阅读说明：本技术 用于船只的电气推进系统的冷却系统 (Cooling system for an electric propulsion system of a ship ) 是由 J.D.多雷穆斯 T.费耶 E.T.威尔斯 于 2020-02-07 设计创作，主要内容包括：一种用于船的冷却系统包括至少一个冷却器,其位于船的船体内部并且对船体的外部封闭。该冷却器构造成用于经由定位在冷却剂流和流体流之间的船体壁在至少一个冷却器中的冷却剂流与船体外部的流体流之间交换热能。一个或多个冷却剂通道从限定至少一个冷却剂回路的至少一个冷却器延伸。一个或多个冷却剂通道构造成将冷却剂流从至少一个冷却器传递到沿至少一个冷却剂回路设置的一个或多个部件,以冷却所述一个或多个部件并且使冷却剂流返回到至少一个冷却器。(A cooling system for a ship comprises at least one cooler which is located inside the hull of the ship and is closed to the outside of the hull. The cooler is configured for exchanging thermal energy between the coolant flow in the at least one cooler and the fluid flow outside the hull via a wall of the hull positioned between the coolant flow and the fluid flow. One or more coolant channels extend from at least one cooler defining at least one coolant circuit. The one or more coolant passages are configured to transfer a flow of coolant from the at least one cooler to one or more components disposed along the at least one coolant circuit to cool the one or more components and return the flow of coolant to the at least one cooler.)

1. A cooling system for a ship, comprising:

at least one cooler arranged inside the hull of the vessel and closed to the outside of the hull, the cooler being configured for exchanging thermal energy between the coolant flow in the at least one cooler and the fluid flow outside the hull via a hull wall arranged between the coolant flow and the fluid flow; and

one or more coolant channels extending from the at least one cooler defining the at least one coolant loop, the one or more coolant channels configured to communicate a flow of coolant from the at least one cooler to one or more components disposed along the at least one coolant loop to cool the one or more components and return the flow of coolant to the at least one cooler.

2. The cooling system of claim 1, wherein the at least one cooler is disposed at a ridge of the hull.

3. The cooling system of claim 2, further comprising a ridge enclosure secured to an interior of the hull to enclose a ridge recess defined by the ridge, the enclosed ridge recess defining a cooler of the at least one cooler.

4. The cooling system of claim 3, wherein the ridge seal is secured to the interior of the hull by welding.

5. The cooling system of claim 1, wherein the one or more components are one or more electrical components of a marine propulsion system.

6. The cooling system of claim 1, further comprising a pump to propel a flow of coolant along the at least one coolant loop.

7. The cooling system of claim 1, wherein the at least one cooler is two coolers disposed at opposite sides of the hull.

8. The cooling system of claim 7, wherein the at least one cooling circuit is two coolant circuits, and wherein a first of the two coolant circuits comprises a first of two coolers and a second of the two coolant circuits comprises a second of two coolers.

9. The cooling system of claim 8, wherein the first and second coolant circuits are constructed and arranged to cool different ones of the one or more components.

10. A method of cooling one or more propulsion system components of a ship, comprising:

forcing a coolant flow through at least one ridge cooler disposed inside the hull of the vessel and abutting the outer hull wall;

exchanging thermal energy between the coolant flow in the at least one ridge cooler and the fluid flow outside the hull via an outer hull wall disposed between the coolant flow and the fluid flow;

directing a flow of coolant from the at least one ridge cooler along one or more coolant channels defining at least one coolant circuit;

cooling one or more propulsion system components disposed along at least one coolant circuit via a thermal energy exchange between the coolant flow and the one or more propulsion system components; and

urging a flow of coolant from the coolant loop to the at least one ridge cooler.

Technical Field

The subject disclosure relates to watercraft, and more particularly to cooling systems for marine propulsion systems and components.

