WO2011012307A1

WO2011012307A1 - Combustion-gas system, in particular for cargo vessels

Info

Publication number: WO2011012307A1
Application number: PCT/EP2010/004652
Authority: WO
Inventors: Olaf Beyer; Annette Kalsbach
Original assignee: Tge Marine Gas Engineering Gmbh
Priority date: 2009-07-30
Filing date: 2010-07-29
Publication date: 2011-02-03
Also published as: DE102009028109A1; EP2459922B1; CN102472430A; KR20120036334A; JP2013500192A; EP2459922A1

Abstract

The invention relates to a method for storing cryogenic liquid gas in a tank (1) of a transport means, in particular of a ship, having the following steps: removal of liquid gas from a storage tank, heating of the removed liquid gas, filling of the tank (1) of the transport means with the heated liquid gas by pumping the liquid gas into the tank (1) of the transport means. Moreover, the invention relates to a system, by way of which this method can be carried out, and to a ship having a system of this type.

Description

Fuel gas system, especially for merchant ships

The invention relates to a method and a system for storing cryogenic liquefied gas, in particular LNG, in a transport medium tank, which is used to drive the

Means of transport, in particular a ship, is provided.

In the course of the tightening of exhaust emission limits as well as the efforts, the emissions of harmful gases and in particular SO _x , CO ₂ and NO _x in particular by the

To reduce merchant shipping, systems are currently being developed to power natural gas trading vessels in so-called dual-fuel engines, which alternatively burn natural gas and heavy fuel oil and / or diesel oil or other facilities that use gas as fuel.

The prerequisite for gas operation is that appropriate quantities of gas can be bunkered on board. The required quantities depend on the type of ship and the ship. The requirements related to gas pressure, gas temperature and gas quality of the

Depending on the consumer used to depend on fuel gas.

Due to the low energy density of natural gas offers as a preferred storage form of the fuel gas liquefied natural gas, so-called LNG, which allows a relatively high energy density in the storage volume at relatively low pressure and cryogenic temperatures and thus the limited amount of space on board a ship, the required amount of energy available ship volume can be stored.

A LNG gas delivery system on a ship usually has the following components:

- loading system (bunker connection);

- LNG storage (designed so that ship parts adjacent to the storage volume do not run the risk of being exposed to extremely low temperatures, which would result in shipbuilding steel failure);

- Fuel delivery or pressure increase to the consumer pressure;

- Fuel treatment (adjustment of temperature and possibly quality);

- safety devices.

According to the prior art predominantly relatively small, vacuum-insulated cylindrical tanks are used as storage containers. The fuel treatment is carried out either by pumps installed in the tank by gaseous withdrawal vaporized LNGs and compression in Compressors or by increasing the pressure in natural circulation evaporators that require a bottom outlet of the tank.

The loading is done with so-called gas commuting. That is, the gas phase contained in the empty ship tank is displaced by refilled liquid LNG and returned by a second line next to the bunker line to the filling ship or storage tank.

In order to connect lines to a tank, a tank is usually provided with nozzles, are flanged to the lines. For safety reasons, it would be better to weld cables to a tank. In a conventional tank, however, this can not be done regularly in practice. For safety reasons, it is also advisable not to pass lines through a tank bottom or through side walls of the tank. Otherwise, a corresponding leak in the line in the tank area will cause the liquid in the tank to drain due to gravity.

Document EP 1 353 113 A2 discloses a system and a method for discharging gas tankers. The system includes a cargo tank with and a cargo tank without submersible pump. The cargo tanks are connected to each other via two pipes, one pipe being provided with a compressor. With the help of the compressor, a gas phase is pumped from the cargo tank with the submersible pump into the tank without submersible pump. As a result of the pressure increase in the tank without submersible pump, liquid from the tank without submersible pump passes through the further line into the tank with submersible pump. With the help of the submersible pump LPG is conveyed from the associated tank via a discharge line to a land plant. The system allows a suitable temperature control.

In another known method for filling a tank, for example, liquefied natural gas is filled into a tank via a first conduit. Boil-off gas produced in the tank is condensed by spraying cryogenic liquid into the gas phase via a second line. Boil-off gas generated in the tank therefore does not have to be removed from the tank. If necessary, LPG is taken from the tank via a third line. The document WO 2009/063127 A1 shows a tank installation with which such a method is carried out.

