EP4219282A1 - Fuel gas supply system, in particular based on liquid gas, for a ship with at least one gas-operated consumer and ship with the same - Google Patents

Abstract

Fuel gas supply system (200), in particular based on liquid gas, for a ship with at least one gas-operated consumer (38) in a consumer installation room (36), the fuel gas supply system (100) comprising: a gas storage tank (11) together with tank connections (15) with or without dome ( 13), a gas processing device (32) which is in fluid connection with the gas storage tank (11) via a line (28) for processing gas from the gas storage tank (11) into gas, preferably with a low flash point, as fuel for a gas-operated consumer (38 ) in a consumer installation room (36), with the gas storage tank (11) together with tank connections (15) and the gas treatment device (32) being arranged in a common gas supply room (42), with the gas supply room (42) being designed in such a way that it complies with the provisions of International Code of Safety for Ships using Gases or other Low-flashpoint Fuels, IGF-Code, in particular version 01.01.2017 or later, of the International Maritime Organization, IMO, for tank connection spaces, TAR (Tank Connection Space, TCS), and for gas treatment rooms, GAR (Fuel Preparation Room, FPR), and the fuel gas supply system (200) also has a gas line (34), one end of which is in gas connection with an outlet of the gas preparation device (32) and the other end of which is connected to the gas supply space (42) for a gas connection with the consumer (38) is brought out in the consumer installation room (36).

Description

The present invention relates to a fuel gas supply system, in particular based on liquid gas, for a ship with at least one gas-operated consumer and a ship with the same.

In general, the present invention relates to the arrangement and design of gas supply systems for fuel on board watercraft. The focus is on gas supply systems in which fuels with a low flash point are used, which are stored in a pressure tank and e.g. B. must be processed accordingly in a machine.

The design and arrangement of such gas supply systems are specified in the applicable regulations of the classification societies (DNV, BV - Bureau Veritas, ABS - American Bureau of Shipping, etc.). The respective regulations refer almost entirely to the so-called "IGF Code", the International Code of Safety for Ships Using Gases or other Low-Flashpoint-Fuels, published by the International Maritime Organization "IMO".

The following components are usually part of such gas supply systems:
storage tank:
Here in particular cryogenic, self-supporting, self-contained pressure vessels of type C according to IMO, which are generally considered safe with regard to leakage, as well as prismatic or spherical tanks of IMO types A and B in general. In these tanks, the consumable is stored in a liquefied, cryogenic form under a certain overpressure. Mainly tempered steels with a high nickel content, stainless steels or aluminum are used.

Two common types of insulation for the storage tank are used for cryogenic applications. A substitute, for example, PU (polyurethane) foam, whereby the foam is applied directly to the metal shell of the storage tank and is protected from moisture and damage by a thin protective layer on the outside. On the other hand, there is vacuum insulation, in which there are two parallel, metal storage tank walls between which there is a vacuum and thus insulation from the environment.

In principle, the arrangement of a gas supply system in foam-insulated and vacuum-insulated storage tanks is different in the prior art and is explained below using the schematic representations in FIGS figures 1 and 2 presented, the examples of fuel gas supply systems 100 with a foam-insulated (see foam insulation 14) liquid gas storage tank 11 ( 1 ) or with a vacuum-insulated (see vacuum insulation 16) liquid gas storage tank 11 in dual-fuel application for a ship.

Tank Connections:
Tank connections are all punctures and openings through a shell, for example tank shell 12, of a storage tank, in particular liquid gas storage tank 11, both for pipelines for process technology and for sensors and access to the storage tank. These tank connections are generally made of steel, are either distributed on the shell of the storage tank or are arranged centrally on a dome specially provided for this purpose, for example dome 13 .

• es im Falle eines Lecks von kryogener Flüssigkeit oder Gas zu keinen strukturellen Schäden an der Schiffsstruktur kommt,
• ein kryogenes Leck sicher eingedämmt und die entstehenden Verdampfungsgase in einem sicheren Bereich entlüftet werden können, und
• keine Gefahr für Feuer oder eine Explosion herrscht, da es keine Zündquellen und/oder keine ausreichende Sauerstoffatmosphäre gibt.