Background

Conventional ship cooling systems utilize water pumped through the hull as a cooling fluid. Water is drawn from a body of water (also referred to herein as seawater) into a vessel where the vessel is operated by a pump and then in some systems routed through a heat exchanger for thermal energy exchange with a coolant stream that also circulates through the heat exchanger. The coolant is then circulated to the engine, motor, or other components to cool the components before being recirculated to the heat exchanger. The water flows through the heat exchanger and is discharged to the outside of the ship by the ship cooling system.

In such systems, flow through the cooling system continues as long as the engine is running. Such systems require the absorption of seawater by the hull. Furthermore, such systems are problematic on certain boats, such as those propelled by battery-powered electric motors, which do not have an operational idle mode or speed. In such a ship, cooling of components such as electric motors and batteries will stop unless the ship is powered on. In other systems, keel coolers mounted on the exterior of the hull are utilized. Keel coolers present additional drag to the hull and require drilling holes in the hull, which presents additional potential failure points to the system. Furthermore, keel coolers are prone to damage due to collisions with underwater objects because they are located outside the hull.

Disclosure of Invention

In an embodiment, a cooling system for a ship comprises at least one cooler located inside the hull of the ship and closed to the outside of the hull. The cooler is configured for exchanging thermal energy between the coolant flow in the at least one cooler and the fluid flow outside the hull via a wall of the hull positioned between the coolant flow and the fluid flow. One or more coolant channels extend from at least one cooler defining at least one coolant circuit. The one or more coolant channels are configured to transfer a flow of coolant from the at least one cooler to one or more components positioned along the at least one coolant loop to cool the one or more components and return the flow of coolant to the at least one cooler.

Additionally or alternatively, in this or other embodiments, the at least one cooler is located at a spine of the hull.

Additionally or alternatively, in this or other embodiments, the ridge seal is secured to the interior of the hull to enclose a ridge recess defined by the ridge. The surrounding ridge recess defines a cooler of the at least one cooler.

Additionally or alternatively, in this or other embodiments, the ridge closure is secured to the interior of the hull by welding.

Additionally or alternatively, in this or other embodiments, the hull is formed of aluminum.

Additionally or alternatively, in this or other embodiments, the one or more components are one or more electrical components of a boat propulsion system.

Additionally or alternatively, in this or other embodiments, the pump is configured to propel a flow of coolant along the at least one coolant loop.

Additionally or alternatively, in this or other embodiments, the at least one cooler is two coolers located at opposite sides of the hull.

Additionally or alternatively, in this or other embodiments, the at least one cooling circuit is two coolant circuits. The first of the two coolant circuits comprises a first of the two coolers, and the second of the two coolant circuits comprises a second of the two coolers.

Additionally or alternatively, in this or other embodiments, the first coolant circuit and the second coolant circuit are configured and arranged to cool different ones of the one or more components.

Additionally or alternatively, in this or other embodiments, the fluid flow is one of water or air.

In another embodiment, a vessel includes a hull and a propulsion system located in the hull and configured to propel the hull. A cooling system is located in the hull and is configured to cool one or more components of the propulsion system. The cooling system comprises at least one cooler which is located inside the hull and is closed to the outside of the hull. The cooler is configured for exchanging thermal energy between the coolant flow in the at least one cooler and the fluid flow outside the hull via a wall of the hull positioned between the coolant flow and the fluid flow. One or more coolant channels extend from at least one cooler defining at least one coolant circuit. The one or more coolant channels are configured to transfer a flow of coolant from the at least one cooler to one or more components positioned along the at least one coolant loop to cool the one or more components and return the flow of coolant to the at least one cooler.

Additionally or alternatively, in this or other embodiments, the at least one cooler is located at a spine of the hull.

Additionally or alternatively, in this or other embodiments, the ridge seal is secured to the interior of the hull to enclose a ridge recess defined by the ridge. The surrounding ridge recess defines a cooler of the at least one cooler.

Additionally or alternatively, in this or other embodiments, the at least one cooler is two coolers located at opposite sides of the hull.

Additionally or alternatively, in this or other embodiments, the at least one cooling circuit is two coolant circuits. The first of the two coolant circuits comprises a first of the two coolers, and the second of the two coolant circuits comprises a second of the two coolers.