If gas in the tank is condensed during filling with liquefied gas in order to avoid overpressure in the tank, this limits the speed with which a tank can be filled with liquefied gas.

A conventional tank of the type mentioned above is regularly provided with 8 to 10 nozzles for the connection of pipes. Thus, for example, in WO 2009/063127 A1 pictured tank already on 6 lines that are connected for reasons of practicality by connecting the tank. In practice, in the case of the tank known from WO 2009/063127 A1, further lines will be required which were merely not shown.

In a tank of a means of transport, in particular a ship, the following lines or nozzles are required in practice for the connection of lines to the tank in practice.

A first nozzle or a line to be connected to it is needed to the

To fill the transport tank. A second port, another line is needed to unload the transport tank when there is a submersible pump in the transport tank. Thirdly, a connection for a spray line is required in order to be able to temper the tank appropriately and to condense boil-off gas. A fourth port is used to direct a gas phase out of the tank. Further nozzles are for

Safety valves and for the measurement of parameters such as pressure, temperature and level provided.

It is an object of the invention to provide an improved method and system for storing cryogenic liquified gas in a tank of a means of transport, in particular a ship. The term "storage" implies both the meanings "storage", ie "filling", as well as "outsourcing", ie removal, as well as "holding" or "containing".

To achieve the object, a tank of a means of transport is filled with liquefied gas, such as LNG, by heating the liquefied gas and pumping it into the tank after heating.

By heating, it is meant that stored liquefied gas is not merely pumped from a storage tank into the transport medium tank. Instead, liquefied gas is actively heated from the storage tank and is heated to the transport tank. An active heating in the context of the invention is when the liquefied gas originating from the storage tank is supplied with controlled heat, for example by mixing boil-off gas with the liquefied petroleum gas or by heating the liquefied gas originating from the storage tank with a heat exchanger and heating it Heat exchanger enters the transport tank.

The invention accordingly relates to a method for storing cryogenic liquefied petroleum gas in a tank of a means of transport, in particular a ship, comprising the steps of: removing liquefied gas from a storage tank, in particular from a stationary storage tank, heating the withdrawn liquefied gas, filling the tank of the means of transport the heated LPG by pumping the liquefied gas into the tank of the transport. Typically, for example, LNG is stored in a storage tank at a temperature of less than -161 ⁰ C, so as to be able to store LNG at normal pressure. For the same reason, the storage temperature of LNG in a ship's tank usually also at less than -161 ⁰ C. By heating now passes according to the invention significantly warmer liquefied gas in the vessel tank. The temperature of the heated LNG, for example, after heating instead of -163 ° C only -140 ⁰ C to -150 ⁰ C.

In particular, a system for filling and / or emptying a tank of a ship with LNG is provided for carrying out the method, for example with a tank for the tank

Storage of LNG whose design pressure (also called design pressure) is at least 5 bar g (bar gauge), preferably at least 10 bar g, the tank being provided with a cryogenic liquified gas inlet and an outlet for unloading the tank , wherein the inlet comprises means for heating LNG.

The invention thus also relates to a system for storing cryogenic liquefied petroleum gas for a means of transport, in particular for a ship, comprising: a transport medium tank for storing liquefied gas, an inlet device, for the removal of liquefied gas from a storage tank, in particular from a stationary storage tank, Means for heating the withdrawn liquefied gas, and a filling device for the tank of the means of transport with a pump for pumping the heated liquefied gas into the tank of the means of transport; as well as one

Means of transport, in particular a ship, with such a system.

Since there is still a liquid phase in the transport medium tank, for example in a ship tank, despite heating, there is an overpressure in the transport tank after filling. This overpressure is sought according to the invention, since it can be used to remove fuel from the tank without having to use a pump. The temperature of the liquefied gas present in the transport medium tank is preferably above the boiling point of the liquefied gas at normal pressure.

Since the overpressure is ready immediately, liquid gas can be taken immediately after filling, so after refueling about the ship, so as to be able to supply a drive with fuel gas. For example, a ship can continue its journey immediately after refueling without having to use a pump for the fuel supply.

