EP2686235A1

EP2686235A1 - Ship

Info

Publication number: EP2686235A1
Application number: EP12710206.9A
Authority: EP
Inventors: Rolf Rohden
Original assignee: Wobben Properties GmbH
Current assignee: Wobben Properties GmbH
Priority date: 2011-03-15
Filing date: 2012-03-15
Publication date: 2014-01-22
Also published as: TW201242840A; CA2828658A1; JP2014509569A; JP5797284B2; WO2012123547A1; KR20130133862A; CN103619704A; TWI468320B; US20140072460A1; DE102011005588A1; KR101596108B1; CA2828658C

Abstract

The invention relates to a ship (102) comprising at least one electric motor (8, 108, 109) for driving the ship (102), and a cooling device (1) for cooling the at least one electric motor (8, 108, 109) by means of at least one coolant. The invention also provides that the cooling device (1) has a heat exchanger (2, 3), which is designed for cooling the at least one coolant by means of seawater (16, 17).

Description

ship

The invention relates to a ship with at least one electric motor for driving the ship, and a cooling device for cooling the at least one motor by means of at least one coolant. Furthermore, the invention relates to a cooling device for a ship with at least one electric motor. The drive of ships has so far been mainly caused by internal combustion engines. For smaller vessels, for example in the leisure sector, electrical drives were often used. Recently, attempts are being made to drive larger ships, such as cargo ships and container ships, by means of electric drives. The climate at sea is a problem for these drives, which often have complicated and expensive electronics. In particular, the cooling of such electric drives for cargo ships is a hitherto inadequately solved problem.

Object of the present invention is to contribute to the solution of this problem to make a contribution, in particular to provide an electric motor driven ship with improved cooling.

The object is achieved in a ship of the type mentioned above in that the cooling device has a heat exchanger, which is adapted to cool the at least one coolant by means of seawater.

Accordingly, a ship according to the invention has at least two cooling circuits, which are coupled together. In a first cycle, coolant circulates between the at least one electric motor and the heat exchanger. In a second cycle, seawater circulates between the heat exchanger and an outside area of the ship. Through the heat exchanger, the two circuits are separated so that coolant and seawater do not mix. As a result, the at least one electric motor does not come into contact with seawater. Thus, according to the invention, corrosion of the at least one electric motor is substantially reduced, thereby significantly prolonging the service life. Furthermore, the maintenance effort is significantly reduced. The construction and production of such an electric motor is simplified because it is not designed for direct cooling by seawater got to. Another advantage is also that a ship is improved with a drive designed in this way in terms of energy consumption and safety. Seawater represents a natural and almost unlimited cold resource. The temperature of the seawater is essentially constant during a trip with the ship, so that such a cooling device does not require permanent adaptation. Furthermore, it is not necessary to install complicated devices for refrigeration on board a ship according to the invention, whereby on the one hand the reliability, on the other hand, the energy consumption of such a ship can be improved. Preferably, the heat exchanger is designed as a countercurrent heat exchanger. Alternatively, the heat exchanger is designed as a DC heat exchanger. According to the invention, a plurality of heat exchangers can also be used so that the coolant can be cooled in a multi-stage heat transfer process.

According to a first preferred embodiment, the coolant is air and / or fresh water. Under fresh water according to the invention is not to understand seawater, but for example, cooling water, cooling fluid and water-oil emulsions and the like. Air here refers to indoor air, not to salty sea air. These two coolants are particularly preferred since they are readily available and have already been widely used for electric motors. The heat transfer from seawater to fresh water is easy to design due to the good heat conduction. For heat transfer from seawater to air, it is preferable to use specially adapted heat exchangers.

According to a further preferred embodiment, the coolant is air and a rotor and / or a stator of the electric motor is / are coolable by means of this air. Air is preferred in particular for cooling a rotor of an electric motor. The cooled air can for example be passed through the gap between the rotor and the stator, cooling fins can be arranged on the stator or cooling channels are guided through the stator, through which the cool air can be conducted. In addition, the air can be passed into an inner cavity of the rotor and thus cool it.