If the storage tank is set up outdoors, the tank connections do not have to be enclosed. If the storage tank is located below deck of a watercraft, especially a ship, in a closed space, the tank connections must be enclosed in such a way that:

• there is no structural damage to the ship's structure in the event of a leak of cryogenic liquid or gas,
• a cryogenic leak can be safely contained and the resulting evaporative gases vented to a safe area, and
• there is no risk of fire or explosion as there are no sources of ignition and/or insufficient oxygen atmosphere.

This is mostly realized by means of a separate, steel construction and gas-tight tank connection space (TAR) 18 .

Gas preparation room (FPR)):
The actual components of a gas supply system, for example fuel gas supply system 200, are usually located in a gas processing room (GAR), e.g. B. gas processing chamber 30 arranged. There the gas, if liquid, from the storage tank, z. B. LPG storage tank 11, removed, evaporated, heated and possibly controlled by means of a buffer tank and continuously one or more consumers, z. B. consumer 38 supplied. Gas that has already evaporated in the storage tank can be removed as a gas phase, heated in the gas processing chamber 30 and also supplied to suitable consumers.

• Leckagen kryogener Flüssigkeit oder eines Gases keine strukturellen Schäden im Raum verursachen, entweder durch z. B. lokale Leckwannen, beispielsweise Leckwannen 44, Abweiserbleche oder eine entsprechende Materialauswahl für die Konstruktion des Gasaufbereitungsraumes,
• eine eventuell vorhandene Gasatmosphäre sich nicht auf andere, womöglich nicht ex-geschützte Bereiche ausbreiten kann,
• eine eventuell vorhandene Gasatmosphäre in zündfähiger Konzentration keinen Zündquellen ausgesetzt ist, und
• eine eventuell vorhandene Gasatmosphäre kontrolliert zu einem sicheren Bereich ventiliert werden kann.

The gas treatment room 30 in the prior art should be designed so that:

• Cryogenic liquid or gas leaks do not cause structural damage in the space, either by e.g. B. local leak pans, for example leak pans 44, deflector plates or a corresponding choice of material for the construction of the gas treatment room,
• any gas atmosphere that may be present cannot spread to other areas that may not be explosion-proof,
• Any gas atmosphere present in an ignitable concentration is not exposed to any sources of ignition, and
• any gas atmosphere present can be vented to a safe area in a controlled manner.

Tank installation room:
If a storage tank is located below deck or in a closed room, it is referred to as a tank installation room, e.g. B. Tank installation room 10. If a C-type storage tank is used, the classification of the C-tank as safe with regard to leaks according to the IGF Code means that the tank installation room usually does not have to be designed against either cryogenic leaks or ignitable gas-air mixtures and is considered a non-hazardous area. However, if the tank connection room (TAR) including access is located in the tank installation room, the tank installation room also becomes dangerous.

Other components of a gas supply system on ships are usually a bunker station, for example bunker station 22, fan rooms for ventilating gas-endangered areas, gas control units near the consumer or consumers, and a control and monitoring device for the entire gas supply system. These components are usually set up decentrally.

Typical arrangements of the rooms and components described above are generally distinguished with regard to the type of storage tank:
In the case of a foam-insulated storage tank, for example, the tank connections and the gas treatment are usually spatially separated from one another. If the storage tank is located below deck, the TAR and GAR are two separate rooms, with the TAR lying entirely in the tank installation room.

When arranged on an upper deck, only the gas treatment is arranged in one room and the tank connections are outdoors.

In a vacuum-insulated storage tank, a so-called "cold box", e.g. B. Cold Box 40 connected. This room contains all tank connections as well as the entire gas processing and is designed and ventilated accordingly for cryogenic temperatures and possible leakage scenarios. The "cold box" can thus be viewed as a space encompassing TAR and GAR.

The storage tank and "cold box" can then be arranged either on an open deck or in a tank installation room. The same criteria then apply to the tank installation room as to a tank insulated with foam, for example.

A further basic distinction must be made when the craft in question is fueled exclusively with a low flash point fuel in accordance with the IGF Code. In this case one speaks of a "single-fuel" application. Thus, if the gas supply system were to shut down following a failure, the entire power supply to the watercraft would be lost. Therefore, in the case of "single-fuel" watercraft in the prior art, all tank connections and the entire gas treatment must be implemented redundantly and separately from one another. Thus, the generation of energy and thus also the maneuverability of the watercraft can be maintained even in the event of a fault on one side of the gas supply system. Examples are in the Figures 3 (Combustion gas supply system 100 with foam insulation 14) and 4 (combustion gas supply system 100 with vacuum insulation 16) shown schematically.