In one embodiment of the invention, the liquefied gas has been heated by at least 10 ⁰ C so as to arrive at a desired bearing pressure. Such a temperature difference is regularly conducive to immediately a sufficiently high bearing pressure in the

To obtain transport tank for the described purpose; can also be beneficial

Warming by at least 15 ° C. In order to be able to remove a sufficient amount of fuel from the ship's tank immediately after refueling, which is required to be able to drive a ship, the bearing pressure in such a ship's tank is preferably at least 3 bar absolute; a pressure of more than 5 bar absolute or even 8 bar absolute can also be beneficial. So before that was the

LPG heated to a correspondingly high temperature.

In order to heat a liquefied gas, gas present in the ship's tank is added to the liquefied gas during filling, which is introduced into the ship's tank. As a result, the liquefied gas is not only heated, but condensed advantageous in the vessel's tank gas at the same time. The supply of the gas is preferably carried out in the supply line, via which the liquefied petroleum gas is pumped into the ship's tank. The feed advantageously takes place outside the ship's tank, specifically in a process space. Gas is thus sucked out of the ship's tank via a second line and pressed into the line, via which the liquid gas is pumped into the ship's tank. The originating from the ship's tank gas is mixed with the liquefied gas, in particular by means of a z. B. static mixer mixed. The mixer is also advantageously located in a process room.

Since with the help of the gas located approximately in the vessel tank, the LPG may only be heated by about 0.5 ⁰ C to 1 ° C and a heating of 0.5 ⁰ C to 1 ° C may not be sufficient, the LPG is at a preferred embodiment, at least in addition to a heat exchanger heated. For reasons of cost, the heat exchanger is preferably also outside the ship's tank and in particular in one

Process space. If liquefied petroleum gas is pumped into the ship's tank, it first reaches the heat exchanger and from the heat exchanger into the ship's tank.

Since an excess pressure is to be built up in the transport medium tank, the liquid gas is pumped into it by means of a pump, namely with a pressure which is above the bearing pressure in the tank. Thus, if the bearing pressure in the tank is 3 bar absolute, the liquefied gas is pumped absolutely into the tank at a pressure of more than 3 bar, for example at a pressure of 4 bar absolute. If gas originating from the transport medium tank is added to the liquid gas which is pumped into the transport tank, this gas is injected into the liquid gas at a pressure which is above the liquid pressure of the liquefied gas to be heated. This gas pressure is, for example, 5 bar absolute (bar a) when the liquid pressure of the liquefied gas to be heated is 4 bar absolute.

In order to be able to fill a ship tank particularly quickly with liquefied gas, it is preferably filled via only one supply line. If liquefied petroleum gas is to be refueled, then only one line (tank line) must be connected and removed after refueling, what the for refueling required time required. The speed with which one

Transport tank can be filled with LPG is limited only by the cross section of the tank line and the pressure at which the LPG is pumped into the tank. It is therefore possible to pump liquid gas into the tank at high speed, so that the means of transport can be refueled quickly.

A transport medium tank, in particular a ship tank, in which heated LPG is located, is preferably taken from LPG by opening a valve of a withdrawal line. The overpressure in the transport tank then ensures that the liquid is pushed out through the withdrawal line out of the tank and can be supplied to the drive as the ship. The extraction line extends approximately in a ship, preferably through a vessel tank top through to the bottom of the

Ship Tanks. If a line is passed through the top of the tank into the tank, so that the risk of such a leak is minimized over which the tank contents could leak completely. If the withdrawal line extends to the bottom of the ship's tank, this ensures that the tank contents can be pushed out almost completely through the withdrawal line.

If, for instance, a ship has a leak in a sampling line which is led out of the tank through the top of the tank, fuel may still escape and damage the ship due to the overpressure prevailing in the tank. However, in the case of a leak, the pressure prevailing in the tank can be relieved relatively quickly by discharging gas, so that in any case in an emergency situation with respect to a tank with bottom outlet, there is the advantage that at most a very small amount will escape from the tank. In this way it can be very reliably avoided that material of the ship is damaged in the event of a leak. In one embodiment of the invention, the valves with which a sampling line is to be closed or opened, housed in a pressure vessel. The relevant valves are adjacent to the transport tank. If a leak occurs behind the valves when viewed from the tank, the valves are closed immediately. It can then get no more liquid gas from a tank in the lines of the system and leak through a leak. If, however, a leak occurs in a valve which is arranged adjacent to the tank and through which a withdrawal line can be opened or closed, there is no possibility of being able to close the withdrawal line and prevent further escape of liquefied gas. This difficulty is solved by the additional pressure vessel, which shields such a valve to the outside. If a leak occurs in such a valve, then the extraction line can not be closed. The leaking liquefied gas then passes into the pressure vessel, which then ensures that liquefied gas can not damage the ship beyond that. The valve of the extraction line is located advantageously outside the transport tank, in particular of the ship's tank, in particular in a process space.

