The present invention relates to a fuel storage tank arrangement in a marine vessel. More particularly, the present invention relates to such an LNG-fuel storage tank arrangement that has the various LNG-connections on top of the fuel tank. The fuel tank arrangement of the present invention covers both LNG-cargo tanks for transporting LNG and LNG-fuel tanks for providing the engine/s of the marine vessel with fuel.
The use of LNG (Liquefied Natural Gas) as fuel for marine applications is increasing since it is an efficient way of cutting emissions. Within the next few decades, natural gas (NG) is expected to become the world's fastest growing major energy source. The driving forces behind this development are the depleting known oil reserves, increasing environmental care and the continuous tightening of emission restrictions. All major emissions can be significantly reduced to truly form an environmentally sound solution; the reduction in C02, in particular, is difficult to achieve with conventional oil-based fuels. NG consists of methane (CH4) with minor concentrations of heavier hydrocarbons such as ethane and propane. In normal ambient conditions NG is a gas, but it can be liquefied by cooling it down to −162° C. In liquid form the specific volume is reduced significantly, which allows a reasonable size of storage tanks relative to energy content. The burning process of NG is clean. Its high hydrogen-to-coal ratio (the highest amongst the fossil fuels) means lower C02 emissions compared with oil-based fuels. When NG is liquefied, all Sulphur is removed, which means zero SOx emissions. The clean burning properties of NG also significantly reduce NOx and particle emissions compared with oil-based fuels. Particularly in cruise vessels, ferries and so called ro-pax vessels, where passengers are on board, the absence of soot emissions and visible smoke in the exhaust gases of ship's engines is a very important feature.
LNG is not only an environmentally sound solution, but also economically interesting at today's oil prices. The most feasible way of storing NG in ships is in liquid form. In existing ship installations, LNG is stored in cylindrical, single- or double-walled, insulated stainless steel or 9% Ni— steel tanks.
A feature common to such LNG fuel storage tanks is that they are traditionally provided with a so-called dome on top of the tank. All connections between the tank interior and the external fuel systems are located in the tank dome. In other words, the deep well pump used for discharging the LNG from the tank is attached to the dome as well as the connection for bunkering the LNG into the tank, connection for removing the boil-off gas (BOG) and the connection for the LNG-sprays arranged inside the tank. Also a number of valves arranged in connection with the connections may be positioned in the nearhood of the dome above the tank.
What makes the dome extending upwardly from the tank and especially the deep well pump attached to the dome problematic is the space they require in the vertical direction above the tank. The problem appears at its worst in connection with LNG tanks arranged inside a marine vessel between the decks thereof. Sometimes, i.e. when the LNG tanks are on the first deck below the uppermost or main deck, the problem is solved by arranging an opening for the dome and the equipment in connection therewith in the uppermost deck, whereby the pump motor and the rest of the equipment are visible on the uppermost deck.
However, the same practice may not be applied when the LNG tank is positioned, for instance, below the lowermost car deck of a car ferry, but the diameter of the LNG tank has to be reduced such that the dome with the equipment in connection therewith fits between the tank and the deck thereabove. In other words, in this kind of cases the overall height of the LNG fuel tank has to fit between two decks of a marine vessel. In practice, such an arrangement means that the storage volume available for the LNG is significantly reduced as there has to be room left between the top of the LNG tank and the upper deck for the deep well pump, the dome and the connections in connection therewith.
All pipe connections on an LNG storage tanks have to be installed inside a secondary barrier. Secondary barrier is the liquid resisting outer element of an LNG-cargo or LNG-fuel containment system designed to afford temporary containment of any envisaged leakage of liquid fuel or cargo through the primary barrier and to prevent the lowering of the temperature of the ship's structure to an unsafe level. This secondary barrier is typically made of stainless steel. The flows in the various pipelines in connection with prior art LNG fuel storage tanks are controlled by valves that are arranged on the top of the tank or tank's dome inside the secondary barrier, therefore taking additional space in height in order to also accommodate the secondary barrier.