In a further preferred embodiment, the at least one electric motor is arranged in an essentially hermetically sealed engine compartment of the ship and the air for cooling the electric motor is room air. Thus, the at least one electric motor is not exposed to salty air, whereby corrosion on the engine is largely avoided. As a result, on the one hand, the maintenance of such a motor or a Ship according to the invention with such an engine and such a cooling device significantly reduced and the reliability of the ship is improved. According to this preferred embodiment, a separate space can be provided for each engine, or all engines are arranged together in a substantially hermetically sealed space. In addition, a power supply of the motors can be arranged in this room. Likewise, the heat exchanger can be arranged in this hermetically sealed space, or otherwise be in fluid communication with this room.

According to a further preferred embodiment, means for conveying air are arranged on a cooling air inlet and / or a warm air outlet of the electric motor. For example, cool air can be directed to the electric motor or directed against it. Also, this air in cooling channels, via cooling fins, in recesses or cavities or the like on the electric motor can be conducted. In addition, warm air can be directed away from the electric motor. Thus, a targeted cooling of the engine is adjustable. In addition, a targeted volume flow or a targeted air speed can be adjusted via the engine so that it can be cooled in a targeted manner. This achieves efficient operation of the engine and extends the life of an engine. Also, the maintenance is further reduced.

According to a further preferred embodiment, means for guiding the air are arranged between a cooling air inlet of the electric motor and a cooling air outlet of the heat transfer and / or between a warm air outlet of the electric motor and a warm air inlet of the heat transfer. Such means may include, for example, hoses, channels, pipes, shafts, etc. A targeted air supply and removal is developed according to the invention and improved effective cooling of the engine. Alternatively or additionally, the means for guiding the air may comprise means for conveying air. According to one embodiment, the means for guiding the air between a cooling air inlet of the electric motor and a cooling air outlet of the heat exchanger are arranged. According to this embodiment, cool air is directed by means of the means for guiding the air specifically to the engine, the engine is cooled by means of the air fed to it, the warm air is then discharged into the space, which is preferably hermetically sealed. The heated room air is then then cooled by the heat transfer again. In an alternative, the means for guiding the air between a hot air outlet of the electric motor and a hot air inlet of the heat transfer are arranged. According to this embodiment Form, the warm air is led away from the electric motor, to the heat exchanger by means of which it is cooled. Subsequently, the cooled air is discharged into the room, which is preferably hermetically sealed. According to a third embodiment, means for guiding the air are arranged both between a cooling air outlet of the heat transfer and a cooling air inlet of the electric motor, and between a warm air outlet of the electric motor and a warm air inlet of the heat transfer. The cooling air circulates in a substantially closed system. According to this embodiment, the space need not be hermetically sealed, but it is sufficient to protect the motors against saline air. According to a further preferred embodiment, the at least one electric motor has cooling channels on a housing and / or on a stator. The cooling channels can run through the housing and / or along a stator winding. By means of such cooling channels targeted cooling of a motor is possible. The cooling channels can be embodied in various geometries, for example straight, curved, zigzag or in another way. Ribs may also be disposed in the channels for even more effective cooling.

According to a further embodiment, air for cooling is feasible through the cooling channels and / or a gap between the stator and a rotor. Thus, an effective cooling of the electric motor is advantageously developed. For example, means for guiding the air and / or means for conveying the air can be connected to the cooling channels.

According to a further preferred embodiment, the coolant is fresh water, which is feasible through the cooling channels for cooling the electric motor. So even more effective cooling of an electric motor is possible. According to this embodiment, the fresh water is cooled by the heat transfer, passed down through pipes, hoses or the like to the channels, passed through the channels, and then heated again passed back to the heat exchanger.

According to a further preferred embodiment, the cooling device has a second heat exchanger, which is connectable to the first heat exchanger and which is adapted to cool air by means of fresh water, wherein the fresh water is coolable by means of the first heat exchanger by means of seawater. So can be cooled with a heat exchanger fresh water and air. For example, it is possible using a large primary heat exchanger to cool fresh water by means of seawater, to direct this fresh water to various engines or other facilities in the ship, such as diesel engines. The electric motors can therefore each have their own second small heat exchanger, by means of which air is cooled by the cool fresh water. The fresh water can then be used in addition to, for example, to cool the stator of the engine, while the cooled air is used to be passed through a gap between the rotor and stator and so to cool the rotor. According to a further preferred embodiment, the first heat exchanger can be connected to the stator of the electric motor and arranged to cool it by means of the fresh water.