The extraction line advantageously has a relatively thin cross-section compared to the conduit through which the transporting agent tank is filled. A large cross-section of the line, through which the tank is filled, advantageously allows fast refueling of a ship. Since the removal is much slower, this is sufficient for a small cross section for this

comparatively cost-effective sampling line.

In one embodiment of the invention, the withdrawal conduit is disposed within the conduit through which liquid gas is pumped approximately into the vessel's tank. This reduces the number of lines leading into the tank separated from each other. The risk of a leak is thus minimized further. However, the double tube thus provided extends advantageously only up to the top of the tank. All that is needed is the bottom of the tank

Sampling line.

In one embodiment of the invention, for example, the ship's tank is provided with a line through which gas can be removed from it. The line therefore preferably flows into the vessel tank from above and does not extend further into the tank. The conduit is connected to a heat exchanger and preferably also to a compressor to heat and compress the gas so that it can be used to propel the vessel. This line therefore always leads to the drive, for example, to be able to use boil-off gas for the drive.

If boil-off gas is used for the drive, then a pressure is initially given by the warm-up during refueling. If necessary, this pressure is either by recirculation of hot gas from a compressor of the system or by suction of gas to

Combustion regulated.

The said process space is outside the transport tank, in particular the

Ship tanks, arranged. This particular has a preferably made of stainless steel tub. The above-mentioned devices, which are preferably arranged in the process space, are located in or above the tub. Occurs in these devices, a leak, it is collected leaking liquefied gas from the tub and can not continue to be destructive. The process room can also be open but also completely closed.

In one embodiment of the invention, the transport tank comprises only two lines which are connected thereto. This reduces the risk of leakage occurring. Preferred are the lines welded to the tank, which is manageable due to the small number of lines in practice. The security is thereby further increased.

In addition, in one embodiment of the invention, the valves of the liquid lines closest to the transport tank are enclosed by a collecting container whose design pressure is higher than that of the respective tank. This greatly minimizes the possibility of leakage of liquid into the process space. Such valves are basically remote-controlled.

In one embodiment of the invention, lines connected to the transport tank are each provided with an enclosed shut-off valve, for example with the aforementioned remotely controllable valves with collecting container. These lines and connections are preferably made fully welded. So it lacks neck, to a line

to join. The security of the system is further improved.

For the sake of clarity, preferred aspects of the invention are summarized again in numbered form below:

1.

Method for filling a tank of a ship with LPG and / or for the

Remove LPG from the tank by heating LPG and pumping heated LPG into the vessel tank.

Second

Process according to embodiment 1, in which the liquefied gas is first stored at normal pressure and the liquid gas stored at normal pressure is heated to a temperature which is above the boiling point of the liquefied gas at normal pressure.

Third

Method according to one of the preceding embodiments, wherein the liquefied gas at least

10 ° C is heated.

4th

Method according to one of the preceding embodiments, in which the bearing pressure of the

Liquefied gas in the vessel tank is at least 3 bar absolute.

5th

Method according to one of the preceding embodiments, in which the liquefied gas is heated by supplying gas, which is located in the ship's tank. 6th

Method according to one of the preceding embodiments, in which the liquefied gas is heated in a heat exchanger.

7th

Method, in particular according to one of the preceding embodiments, in which liquid gas located in the ship tank is removed by opening a valve of a withdrawal line and then by a pressure prevailing in the tank overpressure liquid through the

Suction line is pushed out of the vessel tank.

8th.

Method according to the preceding embodiment, wherein the withdrawn liquefied gas for the

Supply of the drive of the ship with fuel is used.

9th

System for filling and / or discharging a tank of a ship with LNG, with a tank for the storage of LNG, whose design pressure is at least 5 bar g, preferably at least 10 bar g, the tank having a cryogenic liquified gas inlet and an outlet for discharging the tank, the inlet comprising means for heating LNG.

