1. Field of the Invention
The present invention relates to a fuel supply system for a boat and an outboard motor. Specifically, the present invention relates to a fuel supply system for a boat having a second fuel tank connected to a first fuel tank mounted on a hull and an outboard motor.
2. Description of the Related Art
Conventionally, a fuel supply system for a boat having a second fuel tank connected to a first fuel tank mounted on a hull is known (see JP-A-2007-309182, for example). In JP-A-2007-309182, there is disclosed an outboard motor including a vapor separator (second fuel tank) for reserving fuel supplied from a fuel tank mounted on a hull; a low-pressure pump (fuel supply pump) for discharging the fuel reserved in the fuel tank to the vapor separator; and a relief path through which the fuel discharged by the low-pressure pump is returned to the suction side of the low-pressure pump when the vapor separator is filled with a predetermined amount of fuel. The relief path of the outboard motor according to JP-A-2007-309182 is configured to be connected to a plurality of fuel pipes at a location that is different from the location where the vapor separator is disposed.
However, in JP-A-2007-309182, since the relief path of the outboard motor is configured to be connected to the plurality of fuel pipes at a location that is different from the location where the vapor separator is disposed, fuel piping becomes complicated.
In view of the above problems, preferred embodiments of the present invention provide a fuel supply system for a boat and an outboard motor that prevent fuel piping from becoming complicated.
A fuel supply system for a boat according to a preferred embodiment of the present invention includes a second fuel tank connected to a first fuel tank that is mounted on a hull and contains fuel supplied to an engine, a fuel supply pump arranged to discharge the fuel reserved in the first fuel tank to the second fuel tank side, and a relief path through which the fuel discharged by the fuel supply pump is returned to the suction side of the fuel supply pump when the second fuel tank is filled with a predetermined amount of fuel, and the second fuel tank is integral with the relief path.
As described above, the relief path is preferably integral with the second fuel tank, which is different from the case where the relief path is configured to be connected to a plurality of piping members. This prevents the relief path from becoming complicated. Thus, fuel piping can be prevented from becoming complicated.
Preferably, the second fuel tank is also integral with a fuel supply path to connect the discharge side of the fuel supply pump and a tank section of the second fuel tank. With this configuration, because the fuel supply path is integral with the second fuel tank, the fuel supply path can be prevented from becoming complicated. Thus, the fuel piping including the relief path and the fuel supply path can further be prevented from becoming complicated.
In the fuel supply system for a boat in which the second fuel tank is integral with the fuel supply path, preferably, an inlet through which fuel flows into the tank section of the second fuel tank is provided in the tank section side of the fuel supply path integrally provided in the second fuel tank, and the fuel supply system further includes a closing member disposed in the tank section of the second fuel tank to close the inlet when the tank section of the second fuel tank is filled with the predetermined amount of fuel. With this configuration, it is easy with the closing member to prevent fuel from excessively flowing into the tank section of the second fuel tank.
In the fuel supply system for a boat in which the inlet is provided, preferably, the fuel supply path is also connected to the relief path, and the fuel supply system further includes a filter positioned in the fuel supply path as well as in the upstream side of the relief path and the upstream side of the inlet. With this configuration, a relief valve that is, for example, provided in the relief path can be protected from foreign matters contained in the fuel, and the closing member can be protected from foreign matters.
In this case, the filter is preferably arranged to cover the relief path and the inlet. With this configuration, it is possible with the filter to reliably protect the relief path and the inlet.
In the fuel supply system for a boat in which the second fuel tank is integral with the fuel supply path, preferably, the second fuel tank includes a tank body and a first cover member arranged to cover an upper portion of the tank body and the fuel supply path is integral with the first cover member of the second fuel tank. With this configuration, the fuel supply path can be formed simultaneously with the first cover member.
In the fuel supply system for a boat in which the second fuel tank is made up of the tank body and the first cover member, the relief path is preferably integral with the second fuel tank so as to lie astride the tank body and the first cover member. With this configuration, the relief path can be formed simultaneously with the tank body and the first cover member.
In the fuel supply system for a boat in which the second fuel tank is made up of the tank body and the first cover member, a suction opening of the fuel supply pump is preferably attached to the tank body of the second fuel tank so as to be connected to the relief path. With this configuration, no piping member such as a hose is required between the suction opening of the fuel supply pump and the tank body, thereby preventing fuel piping from becoming complicated.