According to a further preferred embodiment, the power supply has at least one converter and the converter can be cooled by means of fresh water. In particular, it is preferable to cool these converters by means of the fresh water, since they are preferably arranged in a local proximity to the electric motors. It is also preferable to arrange both the converter cooling or the energy supply cooling and the electric motor cooling to the same cooling circuit of fresh water. However, it is also possible to provide different cooling circuits.

According to a further aspect of the invention, the object is achieved in a cooling device of the type mentioned above in that the cooling device is designed according to one of the above-mentioned embodiments. Such a cooling device can be used in a variety of ships, watercraft or yachts, for example, to cool electric motors or other devices to be cooled. Such a cooling device helps to make the ship low maintenance and reliable and to reduce energy consumption. When using such a cooling device in a ship, all the advantages mentioned above are realized.

The invention is described below by means of embodiments with reference to the accompanying drawings. Show it:

1 shows a ship according to the invention in a perspective view, partially broken away; Figure 2 is a schematic representation of a first embodiment of a

Cooling device; Figure 3 is a schematic representation of a second embodiment of a cooling device;

Figure 4 is a schematic representation of a third embodiment of a

Cooling device; and FIG. 5 shows a schematic illustration of a fourth exemplary embodiment of a

Cooling device.

The ship 102 shown in Figure 1 has on a deck 1 14 four Magnusrotoren 1 10 as propulsion devices. In addition to these Magnusrotoren 1 10, the ship also optionally has a bridge 130 and a crane 105 and a crane 103 on the deck 1 14 on. As a further propulsion device, the ship additionally has a ship's propeller 150 at the stern of the ship 102. This propeller 150 may be connected via a shaft 1 1 1 with two electric motors 108, 109. The electric motors 108, 109 are fed via two converter cabinets 1 15, 1 16 with electric current. Above the electric motors 108, 109 and the inverter cabinets 1 15, 1 16 a ceiling 172 is arranged, which preferably closes the engine compartment relative to a cargo space airtight. As electric motors 108, 109 are preferably large-volume electric motors, e.g. Synchronous machines, used at a low speed, so that in the entire drive train, a gearbox is not necessarily provided. Furthermore, the motors are preferably selectively operable. For a light inlet into the interior of the ship 102, this has on the sides of window 1 18.

Figures 2 to 4 show exemplary embodiments of a cooling device according to the invention for a ship according to the invention 102 by means of which the electric motors 108, 109 are coolable.