Additionally or alternatively, in this or other embodiments, the first coolant circuit and the second coolant circuit are configured and arranged to cool different ones of the one or more components.

Additionally or alternatively, in this or other embodiments, the propulsion system is an electric propulsion system that includes an electric motor, a strut operatively connected to and driven by the electric motor, and one or more batteries operatively connected to the electric motor to provide power to the electric motor. The one or more components include at least one of an electric motor or one or more batteries.

Additionally or alternatively, in this or other embodiments, the vessel comprises a central hull and two outer hulls disposed laterally outboard of the central hull. At least one cooler is located in one of the two outer hulls.

In yet another embodiment, a method of cooling one or more propulsion system components of a ship includes forcing a coolant flow through at least one spine cooler positioned inside a hull of the ship and abutting an outer hull wall, and exchanging thermal energy between the coolant flow in the at least one spine cooler and a fluid flow outside the hull via the outer hull wall positioned between the coolant flow and the fluid flow. The coolant flow from the at least one ridge cooler is directed along one or more coolant channels defining at least one coolant loop. One or more propulsion system components are positioned along the at least one coolant circuit and cooled via thermal energy exchange between the coolant flow and the one or more propulsion system components. Urging a flow of coolant from the coolant loop to the at least one ridge cooler.

The above features and advantages and other features and advantages of the present disclosure will be readily apparent from the following detailed description when taken in connection with the accompanying drawings.

Drawings

Other features, advantages and details appear, by way of example only, in the following detailed description, the detailed description referring to the drawings in which:

FIG. 1 is a schematic view of an embodiment of a watercraft;

FIG. 2 is a rear cross-sectional view of an embodiment of a hull;

FIG. 3 is a rear cross-sectional view of another embodiment of the hull;

FIG. 4 is a schematic view of an embodiment of a cooling system for a vessel utilizing a spine cooler;

FIG. 5 is another schematic view of an embodiment of a cooling system for a vessel utilizing a spine cooler; and

FIG. 6 is yet another schematic view of an embodiment of a cooling system for a vessel utilizing a ridge cooler.

Detailed Description

The following description is merely exemplary in nature and is not intended to limit the present disclosure, application, or uses. It should be understood that throughout the drawings, corresponding reference numerals indicate like or corresponding parts and features.

The exemplary embodiment according to fig. 1 is an embodiment of a ship or vessel 10. The boat 10 has a propulsion system 12 which in the embodiment of fig. 1 includes an electric motor 14 connected to a stern drive 16, the stern drive 16 propelling the boat 10 via rotation of struts 18 about strut axes 20. In some embodiments, the electric motor 14 is connected to the stern drive 16 via a drive shaft 22, while in other embodiments, the drive shaft is omitted and the electric motor 14 and stern drive 16 are directly connected. Although a configuration of the stern drive 16 is shown and described herein, those skilled in the art will appreciate that the present disclosure may readily be applied to boats 10 having other propulsion system configurations, such as inboard or outboard motor configurations. Operation of the electric motor 14 drives rotation of the drive shaft 22, which in turn urges rotation of the strut 18, either directly or via an intermediate connection or gear reduction (not shown). The electric motor 14 is powered by one or more batteries 24 connected to the electric motor 14. When the vessel 10 is docked or moored onshore, the battery 24 is periodically charged through, for example, an electrical outlet 26 connected to a power supply 28. The propulsion system 12 also includes an Accessory Power Module (APM)68 that converts 350V DC to 12V DC power to charge the onboard 12V electrical system, a Single Power Inverter Module (SPIM)70 that converts 350V DC power to three-phase AC power to power the electric motor 14, and an onboard charging module (OBCM)72 that converts AC power from the grid to DC power to charge the one or more batteries 24. The propulsion system 12 is disposed in the hull 30 and is operatively connected to a controller 32 operable by a user of the vessel 10. In some embodiments, hull 30 is formed of aluminum, but in other embodiments other materials, such as fiberglass, are used in the construction of hull 30.

