources. Furthermore, the oceanographic and climatic conditions around that region are assessed. Then the topographic conditions pertaining to that particular region along with the critical risk factors probable to the given sea-state gives the outline for the apt installation for the site. The offshore structures maybe mobilized from one site to another, may be erected after compilation of the raw materials and parts or maybe made from scratch at the purported site itself depending on its nature. 
As these offshore structures are high-budget, heavy-duty and long-term projects, umpteen care is taken to ensure its livability in hostile sea state and its long term life span.


Fig.2:Image of  a semi-submersible offshore installation (Courtesy: www.offshoreenergytoday.com/)



Jacket Platforms
                                       
These platforms are quite common and comprise of an outer jacket-like structure of welded tubular steel. Steel jackets are vertical sections made of tubular steel members, and are usually piled into the seabed. The pipes are about 1 to 2 m in diameter and have a maximum penetration of about 100 m. They weigh about 20000 tonnes. This external steel jacket has many functions ranging from stability and supporting the entire structure to protecting the internal piping and drill equipment from external disturbances.

Design Parameters 

These steel jackets have tapering, truss-like structure with high strength, durability and fatigue resistance.Loading and life cycle apart from diameter, penetration, thickness and spacing are taken into account. 
  • In a typical design , the cross-sectional dimensions are about 70*65 at the seabed and 56*30 at the top. 
  • They have capacities of resisting forces up to 50 MN in compression and 10 MN in tension and has a large vulnerability to lateral loads like expansion and hydrodynamic stresses. 
  • They also have a maximum permissible overturning moment up to 10 GN.m in most cases.   
The jacket design and the pile design are the crucial factors in determining the total performance of the structure and the total cost in its design and maintenance can devour up to 40-50% of the total cost estimation. 
One point to ponder upon in jacket structure is the protection of the steel from rust and corrosion, a "disease" of all marine vehicles and structures which is principally to be taken care of . This can be done up to a certain extent by using high-grade "stain free" steel and by repeated cathodic protection. 

Jack-Up Rigs

Jack-Up drilling rigs are a type of self-elevating, mobile platform capable of raising the hull part which is obviously buoyant above the sea level and penetrating its steel legs into the sea-bed for support for deep sea drilling operations. The name "jack-up" is derived from versatile nature of the legs or jacks which can be suitably jacked above or below the hull accordingly when not in operation and when in operation. 
These Legs maybe piled into the sea-bed or maybe placed on large footings for better grip and stability. There maybe three or four legs for jacking up the buoyant hull above the sealevel for operations. After a stipulated time period after termination of the operations at a place, the legs are dismantled from the sea floor and are jacked above the hull and the entire unit is mobilized to another destination maybe to some jetty/port or to another drilling site. They are not self-propelled and usually depend on tugs of Heavy Lift Ships for towing from one place to another.
Well when and where can jack up rigs be used? The answer IS that they maybe used in shallow waters as pre-operation and post-operation mantling and dismantling of the jack ups are very bleakly feasible in deeper waters. The steel legs are of high strength HSS steel and are  designed to confront wave dynamics even in rough seas up to a certain limit. Care must  be taken for their maintenance in terms of corrosion, fatigue, stresses. In case of sea or external parameters going beyond the tolerance level, these are immediately "jacked up" and are shifted to safer locations or kept in a safe nonoperational, dormant mode. 
Jack -Up rigs are used specifically for oil well drilling purposes and has limited or no storage capacity. Storage or bulk transport may be through oil tankers or the multi-purpose FPSOs (Floating Production, Storage and Offloading Units).  

 Fig.3: Basic Components of a Steel Jacket Offshore 
Structure (Copyright: Maersk)    
 

Concrete Platforms/Gravity Platforms

Concrete Structures are purely composed of concrete and is considered the safest mode of offshore industrial operations. They maybe directly fixed or molded to the sea floor on a permanent basis or maybe floating. 

Fixed ones are also known as Gravity-based structures or the Caisson type. The entire structure is based on a submerged island-like solid structure which may serve as a foundation structure as well as storage or oil or other by-products. The entire load of the structure acts directly on the subsequent  layers of the sea-bed eradicating problems even of the extreme wave disturbances or seafloor scour. On the other hand the floating ones are freely float-able and has six degrees of freedom under a proper mooring system.  