10th

A system according to the preceding embodiment, wherein the means for heating LNG comprises a heat exchanger and / or means for adding gas from the tank to the LNG pumped into the tank.

11th

System according to one of the preceding system designs with a mixer for mixing gas from the tank and LNG to be pumped into the tank:

12th

System according to one of the preceding system designs with a process room containing the means for heating LNG.

13th

System according to one of the preceding system versions with a pump with which the LNG can be pumped into the tank at a pressure of at least 4 bar a, preferably at least 6 bar a. 14th

System according to one of the preceding system versions with a compressor with which gas from the tank with a pressure of at least 3 bar a, preferably of at least 4 bar a can be pumped into the LNG to be pumped into the tank.

15th

System according to one of the previous system versions with no pump in the tank.

16th

System according to one of the preceding system designs with one serving as outlet

Extraction line that reaches to the bottom of the tank.

17th

System according to one of the preceding system versions with a particular in one

Process chamber evaporator for LPG, which is removed from the tank.

18th

System according to one of the preceding system designs with means for the supply of

Fuel from the tank to a ship propulsion.

19th

System according to one of the preceding system versions, wherein up to two lines are welded to the tank and no filler neck for connecting more than two lines are provided with the tank.

20th

System according to one of the preceding system designs with at least one

Pressure vessel, the at least one valve for opening and closing at least one

Discharge line wrapped.

21st

Ship with a system according to one of the previous system versions.

The invention can, as mentioned, not only for ships, but also for the drive of other mobile systems, ie means of transport are used, such as for the propulsion of aircraft or land vehicles. Instead of a ship's tank is then about the tank about an aircraft. Generalizing here is placed on transport tanks. The aspects disclosed in the foregoing and following description are related to both the method and the system, although not always expressly stated. In principle, the individual features can also be essential to the invention in combinations other than those shown.

In the following, the invention will be explained in more detail by means of exemplary embodiments, without wishing to restrict the invention by the examples:

Figure 1 shows a system according to the invention.

Figure 2 shows another system according to the invention.

FIG. 3 shows a time chart for a method according to the invention.

In Figure 1, three tanks 1 of a ship are shown in section, which are intended for receiving the fuel and set up and dimensioned accordingly. The tanks 1 are such that they are able to withstand a temperature of -163 ° C to 45 ° C. The design pressure of the tanks 1 is about or slightly more than 10 bar g. In the top of each tank 1 opens a line 2, but does not reach into the tank. In addition, each tank 1 is provided with a line 3, which extends through the respective tank top through to the respective tank bottom. Each line 3 is used to fill the associated tank 1 with LPG. In addition, through this line, liquefied gas from the tank due to a pressure prevailing in the tank, for example, 3, 5 or 9 bar absolutely pushed out and forwarded to a drive for the ship, so for example to a motor or to a turbine of the ship. The line 3 may be partially designed as a double tube. Liquefied petroleum gas is taken from the tank via an inner tube of the double tube. Liquid gas is pumped into the respective tank via an outer tube of the double tube.

The system shown in FIG. 1 has a connection 4, via which liquefied gas to be heated is introduced into the system when a ship is to be refueled. The liquefied gas entering the system via port 4 is heated in a heat exchanger 5. The liquefied gas is also passed through a mixer 6 and mixed here with coming from the tanks 1 gas. The liquid gas thus heated is then pumped into the tanks 1 via the line 3.

Boil-off gas in the tanks is led out of the tanks via lines 2 during refueling. The outgoing gas is passed through a heat exchanger 7, in order to heat the gas when needed can. Subsequently, the gas is in two compressors 8 introduced, which are able to compress the gas in the desired manner. If inexpensive oil-lubricated compressors 8 are used, the gas is then passed through the oil separator 9. The oil separated here can be returned to the compressors 8. For redundancy reasons, two compressors are provided in order to be able to continue driving in the event of a compressor failure.

Subsequently, the gas is introduced through a cooler 10 into a buffer volume 11. The cooler, if necessary, cools the gas to a temperature that is required by the consumer. The buffer volume 11 serves to bridge, if in the short term not enough fuel (LPG or Boil-off Gas) can be removed from the tanks 1.

From the buffer volume 11, the gas is either forwarded via the line 12 to the consumer or via the line 13 into the mixer 6 into it.

The conduit 13 can pass through an activated charcoal filter 14 in order to purify the gas to be introduced into the liquefied gas to be heated beforehand.