The flows in the various pipelines in connection with prior art LNG fuel storage tanks are controlled by valves that are arranged either on the top of the tank's dome, therefore taking additional space in height, or in a tank connection space at the end of the LNG fuel tank. It means that the pipelines are taken from the dome at the top of the LNG fuel tank to the end thereof in the tank connection space, and in some cases the same fluid that is taken from the dome is returned back to the dome from the tank connection space. In other words, for instance if the LNG in the tank is pumped out of the tank to be returned into the tank via the spray nozzles for temperature control purposes, the LNG is, in accordance with prior art, taken in vain to the tank connection space. Such unnecessary circulation not only increases pumping losses but also increases conveyance of heat in the LNG tank. Additionally, the classification rules require that all shut-off valves have to be installed as close as possible to the tank penetration, which is difficult in prior art.
EP-A2-1351013 discusses a container for holding a solid, liquid and/or gaseous phase product therein and for use within a transportable or stationary support structure. The container maximizes the compressed product volume contained therein and prevents liquid and/or contaminant entrainment during gaseous product delivery from liquid phase product.
U.S. Pat. No. 5,097,976 discusses a fluid containment apparatus including a fluid tank, a well wall and a closure system. The tank has a tank shell, which defines at least in part a fluid containment compartment and has a tank shell opening therethrough. The well wall is secured to the tank shell, positioned at the shell opening, recessed into the fluid containment compartment and defines at least in part a recessed well.
EP-A2-1347231 discusses a system for the transportation and storage of a product comprising a tank including a cylindrical wall section and two ends which define a cylindrical tank periphery, wherein the tank periphery has an interior and an exterior; a recessed valve box including one or more side walls, a bottom wall, and a removable, sealable top cover which can be attached to the one or more side walls to seal the valve box, wherein the valve box side walls are sealably joined to the cylindrical wall section such that the valve box extends through the cylindrical wall section into the interior of the tank periphery and is partially or totally disposed in the interior of the tank periphery; and one or more valves disposed in the valve box.
Thus, in view of a practical aspect, an object of the present invention is to design a novel LNG fuel tank arrangement for a marine vessel, the novel LNG fuel tank arrangement solving the above discussed problems relating to the overall height of an LNG tank and to the positioning of the flow control valves.
Another object of the present invention is to offer a novel LNG fuel tank where the deep well pump used for pumping LNG out of the fuel tank is arranged in a recess arranged at the top of the LNG fuel tank.
A further object of the present invention is to offer a novel LNG fuel tank arrangement where the valves controlling the flow tank are arranged in a recess arranged at the top of the LNG fuel tank.
At least one object of the present invention is substantially met by a fuel tank arrangement of a marine vessel comprising a fuel tank for Liquefied Natural Gas (LNG), the fuel tank comprising a shell, a heat insulation in connection therewith, connections for a pipeline for bunkering LNG to the fuel tank, a pipeline for taking boil-off gas from the fuel tank and a pipeline for taking LNG from the fuel tank, a deep well pump for pumping LNG from the tank to the pipeline, at least one recess extending inwardly from the shell and being arranged on top of the fuel tank, the deep well pump being installed in the at least one recess, the recess having a bottom and a side wall, the deep well pump comprising a pump, a riser and a drive motor, the riser passing through the bottom, wherein the drive motor of the deep well pump is located at least partially inside the recess.
Advantageously, the above discussed fuel tank arrangement allows the installation of the deep well pump and especially its drive motor at least partially within the outer dimensions of the LNG fuel tank, whereby the vertical space required by the deep well pump is reduced. Therefore the need for reducing the diameter of the LNG fuel tank to be able to fit the LNG tank between two decks in a marine vessel is avoided.