In all currently customary arrangements, the components of the gas supply system, such as storage tank, TAR and GAR, are spatially separated from one another or from the tank installation room. This creates several problems, which are detailed below:

Accessibility:

Each separate room must also be accessible through an entrance. If access is from a non-hazardous area and the space itself is hazardous, i. That is, because of the equipment in this space and its operation, there is a likelihood that an ignitable gaseous atmosphere will prevail, the non-hazardous area and the space shall be separated by a gas lock unless access is from an open deck. Since a gas lock may only have two doors as defined by the IGF Code, two rooms cannot be reached via the same gas lock. Accordingly, several gas locks may be required for several gas-hazardous rooms of different categories.

Ventilation:

Any hazardous space must be mechanically vented. Separate rooms must not be supplied with the same ventilation system. Care must also be taken at the air inlet openings to ensure that any gas zones do not overlap in such a way that gas can be drawn from one room into another.

Each of these ventilation systems must be equipped with gas sensors and redundant fans. According to the IGF Code, ventilation rates of up to 30 times the net room volume per hour are required for hazardous rooms, which results in large duct cross-sections. The number of fans, sensors and pipe systems is therefore quite high and so is the space requirement.

Pipe penetrations:

If the process of gas extraction and treatment is spread over several rooms, gas-tight pipe penetrations are required between these rooms. If the pipes are cryogenic, they must be examined in a pipe stress analysis. A pipe penetration through a bulkhead always forms a fixed point, which restricts the flexibility of the pipeline in the event of thermal shrinkage, for example, and may necessitate additional compensation bends.

In addition, every restraint of a cryogenic line is a thermal bridge to the ship's structure and must be considered and designed as such.

required space:

Above all on board smaller ships, eg vehicles with a length < 100 m and a liquid gas tank volume < 100 m ³ , installation space is a critical factor and can be decisive for the feasibility or profitability of a concept. Each room separation usually results in an increase in weight (due to additional walls and bracing), more space requirements (more access or more space for inspection, maintenance, service, etc.) and higher costs (additional ventilation, lighting, drainage, insulation, etc.).

The present invention is therefore based on the object of reducing the space required for fuel gas supply systems based on liquid gas for a ship with at least one gas-operated consumer.

• einen Gasvorratstank nebst Tankanschlüssen mit oder ohne Dom und
• eine mit dem Gasvorratstank über eine Leitung in Fluidverbindung stehende Gasaufbereitungseinrichtung zur Aufbereitung von Gas aus dem Gasvorratstank zu Gas, vorzugsweise mit einem niedrigen Flammpunkt, als Treibstoff für einen gasbetriebenen Verbraucher in einem Verbraucheraufstellraum, wobei der Gasvorratstank nebst Tankanschlüssen und die Gasaufbereitungseinrichtung in einem gemeinsamen Gasversorgungsraum angeordnet sind, wobei der Gasversorgungsraum so ausgelegt ist, dass er den Vorschriften des International Code of Safety for Ships using Gases or other Low-flashpoint Fuels, IGF-Code, insbesondere Version 01.01.2017, der International Maritime Organisation, IMO, für Tankanschlussräume, TAR (Tank Connection Space, TCS), und für Gasaufbereitungsräume, GAR (Fuel Preparation Room. FPR), entspricht, und das Brenngasversorgungssystem ferner eine Gasleitung aufweist, deren eines Ende mit einem Ausgang der Gasaufbereitungseinrichtung in Gasverbindung steht und deren anderes Ende aus dem Gasversorgungsraum für eine Gasverbindung mit dem Verbraucher in dem Verbraucheraufstellraum herausgeführt ist.