Referring now to fig. 2, a schematic rear cross-sectional view of an embodiment of hull 30 is shown. The hull 30 has a V-shaped bottom with an outer hull surface 34 extending from a keel 36 toward a track 38. The hull outer surface 34 has one or more ridges 40, or sharp changes in angle between the keel 36 and the track 38. In the embodiment of fig. 2, the outboard surface 34 includes ridges 40 formed by a 90 degree angular change in the outboard surface 34. It should be understood that the shape of the hull outer surface 34 and the illustrated ridges 40 are merely exemplary, and one skilled in the art will readily appreciate that the present disclosure may be applied to other hull outer surface 34 shapes and ridge 40 configurations. As shown in FIG. 1, the spine 40 extends longitudinally along the hull 30 from a spine first end 42 to a spine second end 44.

Referring again to fig. 2, the ridges 40 define ridge recesses 46 inside the hull 30. The ridge seal 48 is secured and sealed to the hull 30 at the ridge 40, for example, between the ridge 40 and the keel 36 and between the ridge 40 and the track 38. The ridge seal 48 surrounds the ridge recess 46 and, together with the hull 30, defines a sealed ridge cooler 50 within the ridge recess 46. In some embodiments, the ridge seal 48 is secured to the hull 30, such as by welding. The ridge seal 48 may be formed of the same material as the hull 30, such as aluminum, or may be formed of a different material than the hull 30, such as a plastic or fiber-reinforced composite material. The ridge cooler 50 is closed to the outside of the hull 30. In other words, no passages or openings in the spine cooler 50 extend through the hull 30 to the exterior thereof. In addition to or in lieu of the spine cooler 50, the boat 10 may include one or more keel coolers 90 defined by securing and sealing keel closures 92 at the keels 36, as shown in FIG. 2.

The coolant flows through the ridge cooler 50. In some embodiments, the coolant is water or other fluid. Thermal energy is conducted away from the coolant in the ridge cooler 50 through the outer hull surface 34 adjacent the ridge cooler 50 and to the body of water 52 in which the ship 10 is operating. Due to the shape of ridge recess 46, heat energy is conducted from ridge cooler 50 through an upper portion 54 of ridge cooler 50 between rail 38 and ridge 40 and a lower portion 56 of ridge cooler 50 between ridge 40 and keel 36. When the hull 30 is formed of a high thermal conductive material such as aluminum, the efficiency of thermal energy transfer is improved.

In another embodiment, as shown in fig. 3, the hull 30 is a multi-hull construction having, for example, a central hull 200 and two outer hulls 202 located laterally outboard of the central hull 200. In the embodiment of fig. 3, the center hull 200 may include one or more spine coolers 50 and/or one or more keel coolers 90, as described above with reference to fig. 2. Additionally or alternatively, one or more of the outer hulls 202 may include an outer hull cooler 204. In some embodiments, the outer hull 202 includes outwardly facing outer hull flaps 206. The outer hull sails 206 are defined as protrusions in the outer hull surface 208 and define a sail recess 210 inside the outer hull 202. The sail closure 212 surrounds the sail recess 210 and together with the outer hull 202 defines a sealed outer hull cooler 204 within the sail recess 210. In some embodiments, sail closure 212 is secured to outer hull 202 by, for example, welding. Those skilled in the art will readily appreciate that the exterior shell cooler 204 may be utilized in addition to or in lieu of the spine cooler 50 and keel cooler 90 described herein.