Some designs of these concrete structures are Condeep, ANDOC, Doris and so on. The design parameters are guided by the number of supporting columns and the diameter of the legs. Constructing is a tedious process where the entire structure or its components are towed and assembled with proper ballasting and de-ballasting measures. They have almost negligible maintenance and high durability. Can be also used for greater depths. 
             
               

Fig.4: Garvity based Offshore Structure 
(Courtesy: www.paroscientific.com/)
Fig. 5: Concrete fixed platform (Courtesy: www.wind-energy-the-facts.org)

Compliant Towers 

Whenever the word "compliant" comes to our mind we mean a sense of complying or yielding. These are tall, slender, single isolated structures with high slenderness ratio.
They are comprised of specialized flex tubes of 2 to 7 metres in diameter comprising the space-time frame-like truss  with high degrees of flexibility and can withstand high amounts of lateral loads up to 10 feet  due to waves or oceanic disturbances. 

The rig consists of narrow, flexible (compliant) towers and a piled foundation supporting a conventional deck for drilling and production operations. They are mainly operated in depths upto 1500 to 3000 feet. They inherently have a frequency lower than the natural frequency of the waves, such that with the emergence of any wave disturbance can make it oscillate with a resultant frequency safer for the loads and eradicate the probability of any resonating conditions. They work on a principle of de-amplification of waves dissipating the energy responsible for creating greater mayhem. Hence they are applicable for high tide or even the worst sea conditions.The lower part of the frame depends on the pilings and can penetrate hundreds of feet below the mud line. 


 Fig.6: Different Compliant Structures through the years (Courtesy: www.atp.nist.gov/)

Tension-Leg platforms

These are floating facilities which stay afloat and remain in position with the help of specialized steel tubes called tethers or tendons. These are nothing but the supporting legs of the floating platform which by the virtue of their upward tension takes care of the position, loading and the functionality of the extraction system. For all such tension leg platforms there is not much vertical oscillatory motion of the platform how rough the sea conditions or the average wave height may be. This facilitates in tying with the wellheads and the piping system for extraction of oil without much distortion. for all such systems there is always an additional buoyant force which keeps the platform afloat. Thus for all such installations,


Tension =Buoyancy - Weight

Here topside facilities and the basic parameters like the number of risers have to be fixed at pre-design stage. Generally the platform is manufactured on the shore and is towed to the desired location with the help of tugs. This structure is apt for depths up to 1200 metres and has limited or no storage facility. As of common usage, these have a high maintenance and surveillance cost of the tethers and under unavoidable circumstances the structure may be prone to irreversible damage. 
          
                                            

Fig. 7: Structure of a typical tension-leg platfrom (Courtesy: www.slideshare.com)


Semi-Submersible

They are floating installations which rest on four or six pillar-like legs called columns with a equal weight distribution on each. These columns or legs are in turn attached to large basements called pontoons floating on the water surface. These pontoons may be ballasted or de-ballasted accordingly on and off operations. Often these pontoons delve deeper under the water surface and maintain the buoyancy and position of the floating system. There is always a greater draft. Thereafter the operational deck is kept well aloof from the wave disturbance or the rough seas.However due to small waterplane area the structure is sensitive to load variations and must be trimmed accordingly. They by the virtue of their equivalent weight distribution and a high draft, it has a greater stability than normal ships. The number of legs, pontoon design , the situation of the risers and drill equipment are decided at pre-design stage. They are generally instrumental in Ultra-deep waters where the fixed structures pose a problem. Their position is maintained generally by a catenary mooring system or sometimes in modern structures by Dynamic :Positioning System. These structures are gigantic and may be towed from one location to another by the virtue of a kind of ships called Heavy Lift ships. 

                                                                                  
Fig. 8: Semi-submersible Offshore Platform (Source: patentimages.storage.googleapis.com)


                                               
Fig. 9: Heavy Lift  Ship (Source: www.motorship.com)

SPARS


These have a large diameter cylindrical deck supporting the main deck .They are generally developed as oil platforms for deeper waters as an alternative to the conventional systems. Most of the drilling and oil extraction equipment are situated within them. The inside part of the cylindrical truss is filled with some material denser than the sea-water to lower down the centre of gravity and hence maintain the vertical stability of the structure.  The deep draft design of spars makes them less affected by wind, wave and currents and allows for both dry tree and subsea production. The cylindrical structure is surrounded by helical strakes to avoid vortex-induced motion. 