According to the invention, this object is achieved by a fuel gas supply system, in particular based on liquid gas, for a ship with at least one gas-operated consumer in a consumer installation room, the fuel gas supply system comprising:

• a gas storage tank together with tank connections with or without dome and
• a gas treatment device that is fluidly connected to the gas storage tank via a line for treating gas from the gas storage tank to gas, preferably with a low flash point, as fuel for a gas-operated consumer in a consumer installation room, with the gas storage tank together with tank connections and the gas treatment device being arranged in a common gas supply room where the gas supply room is designed in such a way that it complies with the provisions of the International Code of Safety for Ships using Gases or other Low-flashpoint Fuels, IGF Code, in particular version 01.01.2017 , of the International Maritime Organisation, IMO, for tank connection rooms, TAR (Tank Connection Space, TCS), and for gas processing rooms, GAR ( Fuel Preparation Room. FPR ), and the fuel gas supply system also has a gas line, one end of which is in gas connection with an outlet of the gas processing device and the other end of which is connected to the gas supply room for a gas connection with the consumer is brought out in the consumer installation room.

The lines are generally pipelines. Compressed gas (gaseous state of aggregation), for example, can be used as the gas.

Furthermore, this object is achieved by a ship with at least one gas-operated consumer in a consumer installation room, comprising a fuel gas supply system according to one of Claims 1 to 17.

In the fuel gas supply system, it can be provided that it further comprises a bunker station for bunkering liquid gas, which is fluidly connected to the gas storage tank via a bunker line, preferably further comprising a gas-tight line bushing for the bunker line. In this example, the bunker station is only used to take over liquid gas on board and, if necessary, to empty the gas storage tank overboard in an emergency in the event of a serious fault in the gas system.

In addition, it can be envisaged that it includes access with or without a gas lock in accordance with the IGF code for access to the bunker station.

Advantageously, the fuel gas supply system also includes access with or without a gas lock in accordance with the IGF Code for access to the gas supply space.

In addition, it is advantageous if the fuel gas supply system also includes a ventilation device for the gas supply space.

Furthermore, the fuel gas supply system advantageously also has a control and monitoring device for controlling and monitoring the same.

Furthermore, it can be provided that the gas processing device comprises at least one evaporator and/or a heat exchanger, in particular a pressure build-up heat exchanger, and/or a buffer tank and/or a pump.

The gas storage tank is favorably designed as a C-tank according to IMO. However, depending on the application, it can also be an A or B tank according to IMO.

Provision can furthermore be made for the gas storage tank to be arranged in the gas supply space in a hanging, lying or standing position, with a cylindrical shape or with a bilobe shape or multilobe shape.

Furthermore, it can be provided that the gas storage tank is designed as double-walled vacuum insulation or single-walled and insulated, in particular foam-insulated.

According to a further special embodiment of the present invention, the gas supply space can be divided into two subspaces by a dividing bulkhead and the gas storage tank can be part of both subspaces and integrated into the dividing bulkhead.

This is for a "single fuel" application.

In particular, it can be provided that the fuel gas supply system has further tank connections with or without a dome, a further gas processing device and a further gas line, so that each of the two sub-chambers has a gas processing device that is in fluid communication with the gas storage tank via a respective gas line for processing gas from the gas storage tank to gas, preferably with a low flash point, as a fuel for a gas-operated consumer in the consumer installation room and a gas line, one end of which is in gas connection with an outlet of the respective gas processing device and the other end of which is connected to the gas supply room for a gas connection to the consumer in the Consumer installation room is brought out.

The fuel gas supply system expediently includes a further access with or without a gas lock according to the IGF code for access to the gas supply space, so that it includes an access with or without a gas lock according to the IGF code for the sub-spaces.

Furthermore, the consumer can be or comprise an internal combustion engine or a heating boiler.

In particular, it can be provided that the internal combustion engine is designed as a dual-fuel machine or purely gas-operated machine.

It is also conceivable that the fuel gas supply system is designed to be arranged on the deck of a ship, in particular with the gas supply space being designed as a container or being designed in a container.

It is also conceivable that the combustible gas supply system is designed below the deck of a ship.

In particular, it can be provided that the gas supply space is designed as part of a ship's hull with an outer skin contour.

Alternatively, it can be provided that the gas supply space is designed as a pre-fitted section in a ship's hull.

Finally, it can be provided in the ship that the gas supply space is arranged, preferably directly, adjacent to the consumer installation space.