According to Figure 2, the cooling device 1 in a first embodiment, a heat exchanger 2, which can be fed on one side 4 with a seawater stream 16. The seawater flow is indicated here only schematically by the arrows. In a ship 102, as shown in Figure 1, the seawater stream 16 can be directed by pipes to the heat exchanger 2 back and forth. On a second side 6, the heat exchanger 2 has an air inlet 24 and an air outlet 26. Thus, air can be cooled by means of this heat exchanger 2. Furthermore, an electric motor 8 is shown in FIG. The electric motor 8 has a stator 10, which may have a stator housing. Furthermore, the electric motor 8 has a rotor 12 which, in operation, rotates about an axis of rotation 14 and can be coupled to a drive unit of a ship, such as a shaft 1 1 1 and a marine propeller 150 (FIG. 1). The electric motor 8 together with its elements is arranged in a space 19, which is closed by a wall 18 substantially airtight. The heat exchanger 2 is arranged together with its elements outside of the space 19. The stator or the stator housing 10 of the electric motor 8 also has an air inlet 20 and an air outlet 22. At each of these, as a means for conveying the air, a fan 20a, 22a is arranged to convey the air into or out of the engine 8; Alternatively, other pumps such as vane pumps o. The like. Be used for this purpose. Preferably, the air can be conducted through cooling channels in the stator or the stator housing 10, and / or through a gap between the rotor 12 and the stator 10. A tube 30 is arranged between the air outlet 22 and the air inlet 24 of the heat exchanger 2. Through this pipe 30 warm air is discharged from the engine 8 and passed to the heat exchanger 2. The cool air exiting the air outlet 26 of the heat exchanger 2 is conducted by means of a second tube 32 to an air inlet 28 of the space 19 in the wall 18. From this air inlet 28, the air enters the space 19 so that it is filled with cool air in total. The cool room air is then sucked by the fan 20a at the air inlet 20 and passed into the cooling channels or the gap between the rotor 12 and the stator 10. By filling the space 19 with cool air, the fan 20a in the inlet 20 can always suck in as much air as is needed to cool the engine 8 to a temperature required for optimum performance. Further, the motor 8 is also cooled by air, which is not blown directly into the motor 8, or sucked, but sweeps along its surface. Preferably, the space 19 is hermetically sealed by means of the wall 18 or ceilings, doors, hatches, etc., so that in a ship 102 (FIG. 1) no or as little salty air as possible reaches the space 19. Alternatively, it is also according to the invention that the space 19 is not hermetically sealed, but within the space 19 there is an overpressure, so that saline air can not flow from outside into the interior of the space 19. Likewise, it is also possible that a pipe is arranged between the inlet 28 of the space 19 and the inlet 20 of the engine 8, and / or that no pipe 30 is arranged between the outlet 22 of the engine 8 and the inlet 24 of the heat exchanger 2. In the second exemplary embodiment of the cooling device 1 according to FIG. 3, the cooling device 1 has a first heat exchanger 2 and a second heat exchanger 3. Both heat exchangers 2, 3 are coupled to a motor 8 and serve to cool them by means of coolant. The first heat exchanger 2 is arranged in a first cooling circuit, which substantially corresponds to the first embodiment according to FIG. 2 of the cooling device 1. The second cooling circuit, in which the second heat exchanger 3 is arranged, uses as coolant fresh water, such as cooling water, or other cooling liquid. The second heat exchanger 3, like the first heat exchanger 2, is coupled to a seawater flow 17, this seawater flow 17 in turn being able to be conducted to the heat exchanger 3, for example via pipes from an outer region of the ship 102 in a ship 102 according to FIG. The heat exchanger 3 is connected in a second side 7 with two cooling water lines 34, 36, which each have a pump 38, 40. The pumps 38, 40 are adapted to deliver a corresponding cooling water flow. The cooling water lines 34, 36 lead from outside the room where the heat exchanger 3 is arranged in the interior 19 of the room and are there connected to a heat sink 42. For this purpose, the heat sink 42 has a cooling water inlet 44 and a cooling water outlet 46. According to FIG. 3, the heat sink 42 is arranged on an outer section of the motor housing or of the stator 10 of the electric motor 8. This is just a schematic illustration. It is also possible to provide in a housing or in the stator 10 cooling channels through which cooling water is conductive. According to this exemplary embodiment, it is possible, for example, to substantially cool the rotor 12 with the air which can be conducted through the air inlet 20 into the interior of the motor 8 and to cool the stator 10 of the motor 8 substantially with water which flows over the Heat exchanger 3 can be cooled by means of the seawater flow 17 and circulated by means of the cooling water lines 34, 36 between the heat exchanger 3 and heat sink 42.

FIG. 4 shows a further alternative of a cooling device 1. In addition to the cooling device 1 shown in FIG. 3, the cooling device 1 according to FIG. 4 has a third cooling circuit. The third cooling circuit is fed as well as the second cooling circuit by means of the heat exchanger 3, which is adapted to cool cooling water by means of a seawater flow 17. According to FIG. 4, two further cooling water lines 35, 37 branch off from the cooling water lines 34, 36 and lead cooling water toward or away from a converter cabinet 48. The converter cabinet 48 is connected to the electric motor 8 via a power supply cable 50. In the inverter cabinet 48, a plurality of inverters are arranged, which are adapted to electrical To provide current with a voltage and a frequency that are required by the electric motor 8. To ensure optimum operation of a converter cabinet 48, it is preferable to cool it. According to the embodiment, the converter cabinet 48, or the converter contained in it is cooled with cooling water, which is cooled by means of the heat exchanger 3 by means of a seawater flow 17. The cooled cooling water is conveyed on a second side 7 of the heat exchanger 3 by a pump 40, flows through a cooling water supply line 37 up to the converter cabinet 48. In this a plurality of heat sinks may be arranged, or lamellae or the like which transport heat away from the inverters , The heated water is then conveyed away by means of the cooling water line 35 and the pump 38 of the converter cabinet 48 and passes back to the heat exchanger 3. The two other cooling circuits are formed according to the cooling circuits of Figure 3.