The system includes a connected to the lines 3 pump 15, with the tanks 1 can be pumped empty in an emergency.

Via a line 16 can be removed from the system in an emergency gas.

If liquefied gas is pressed out of the tanks, it is first led into an evaporator 17 and vaporized here. From the evaporator 17, the gas is introduced, for example, in the heat exchanger 7 in order to be able to supply the gas to the consumer.

The lines are provided with a plurality of valves 18 to control the flow through the lines to the individual devices in the manner described.

The system shown in Figure 1 is provided with a load-control bypass 19, with which gas can be withdrawn behind the compressors 8 and fed back into the line with which gas is supplied to the compressors. By this load control bypass unwanted pressure fluctuations and rapid pressure changes can be compensated.

The devices of the system shown in Figure 1 are within one

Process room 20, which is provided at the bottom with a stainless steel drip tray. Any conduit that passes outside the tank through the room presents a safety hazard. In the embodiment shown in FIG. 1, there are only two welded joints and only two pipes leading from each ship tank 1 into the process space 20.

By mixing boiled gas with vaporized gas, the fuel gas can be treated in the desired manner, for example, to achieve a desired anti-knocking properties.

The system shown in FIG. 1 may include one or more pressure regulators (PIC) and / or

Pressure control valves (PCV) include, in order to regulate the pressure in the system suitable. With the help of temperature control instruments (TIC), temperatures in the system can be monitored and / or controlled. A temperature control takes place especially when loading the tanks.

Test leads, which lead into the tank, enter via existing lines into the tank and in particular via the intended for the discharge line 3. It is thus achieved a very high safety standard. Security measures can be saved accordingly.

On spray lines to cool the tank can be dispensed with. On the one hand, the tanks are anyway permanently filled with cryogenic liquefied gas as otherwise the ship could not be moved due to a lack of fuel. In addition, relatively warm liquefied gas is introduced, which reduces thermal problems. Thus, LNG at temperatures of about -140 ⁰ C or even about -145 ° C or -150 ⁰ C stored in the vessel's tank and not as usual at temperatures below -160 ⁰ C.

FIG. 2 shows another embodiment of the invention. In contrast to the embodiment according to FIG. 1, the remote-controllable valves, with which a withdrawal line of a tank can be closed and which are arranged adjacent to the respective tank, are enclosed by a pressure-resistant container 21. If a leak occurs in these valves, liquid gas enters the pressure-resistant container, so that further damage is avoided. Via a line 22, liquefied gas can be suitably forwarded by a pressure-resistant container 21 in a line of the system. Therefore, the embodiment shown in Figure 2 is particularly safe.

The embodiment shown in Figure 2 also still includes level gauge 23. Although there is then a third compound which leads into the tank. But since this is not connected to external lines, this is not a problem and does not hinder the construction of the system further. The level indicator of the level gauge is located in the process room. This can also be accommodated in a separate container.

The same applies to the other devices which are arranged in the process space 20. By the present invention can be provided by reducing the pressure in a ship's tank 1 immediately a desired amount of gas, since the pressure prevailing in the tank overpressure for the liquefaction of the gas is needed.

If the bearing pressure in the vessel tank is above the pressure required by the consumer, no compressor is required to provide the gas pressure needed by the consumer. It then suffices a reducing valve, with which the gas pressure can be lowered if necessary suitably. For example, if the bearing pressure in the tank is 6 bar a and requires one

Consumers have a gas pressure of 5 bar a, so there is a sufficiently high pressure difference available to lower the gas pressure in the tank can so quickly have enough gas available. On the other hand, no additional compressor or compressor is needed to compress the gas to the pressure required by the consumer.

The ship's tanks 1 can be insulated with insulating material or by vacuum. In-tank pumps are not used because they are not needed.

The system according to the invention is robust and less susceptible to interference. Wear parts lie outside the tank and are therefore easy to reach without having to go through the tank.

FIG. 3 shows a flowchart for the essential steps of the invention

Process. First, LNG is taken from a stationary storage tank located on land 31. After removal and before LPG is pumped into the tank of a ship, the LPG is heated by means of a heat exchanger 32. After heating, the

Liquefied petroleum gas is pumped into a tank of the ship to be used as fuel for a propulsion system

To be available 33.