The present invention is based on the surprising finding that by appropriate arrangement and design of at least some of the components of a gas supply system, the number of rooms is reduced to one and the space requirement can be reduced as a result (since it contains the most important components for storing the fuel and supplying of a consumer or consumers with the same). At least in one particular embodiment, this space, referred to here as the gas supply space, requires only one access with or without a gas lock and only one aeration and ventilation system. Since at least the most important components for heating the gas are located in the gas supply space, no cryogenic pipe penetrations are required for the process side of the gas treatment, at least in one particular embodiment. The only exception is the bunker line, which conducts cryogenic fuel from a bunker station into the liquid gas storage tank, and, if available, a gas return line (also called "vapor return" line).

At least in special embodiments, the number of rooms can be reduced and space, costs and weight can be saved.

In principle, two separate rooms are required for "single-fuel" applications in order to comply with the IGF Code. At least according to a particular embodiment of the present invention, this is achieved by dividing a room into two sub-rooms by means of a partition and integrating the liquid gas storage tank in the partition. The liquid gas storage tank is then part of both sub-spaces.

In contrast to the previous design of a tank installation room as a purely shipbuilding and non-hazardous room, the gas supply room is also designed in such a way that it also fulfills all the requirements placed on a TAR and GAR.

• Konzeption aus geeigneten Werkstoffen, die für Leckagen tiefkalter Brennstoffe geeignet sind, wie zum Beispiel hoch legierte Nickelstähle, Edelstähle oder Aluminium etc..
• Auswahl eines Werkstoffes, der mit einer übrigen Schiffsstruktur gut verschweißbar ist, zum Beispiel Aluminum nur bei Aluminiumschiffen,
• strukturelle Auslegung gegenüber Druck im Falle einer schlagartigen Verdampfung ausgelaufener kryogener Flüssigkeit,
• ex-geschützte Ausführung der gesamten Inneneinrichtung,
• thermische Isolierung zu benachbarten Räumen, Einrichtungen und Rohrsystemen, die eventuell bei tiefkalten Temperaturen Schaden nehmen könnten,
• Abkofferung gemäß IGF/SOLAS zu benachbarten Räumen mit hoher Feuergefahr "Category A",
• A60-Isolierung zu allen benachbarten Räumen gemäß IGF/SOLAS-Raumkategorien,
• 30-fache Belüftung samt Temperatur- und Gasüberwachung, alternativ konstante und überwachte Überdruckatmosphäre mit Stickstoff/getrockneter Luft,
• Temperatur- und Gasüberwachung aller installierter Anlagenteile,
• Prüfung, ob eine Brandmeldeanlage und/oder ein Feuerlöschsystem installiert werden muss bzw. müssen.
• Zugang mit oder ohne eine(r) Gasschleuse.

Specifically, this can mean the following, individually or in any combination:

• Design from suitable materials that are suitable for leaks of cryogenic fuels, such as high-alloy nickel steels, stainless steels or aluminum etc..
• Choosing a material that can be easily welded to the rest of the ship's structure, e.g. aluminum only for aluminum ships,
• structural design against pressure in the event of a flash vaporization of spilled cryogenic liquid,
• explosion-proof design of the entire interior,
• thermal insulation to neighboring rooms, facilities and pipe systems that could possibly be damaged at low temperatures,
• Covering according to IGF/SOLAS to neighboring rooms with high fire risk "Category A",
• A60 insulation to all adjacent rooms according to IGF/SOLAS room categories,
• 30-fold ventilation including temperature and gas monitoring, alternatively constant and monitored overpressure atmosphere with nitrogen/dried air,
• Temperature and gas monitoring of all installed system parts,
• Check whether a fire alarm system and/or a fire extinguishing system must be installed.
• Access with or without a gas lock.