Another alternative of the cooling device 1 is shown as an exemplary embodiment according to FIG. According to this embodiment (FIG. 5), the cooling device 1 has essential features in common with the exemplary embodiment according to FIG. The cooling circuits, which are used for cooling the electric motor 8 according to the embodiment of Figure 5, are cascaded. The cooling device has a first heat exchanger 2 and a second heat exchanger 3. The heat exchanger 3 has a first side 5 and a second side 7, wherein in the first side 5, a seawater flow 17 is conductive, and to the second side cooling water lines 34, 36 are connected. The first heat exchanger 2 also has a first side 4 and a second side 6, wherein two cooling water lines 52, 54 are connected to the first side 4 and to the second side 6 two air channels 30, 32nd Die Kühlwasserleitungen 52, 54 lead to the second side 7 of the second heat exchanger 3. The interaction of the air ducts 30, 32 with the electric motor 8 and the cooling channels 34, 36 with the cooling element 42 are formed according to the embodiment of Figure 3. According to the present embodiment (Figure 5), a seawater flow 17 is used to cool cooling water, which is then used on the one hand to cool the electric motor 8 via a heat sink 42 and on the other hand is used in the first heat exchanger 2 to cool air, which then in turn is used to cool the electric motor 8 and in particular the rotor 12. Thus, only one seawater access is necessary for the entire cooling system, and moreover, corrosion in the first heat exchanger 2 can be largely avoided. If more than one engine 8, 108, 109 is arranged in a ship 102 (FIG. 1), a cooling device may be provided for each engine, or a common cooling device for a plurality of engines. If a cooling device for a plurality of motors according to the embodiment of Figure 5 is executed, for example, for each electric motor 8, 108, 109, a first heat exchanger 2 may be arranged, said plurality of first heat exchanger 2 cooperating with a single second heat exchanger 3.

Claims

claims

1 . Ship (102) with

at least one electric motor (8, 108, 109) for driving in particular a ship's screw (150) of the ship (102), and a cooling device (1) for cooling the at least one electric motor (8, 108, 109) by means of at least one coolant, characterized in that the cooling device (1) has a heat exchanger (2, 3) which is adapted to cool the at least one coolant by means of seawater (16, 17).

2. Ship according to claim 1,

characterized in that the coolant is air and / or fresh water.

3. Ship according to claim 1,

characterized in that the coolant is air and a rotor (12) and / or a stator (10) of the electric motor (8, 108, 109) is coolable by means of this air / are.

4. Ship according to claim 3,

characterized in that the at least one electric motor (8, 108, 109) is arranged in a substantially hermetically sealed engine compartment (19) of the ship (102) and the air for cooling the electric motor (8, 108, 109) is room air.

5. Ship according to claim 3 or 4,

characterized in that means (20a, 22a) for conveying air are arranged on a cooling air inlet (20) and / or a warm air outlet (22) of the electric motor (8, 108, 109).

6. Ship according to one of the preceding claims,

characterized in that between a cooling air inlet (20) of the electric motor (8, 108, 109) and a cooling air outlet (26) of the heat exchanger (2, 3) and / or between a hot air outlet (22) of the electric motor (8, 108, 109) and a warm air inlet (24) of the heat exchanger (2, 3) has means (20a, 22a) for guiding the air (30, 32).

7. Ship according to one of the preceding claims,

characterized in that the at least one electric motor (8, 108, 109) on a housing and / or on a stator (10) has cooling channels.

8. Ship according to claim 7,

characterized in that through the cooling channels and / or a gap between the stator (10) and a rotor (12) air for cooling is feasible.

9. Ship according to claim 7,

characterized in that the coolant is fresh water, which is feasible through the cooling channels for cooling the electric motor (8, 108, 109).

10. Ship according to one of the preceding claims,

characterized in that the cooling device (1) comprises a second heat exchanger (2) which is connectable to the first heat exchanger (3) and which is adapted to cool air by means of fresh water, wherein the fresh water by means of the first heat exchanger (3) Seawater is coolable.

1 1. Ship according to claim 10,

characterized in that the first heat exchanger (2, 3) with the stator (10) of the electric motor (8, 108, 109) is connectable and adapted to cool it by means of the fresh water.

12. Ship according to one of the preceding claims,

characterized by a power supply (48) which is coolable by means of the coolant.

13. Ship according to claim 12,

characterized in that the power supply (48) comprises at least one inverter and the inverter is coolable by means of fresh water.

14. Cooling device for a ship (102) with at least one electric motor (8, 108, 109), for cooling by means of at least one coolant, with

a heat exchanger (2, 3) which is adapted to cool the at least one coolant by means of seawater (16, 17).