The first prototype of the SPAR Platform was Neptune laid off the US coast in 1997. 

There are basically three types of spars, namely, truss spar, classic spar and cell spar. 

It is generally equipped with taut catenary mooring and the heave natural period is generally below 30 seconds. Generally , the  spar is employed for depths up to 2300 m. The number of risers is restricted generally due to the limited space of the core cylinder. These are highly stable and hence are negligible unaffected even on adverse sea conditions or sharp environmental vagaries.  

                                      

                                                   
Fig. 10: A typical deep sea SPAR Platform (Courtesy:www.maritimeconnector.com)


FPSOs

FPSOs stand for Floating, Production, Storage and Offloading Systems. It is a specialized vessel for the purpose of offloading, processing, storage, distribution of oil and other hydrocarbon resources. One important point to wonder is that these installations does not have anything to do with the extraction purposes and can be merely reckoned as a carrier with specialization. These vessels eradicate the need of long pipelines for transfer of oil and petroleum to the shore. FPSOs are preferred in frontier offshore regions as they are easy to install, and do not require a local pipeline infrastructure to export oil. FPSOs can be a conversion of an oil tanker or can be a vessel built specially for the application. A vessel used only to store oil (without processing it) is referred to as a floating storage and offloading vessel (FSO). These can operate extensively in remote and deep waters and also in marginal wells where fixed platform or piping is technically or economically not feasible. 
In majority of the cases the vessel may be buoyed to a vicinal drilling platform. Also the oil or other petroleum products maybe transported to the mainland by pipelines or by a conventional mooring system. The vessel may be fixed in a particular position by mooring lines or by a dynamic positioning system (DPS). 
                                    
                                                   
Fig.11: The ongoing operations to an FPSO and the production process

Fig.12: Floating production storage and offloading unit (Courtesy: www.alibaba.com)

These ships have an integral storage capability inside their voluminous hull and have a calculated freeboard and draught. They are operational in adverse weather  and have a high maintenance cost. 

Drill ships

It is a mobile offshore installation akin to a ship which is specialized for exploration and drilling of oil and gas resources more specifically for scientific exploratory purposes. Mostly, it is used for deep and ultra deep applications involving exploratory and drilling purposes. The first drillship was the CUSS I, designed by Robert F. Bauer of Global Marine in 1955. The CUSS I had drilled in 400 feet deep waters by 1957.Apart from regular drilling purposes, the drillship may also be used for maintenance and surveillance purposes such as casing and tubing installation, subsea tree installations or wellhead capping. Drillships though expensive and of high precision in operating and maintenance, is often believed to be the most proficient mode of offshore technology trend where like any conventional ship, it can be transferred from one place to another anytime and that too without the use of any tugs , heavy lift ships or any other towing system. However a mandatory mooring system should be kept or a DPS positioning system  should be employed. Generally, underneath the derrick through the hull is the moon pool which connects the deck to the sea directly. Sounds pretty interesting, isn't it ? The moonpool is generally an opening of the deck floor with the water in any marine research vessel, drillship, sometimes icebreakers, diving support vessel for easy exposure to the underwater environment or for the easy steup of the drilling equipment as done here. Generally moonpools are situated in four different positions, above the waterline, at the waterline, underneath the waterline or deep submerged depending upon the requirements, the vehicle or the design. So, for a drillship the moonpool provides easy accessibility for the drill equipment or manpower for the purpose of maintenance of the drill equipment or underwater survey. However immense care has to be taken during the design stage to ensure the moon pool compensates the loss of strength in the deck or hull, maintain stability and trim and avoid flooding or leakage. 

                                                              
Fig. 13: Different types of moonpools (Courtesy: www.wikipedia.com)




A simple way to understand what a drillship is to do in order to drill, a marine riser is lowered from the drillship to the seabed with a blowout preventer (BOP) at the bottom that connects to the wellhead. All this is done through the moonpool intricate to the hull. Drillships also have their own storage and processing system . However, in terms of positioning and stagnancy during drilling operations, the semi-submersibles have an upper hand. 

Fig. 14: A TIGER Series Drillship (Courtesy: www.offshoreenergytoday.com)

This was all about the common types of offshore structures in existence today.LSD


Article By: Subhodeep Ghosh