Referring now to FIG. 4, the ridge cooler 50 is part of a cooling system 58. Fig. 4 is a plan view of the hull 30, schematically illustrating the arrangement of the components of the vessel 10 therein. The cooling system 58 includes a spine cooler 50 at each side 60 of the hull 30. The first ridge cooler 50a is located at the first side 60a of the hull 30 and is connected to a first coolant circuit 62 a. The coolant flows from the first ridge cooler 50a through the outlet port 64 and through the coolant passage 66. Coolant flows through components arrayed along the coolant passage 66, such as an Accessory Power Module (APM)68, a Single Power Inverter Module (SPIM)70, an on-board charging module (OBCM)72, and the electric motor 14. The coolant cools the component by exchanging thermal energy therewith. The coolant then returns to the first ridge cooler 50a through the inlet port 74. In some embodiments, the coolant is forced along the coolant passages 66 by a coolant pump 76. In the embodiment of FIG. 4, the coolant pump 76 is located between the outlet port 64 and the components, but in other embodiments, the coolant pump 76 may be located elsewhere along the coolant passages 56.

The second ridge cooler 50b is located on a second side 60b of the hull 30 opposite the first side 60a, and is connected to a second coolant circuit 62 b. Coolant flows from the second ridge cooler 50b through the outlet port 64 and through the coolant channel 66. The coolant flows through components, such as one or more cells 24, arranged along the coolant channels 56. The coolant cools the one or more batteries 24 by exchanging thermal energy therewith. The coolant then returns to the second ridge cooler 50b through the inlet port 74. In some embodiments, the coolant is forced along the coolant passages 66 by a coolant pump 76. In the embodiment of FIG. 4, the coolant pump 76 is located between the outlet port 64 and the one or more batteries 24, but in other embodiments, the coolant pump 76 may be located elsewhere along the coolant passages 56. In some embodiments, the first coolant circuit 62a and the second coolant circuit 62b operate at different temperatures.

Although in the embodiment of fig. 4 the first coolant circuit 62a and the second coolant circuit 62b are isolated such that the coolant in the first coolant circuit 62a is not mixed with the coolant in the second coolant circuit 62b, in other embodiments as shown in fig. 5, the coolant from the first coolant circuit 62a may be directed through the second coolant circuit 62b, and vice versa. In such embodiments, the cooling system 58 includes one or more connecting coolant passages 78 that connect the first coolant circuit 62a to the second coolant circuit 62 b. In addition, one or more valves 80 are positioned along the connecting coolant passage 78 to selectively direct coolant along the passages of the cooling system 58. For example, under certain operating conditions, one or more batteries 24 may require additional cooling in addition to that provided by the coolant in the second coolant loop 62 b. In this case, the valve 80 may be selectively opened to direct additional coolant from the first coolant loop 62a through the connecting coolant channel 78 and through the second coolant loop 62b to provide additional cooling to the one or more batteries 24. When one or more of the cells 24 are sufficiently cooled and it is determined that additional cooling is no longer needed, the valve 80 may be closed. Furthermore, as shown in the embodiment of FIG. 6, the ridge coolers 50a, b and components may be arranged in a single coolant loop 62, with the ridge coolers 50a, b arranged in series. A single pump 76 may drive coolant through a single coolant loop 62.

The cooling system 58 disclosed herein provides a relatively low maintenance solution for cooling of onboard electrical components because the system is closed to the exterior of the hull and therefore does not require a yearly overwintering. Furthermore, the disclosed cooling system 58 is still operable when the vessel 10 is not in water, as the flow of coolant can readily exchange thermal energy with the outside air at the outer hull surface 34 via the ridge cooler 50. Furthermore, the cooling system 58 can be easily fitted to existing hulls 30 without requiring drilling holes in the hull 30 and without protruding from the hull outer surface 34, thus not altering the hydrodynamic performance of the hull 30. This solution also eliminates the need for a fresh water cooling pump, thus making the overall system more efficient and eliminating the need for large water coolant heat exchangers, which can save up to 100 pounds of weight from the vessel, thereby improving performance and efficiency.

While the foregoing disclosure has been described with reference to exemplary embodiments, it will be understood by those skilled in the art that various changes may be made and equivalents may be substituted for elements thereof without departing from the scope thereof. In addition, many modifications may be made to adapt a particular situation or material to the teachings of the disclosure without departing from the essential scope thereof. Therefore, it is intended that the disclosure not be limited to the particular embodiments disclosed, but that the disclosure will include all embodiments falling within its scope.