Claims

claims

1.

Process for the storage of cryogenic liquid gas in a tank (1) of a means of transport, in particular of a ship, comprising the steps of:

Removing liquefied gas from a storage tank, in particular from a stationary tank

Storage tank,

Heating the withdrawn liquefied gas,

Filling the tank (1) of the means of transport with the heated LPG by pumping the

Liquefied gas in the tank (1) of the means of transport.

Second

The method of claim 1, wherein the liquefied gas initially in a storage tank at

Normal pressure is stored and stored at atmospheric pressure liquefied gas is then heated before filling the tank (1) of the transport to a temperature above the

Boiling temperature of the liquefied gas is at atmospheric pressure.

Third

Method according to one of the preceding claims, wherein the liquid gas at least

10 ° C is heated.

4th

Method according to one of the preceding claims, in which the bearing pressure of the

Liquefied gas in the tank (1) of the transport is at least 3 bar absolute.

5th

Method according to one of the preceding claims, comprising the step:

Supplying gas from the tank (1) of the means of transport to the tank (1) of the tank

Transport means to be filled liquefied gas, so that in the tank (1) of the transport means to be filled liquefied gas is heated by the supplied gas.

6th

Method according to one of the preceding claims, wherein the liquefied gas in a

Heat exchanger (5, 7) is heated.

7th

Method according to one of the preceding claims, in which in the transport medium tank (1) there is an overpressure and in which in the transport tank (1) befindliches liquefied gas is removed by a valve of a withdrawal line (3) is opened and then Liquefied gas is forced out of the transport medium tank (1) through the removal line (3) through a positive pressure prevailing in the transport medium tank (1).

8th.

Method according to the preceding claim, in which the liquefied gas removed from the transport medium tank (1) is used to supply the drive of the transport means with fuel.

9th

System for storing cryogenic liquid gas for a means of transport, in particular for a

Ship, with:

a transport tank (1) for storing LPG,

an inlet device (4) for the removal of liquid gas from a storage tank, in particular from a stationary storage tank,

Means for heating the withdrawn liquefied gas (5, 6, 7), and

a filling device for the tank (1) of the means of transport with a pump for pumping the heated liquefied gas into the tank (1) of the means of transport.

10th

System according to claim 9, wherein the transport medium tank (1) has a design pressure of at least 5 bar g, preferably of at least 10 bar g, and an inlet (4) for

Liquefied gas for filling the transport tank (1) and an outlet for emptying the

Transport tank (1), wherein the inlet (4) comprises means (5, 6) for the heating of liquefied gas.

11th

A system according to claim 9 or 10, wherein the liquid gas heating means (5, 6) comprises a heat exchanger (5) and / or gas addition means (6)

Transport tank (1) to the liquefied gas, which is pumped into the tank have.

12th

System according to one of the preceding system claims with a mixer (6) for the mixing of gas from the transport medium tank (1) and into the transport medium tank (1) into liquid gas to be pumped.

13th

System according to one of the preceding system claims with a process space (20) in which the means (5, 6, 7) for the heating of liquefied gas are located.

14th

System according to one of the preceding system claims with a pump with which the liquid gas at a pressure of at least 4 bar a, preferably of at least 6 bar a in the transport medium tank (1) can be pumped.

15th

System according to one of the preceding system claims with a compressor (8), are pumped with the gas from the transport tank (1) with a pressure of at least 3 bar a, preferably at least 4 bar a in the in the transport tank (1) to be pumped liquefied gas can.

16th

System according to one of the preceding system claims, in which the transport medium tank (1) is free of pumping medium in its interior.

17th

System according to one of the preceding system claims with an outlet

Extraction line (3), which extends to the bottom of the tank (1).

18th

System according to one of the preceding system claims with an evaporator (17) for

Liquefied gas from the transport tank (1).

19th

System according to one of the preceding system claims with means for the supply of

Fuel from the transport tank (1) to a ship propulsion.

20th

System according to one of the preceding system claims, wherein on the transport medium tank (1) up to two lines (2, 3) are welded and no filler neck for connecting more than two lines (2, 3) are provided with the tank (1).

21st

System according to one of the preceding system claims with at least one pressure vessel (21), the at least one valve (18) for opening and closing at least one

Discharge line (3) wrapped.

22nd

Ship with a system according to one of the preceding system claims.