Figur 1:

schematisch ein Beispiel für ein Brenngasversorgungssystem mit einem Flüssiggasvorratstank mit Schaumisolierung für eine Dual-fuel-Anwendung im Stand der Technik;

Figur 2:

schematisch ein Beispiel für ein Brenngasversorgungssystem mit einem Flüssiggasvorratstank mit Vakuumisolierung für eine Dual-fuel-Anwendung im Stand der Technik;

Figur 3:

schematisch ein Beispiel für ein Brenngasversorgungssystem mit einem Flüssiggasvorratstank mit Schaumisolierung für eine Single-fuel-Anwendung im Stand der Technik;

Figur 4:

schematisch ein Beispiel für ein Brenngasversorgungssystem mit einem Flüssiggasvorratstank mit Vakuumisolierung für eine Single-fuel-Anwendung im Stand der Technik;

Figur 5:

schematisch ein Beispiel für ein Brenngasversorgungssystem mit einem Flüssiggasvorratstank mit Schaumisolierung für eine Dual-fuel-Anwendung gemäß einer besonderen Ausführungsform der vorliegenden Erfindung;

Figur 6:

schematisch ein Beispiel für ein Brenngasversorgungssystem mit einem Flüssiggasvorratstank mit Vakuumisolierung für eine Dual-fuel-Anwendung gemäß einer besonderen Ausführungsform der vorliegenden Erfindung;

Figur 7:

schematisch ein Beispiel für ein Brenngasversorgungssystem mit einem Flüssiggasvorratstank mit Schaumisolierung für eine Single-fuel-Anwendung gemäß einer besonderen Ausführungsform der vorliegenden Erfindung; und

Figur 8:

schematisch ein Beispiel für ein Brenngasversorgungssystem mit einem Flüssiggasvorratstank mit Vakuumisolierung für eine Single-fuel-Anwendung gemäß einer besonderen Ausführungsform der vorliegenden Erfindung.

Further features and advantages of the invention emerge from the appended claims and from the following description of particularly advantageous embodiments in conjunction with the schematic drawings, in which:

Figure 1:

schematically an example of a fuel gas supply system with a liquid gas storage tank with foam insulation for a dual-fuel application in the prior art;

Figure 2:

schematically an example of a fuel gas supply system with a liquid gas storage tank with vacuum insulation for a dual-fuel application in the prior art;

Figure 3:

schematically an example of a fuel gas supply system with a liquid gas storage tank with foam insulation for a single-fuel application in the prior art;

Figure 4:

schematically an example of a fuel gas supply system with a liquid gas storage tank with vacuum insulation for a single-fuel application in the prior art;

Figure 5:

schematically an example of a fuel gas supply system with a liquid gas storage tank with foam insulation for a dual-fuel application according to a particular embodiment of the present invention;

Figure 6:

schematically an example of a fuel gas supply system with a liquid gas storage tank with vacuum insulation for a dual-fuel application according to a particular embodiment of the present invention;

Figure 7:

schematically an example of a fuel gas supply system with a liquid gas storage tank with foam insulation for a single-fuel application according to a particular embodiment of the present invention; and

Figure 8:

schematically shows an example of a fuel gas supply system with a liquid gas storage tank with vacuum insulation for a single-fuel application according to a particular embodiment of the present invention.

figure 5 shows schematically an example of a fuel gas supply system 200 based on liquid gas for a ship (not shown) with two gas-powered consumers 38, in the present example two gas-powered internal combustion engines, in a consumer installation room 36 according to a particular embodiment of the present invention. It includes a liquid gas storage tank 11, in this example designed as a C-tank according to IMO, with a metal tank shell 12 together with tank connections 15 on the top of the tank, in the present case without a dome, and a gas processing system 32 for processing gas, which is connected to the liquid gas storage tank 11 via a gas line 28, here including conversion of liquid gas into gas from the liquid gas storage tank 11, into gas, preferably with a low flash point, as fuel for the gas-operated consumers 38 in the consumer installation room 36, the liquid gas storage tank 11 together with tank connections and the gas processing device 32 being arranged in a common gas supply room 42, the gas supply space 42 being designed in such a way that it complies with the provisions of the International Code of Safety for Ships using Gases or other Low-flashpoint Fuels, IGF Code, in particular version 01.01.2017, of the International Maritime Organization, IMO, for tank connection spaces, TAR ( Tank Connection Space, TCS), and for gas processing spaces, GAR (Fuel Preparation Room, FPR), and the fuel gas supply system also has a gas line 34, one end of which is in gas connection with an outlet of the gas processing device 32 and the other end of which is connected to the gas supply space 42 brought out for a gas connection with the consumers 38 in the consumer installation room 36 and, in this example, through appropriate branches. In this example, the gas supply space 42 and the consumer installation space 36 are arranged directly next to one another. For example, they could also be arranged directly above or below one another.