In the following, the present invention will be described in more detail with reference to the accompanying exemplary drawings, in which
On top of the LNG fuel tank 10 a dome 16 projecting radially upward from the shell 20 is provided. The dome 16 is provided with openings in which the pipelines 26, 28 and 30 connecting the interior of the LNG fuel tank 10 to the tank connection space 32 arranged at the longitudinal end of the LNG fuel tank 10. Pipeline 26 is used for removing boil-off gas from the LNG fuel tank, pipeline 28 for bunkering LNG into the LNG fuel tank 10 and pipeline 30 for feeding re-condensed LNG into the LNG fuel tank via a spray header 34 and spray nozzles 36.
The dome 16 is further provided with a deep well pump 38, which is, for example, formed of a centrifugal pump 40 arranged at the lower end of a riser 42 close to the bottom of the LNG fuel tank 10. The deep well pump has further at the upper end of the riser 42 a drive motor 44, normally an electric motor that extends, in practice, 1-2 meters above the dome upper surface, depending on the diameter of the LNG fuel tank 10. The riser 42 between the dome 16 and the drive motor 44 is provided with a pipeline connection 46 for discharging LNG from the fuel tank 10 to the tank connection space 32. The drive 44 of the deep well pump 38, the dome 16 and the pipelines leading from the dome 16 to the tank connection space 32 are enclosed within a secondary barrier 48. The tank connection space 32 may include, among other equipment, valves (not shown) for controlling the flows in the pipelines 26-30 and 46, and a vaporizer for delivering the LNG to be used as a fuel in one or more internal combustion engines of the marine vessel. In another option, when the tank is simply a cargo tank for transporting the fuel the tank connection space does not have the vaporizer, but the pipeline connection 46 is used for unloading the LNG fuel from the tank.
However, contrary to the prior art LNG fuel tanks, the LNG fuel tank 50 of the present invention is not provided with a dome extending radially upwardly from the outer shell, but a corresponding recess 56, tub or pool, i.e. a kind of an inverted dome, that provides room for the pipeline connections 68-72 and the deep well pump 78 within the shell 60 of the LNG fuel tank 50.
The recess of
The above discussed instrumentation, i.e. the pipelines and the valves, has to be arranged within a secondary barrier 100 such that only pipeline 68 for bunkering the LNG, pipeline 70 for discharging the boil-off gas and pipeline 86 for taking the pumped LNG to the vaporizer are taken out of the secondary barrier 100. The discussed instrumentation may fit entirely into the recess 56, it may be partially positioned outside the recess 56, or it may be positioned entirely outside the recess 56. However, preferably at least one of the valves is located inside the recess. Thus the positioning of the instrumentation depends totally on the size, i.e. width and depth of the recess 56. However, it is essential for the operation of the invention, i.e. for solving the problem leading to the present invention, that the deep well pump is arranged in the recess 56. The recess may not necessarily be so deep that the pump (or rather, its discharge connection and drive motor) is totally housed in the recess but, in any case, a substantial share of the vertical height of the deep well pump is fitted in the “inverted dome”. In other words, the drive motor is, in accordance with a preferred embodiment of the present invention, located at least partially inside the recess. Thereby the diameter of the LNG fuel storage tank 50 may be, correspondingly, increased when compared to LNG fuel tanks of prior art.
In view of the above it should also be understood that there may be not only one recess at the top of the LNG fuel tank but two or more recesses may additionally be provided. Naturally the recesses may be of different size/s as the one housing the deep well pump is obviously the deepest one, whereas the one/s housing the instrumentation may be shallower.
While the invention has been described herein by way of examples in connection with what are, at present, considered to be the most preferred embodiments of the present invention, it is to be understood that the invention is not limited to the disclosed embodiments, but is intended to cover various combinations or modifications of its features, and several other applications included within the scope of the invention, as defined in the appended claims. It should be understood that the tank arrangement comprises several features which are not shown in figures for the sake of clarity, for example, all such equipment present in each tank arrangement that concern determining pressure, temperature or LNG surface level in the tank has not been shown.
Filing Document | Filing Date | Country | Kind |
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PCT/FI2015/050644 | 9/28/2015 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
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WO2017/055674 | 4/6/2017 | WO | A |
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Number | Date | Country | |
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20180266628 A1 | Sep 2018 | US |