As can also be seen from the figure 5 results, the fuel gas supply system comprises a bunker station 22 for bunkering liquid gas, which is in fluid communication with the liquid gas storage tank 11 via a bunker line 26 . Advantageously, the bunker station also has a gas-tight line bushing (not shown) for the bunker line 26 . A gas line 24 is used to pump gas from outside into the bunker station. A leak pan 44 is used to collect leakage quantities. In this example, the bunker station 22, like the gas supply room 42, has an access (for people) with a gas lock 20 in accordance with the IGF code.

The liquid gas storage tank 11 has foam insulation 14 around its tank shell 12 .

That in the figure 5 Fuel gas supply system 200 shown is part of a dual-fuel system.

That in the figure 6 The fuel gas supply system 200 shown as an example differs from that in FIG figure 5 Combustion gas supply system 200 shown only in that the liquid gas storage tank 11 has a vacuum insulation 16 instead of a foam insulation 14 . Incidentally, it also belongs to a dual-fuel system.

That in the figure 7 Combustion gas supply system 200 shown differs from that in FIG figure 5 Combustion gas supply system 200 shown essentially is that it is intended for a single-fuel system. For this purpose, in this example the gas supply space 42 is divided into two subspaces 42a and 42b by a partition 48 and the liquid gas storage tank 11 is part of both subspaces 42a and 42b and is integrated into the partition 48 . In addition, in each of the sub-chambers 42a and 42b it has tank connections 15 on the top of the tank, in this example without a dome, as well as a gas treatment device 32 and a gas line 28, so that each of the two sub-chambers 42a and 42b has a connection to the liquid gas storage tank 11 the respective gas line 28 in fluid connection gas processing device 32 for processing gas, here including conversion of liquid gas in the liquid gas storage tank 11, into gas, preferably with a low flash point, as a fuel for the gas-operated consumer in the consumer installation room 36 has a gas line 34, one end of which is in gas connection with an outlet of the respective gas treatment device 32 and whose other end leads out of the gas supply space 42 for a gas connection with the consumers 38 in the consumer installation room 36, and, in this example, through a corresponding branch, with the respective consumer 38 or the Consumers 38 is in gas connection.

In addition, each of the subrooms 42a and 42b has an entrance (for people) with a gas lock 20 according to the IGF Code.

Just like in the embodiment in the figure 5 the liquid gas storage tank 11 has a tank shell 12 with foam insulation 14 . In this example, the dividing bulkhead 48 is connected to the tank shell 12 by means of a steel spring element (spring element made of steel). However, other materials and/or elements can also be used for this purpose.

That in the figure 8 Combustion gas supply system 200 shown differs from that in FIG figure 7 Combustion gas supply system 200 shown only in that the liquid gas storage tank 11 has a vacuum insulation 16 instead of a foam insulation 14 . In addition, the partition wall 48 is connected to the outer shell (vacuum insulation 16) in terms of steel construction in this example.

The features of the invention disclosed in the above description, in the drawings and in the claims can be essential both individually and in any combination for the realization of the invention in its various embodiments.

REFERENCE LIST

10

tank installation room

11

LPG storage tank

12

tank cover

13

Dom

14

foam insulation

15

tank connections

16

vacuum insulation

18

Tank connection room (TAR)

20

gas lock

22

bunker station

24

gas line

26

bunker line

28

gas line

30

Gas treatment room (GAR)

32

gas treatment facility

34

gas line

36

consumer installation room

38

consumer

40

cold box

42

gas supply room

44

leak pan

46

steel spring element

48

bulkhead

100

fuel gas supply system

200

fuel gas supply system

Claims (15)

Fuel gas supply system (200), in particular based on liquid gas, for a ship with at least one gas-operated consumer in a consumer installation room (36), the fuel gas supply system (200) comprising: - A gas storage tank (11) together with tank connections (15) with or without dome (13) and - a gas treatment device (32) in fluid connection with the gas storage tank (11) via a line (28) for treating gas from the gas storage tank (11) into gas, preferably with a low flash point, as fuel for a gas-operated consumer (38) in a consumer installation room (36), wherein the gas storage tank (11) together with tank connections (15) and the gas treatment device (32) are arranged in a common gas supply room (42), the gas supply room (42) being designed in such a way that it complies with the provisions of the International Code of Safety for Ships using Gases or other Low-flashpoint Fuels, IGF Code, in particular version 01.01.2017, of the International Maritime Organisation, IMO, for tank connection spaces, TAR (Tank Connection Space, TCS), and for gas preparation spaces, GAR (Fuel Preparation Room, FPR), and the fuel gas supply system (100) also has a gas line (34), one end of which is in gas connection with an outlet of the gas processing device (32) and the other end of which leaves the gas supply space (42) for a gas connection with the Consumer (38) is brought out in the consumer installation room (36). Fuel gas supply system (200) according to claim 1, wherein it further comprises a bunkering station (22) for bunkering of liquid gas, which has a bunker line (26) is fluidly connected to the gas storage tank (11), preferably further comprising a gas-tight line bushing for the bunker line (26), in particular wherein there is also access with or without a gas lock (20) according to the IGF code for access to the bunker station (22) includes. Combustion gas supply system (200) according to one of the preceding claims, wherein it further comprises an access with or without a gas lock (20) according to the IGF code for access to the gas supply space (42) and/or wherein there is also a ventilation device for the gas supply space (42) includes. Fuel gas supply system (200) according to one of the preceding claims, further comprising a control and monitoring device for controlling and monitoring the same. Fuel gas supply system (200) according to one of the preceding claims, wherein the gas treatment device (32) comprises at least one evaporator and/or a gas heater and/or a heat exchanger, in particular a pressure build-up heat exchanger, and/or a buffer tank and/or a pump. Fuel gas supply system (200) according to one of the preceding claims, wherein the gas storage tank (11) is designed as a type C tank according to IMO. Fuel gas supply system (200) according to claim 6, wherein the gas storage tank (11) is arranged hanging, lying or standing, with a cylindrical shape or with a bilobe or multilobe shape, in the gas supply space (42). Fuel gas supply system (200) according to claim 6 or 7, wherein the gas storage tank (11) is designed as double-walled vacuum insulation or single-walled and insulated, in particular foam-insulated. Combustion gas supply system (200) according to one of the preceding claims, wherein the gas supply space (42) is divided into two sub-spaces (42a, 42b) by a partition (48) and the gas storage tank (11) is part of both sub-spaces (42a, 42b) and in the partition (48) is integrated. Fuel gas supply system (200) according to claim 9, wherein it has further tank connections (15) with or without a dome (13), a further gas treatment device (32) and a further gas line (28), so that each of the two sub-chambers (42a, 42b) has a gas treatment device (32) in fluid connection with the gas storage tank (11) via a respective gas line (28) for treating gas from the gas storage tank (11) into gas, preferably with a low flash point, as fuel for a gas-operated consumer (38) in the Consumer installation room (36) and a gas line (34), one end of which is in gas connection with an outlet of the respective gas treatment device (32) and the other end of which leaves the gas supply room (42) for a gas connection to the consumer (38) in the consumer installation room ( 36) is brought out. Fuel gas supply system (200) according to claim 9 or 10, wherein it comprises a further access with or without a gas lock (20) according to the IGF code for access to the gas supply space (42), so that there is an access with or without a gas lock (20) according to the IGF code for the subspaces (42a, 42b). Fuel gas supply system (200) according to any one of the preceding claims, wherein the consumer (38) is an internal combustion engine or a boiler or includes the same, in particular the internal combustion engine is designed as a dual-fuel machine or purely gas-powered machine. Fuel gas supply system (200) according to one of the preceding claims, wherein it is designed for arrangement on the deck of a ship, in particular wherein the gas supply space (42) is designed as a container or is designed in a container. Combustion gas supply system (200) according to one of Claims 1 to 13, in which it is designed to be arranged below deck of a ship, in particular in which the gas supply space (42) is designed as part of a ship's hull with an outer skin contour or in which the gas supply space (42) is designed as a pre-equipped shipbuilding section in a ship's hull is formed. Ship with at least one gas-operated consumer (38) in a consumer installation room (36), comprising a fuel gas supply system (200) according to one of the preceding claims, in particular wherein the gas supply room (42), preferably directly, is arranged adjacent to the consumer installation room (36).

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