In the fuel supply system for a boat in which the second fuel tank is made up of the tank body and the first cover member, a discharge opening of the fuel supply pump is preferably attached to the first cover member of the second fuel tank so as to be connected to the fuel supply path. With this configuration, no piping member such as a hose is required between the discharge opening of the fuel supply pump and the first cover member, thereby preventing fuel piping from becoming complicated.
Preferably, the fuel supply system for a boat according to a preferred embodiment of the present invention further includes a cooling section through which cooling water is flowed and that is located on an outer wall section of the second fuel tank and cools the second fuel tank. With this configuration, it is possible with the cooling section to cool the inside of the second fuel tank via the outer wall section of the second fuel tank.
The cooling section is preferably configured to cool the fuel flowed through the relief path and the fuel reserved in the tank section of the second fuel tank. With this configuration, it is possible to cool the fuel that is flowed through the relief path and returned to the suction side of the fuel supply pump and restrain the fuel reserved in the tank section from vaporizing.
In the fuel supply system for a boat provided with the cooling section, preferably, the cooling section includes a second cover member configured to cover the outer wall section of the second fuel tank and is configured such that cooling water flows between the second cover member and the outer wall section of the second fuel tank. With this configuration, since cooling water directly contacts the outer wall section of the second fuel tank, the inside of the second fuel tank can be effectively cooled.
In the fuel supply system for a boat according to a preferred embodiment of the present invention, the relief path is preferably configured to house the fuel supply pump. With this configuration, the relief path covers the fuel supply pump, thereby protecting the fuel supply pump from physical shock.
In the fuel supply system for a boat according to a preferred embodiment of the present invention, the relief path preferably includes a relief valve that is disposed in the vicinity of the suction opening of the fuel supply pump in the relief path and allows fuel to flow into the suction opening side of the fuel supply pump when the second fuel tank is filled with the predetermined amount of fuel. With this configuration, fuel can easily be returned to the suction opening side of the fuel supply pump when the second fuel tank is filled with the predetermined amount of fuel.
An outboard motor according to another preferred embodiment of the present invention includes an engine, a second fuel tank connected to a first fuel tank that is mounted on a hull and contains fuel supplied to the engine, a fuel supply pump arranged to discharge the fuel reserved in the first fuel tank to a second fuel tank side, and a relief path through which the fuel discharged by the fuel supply pump is returned to the suction side of the fuel supply pump when the second fuel tank is filled with a predetermined amount of fuel, and the second fuel tank is integral with the relief path.
As described above, the relief path is preferably integral with the second fuel tank, which is different from the case where the relief path is configured to be connected to a plurality of piping members. This prevents the relief path from becoming complicated. Thus, fuel piping can be prevented from becoming complicated.
Other features, elements, arrangements, steps, characteristics and advantages of the present invention will become more apparent from the following detailed description of preferred embodiments of the present invention with reference to the attached drawings.
Preferred embodiments of the present invention will be described in the following sections based on the drawings.
As shown in
As shown in
In the first preferred embodiment, as shown in
The vapor separator unit 8 includes a tank section 82 for reserving fuel supplied to the engine section 2. The tank section 82 is enclosed with the unit main body 80 and the cover member 81. As shown in
The low-pressure pump 12 includes a pump main body 12a that constitutes the main portion of the low-pressure pump 12, a suction opening section 12b for suctioning fuel, and a discharge opening section 12c for discharging the suctioned fuel. Note that the suction opening section 12b is an example of the “suction opening” according to a preferred embodiment of the present invention while the discharge opening section 12c is an example of the “discharge opening” according to a preferred embodiment of the present invention. As shown in
In the first preferred embodiment, as shown in
In the first preferred embodiment, a fuel passage section 81b is formed above the mounting hole 81a for discharge opening in the cover member 81 of the vapor separator unit 8. Note that the fuel passage section 81b is an example of the “fuel supply path” according to a preferred embodiment of the present invention. The fuel passage section 81b preferably includes a channel section 81c formed in an upper surface of the cover member 81 to extend horizontally (in “X” direction in
A pipe section 81e extending downward is provided in the other side of the channel section 81c of the fuel passage section 81b. Note that the pipe section 81e is an example of the “fuel supply path” and the “inlet” according to a preferred embodiment of the present invention. The pipe section 81e is preferably integral with the cover member 81 of the vapor separator unit 8 and connected to the other side of the channel section 81c. The lower end of the pipe section 81e is positioned inside the tank section 82 of the vapor separator unit 8. As described above, the fuel supply path preferably includes the mounting hole 81a for discharge opening, the fuel passage section 81b, and the pipe section 81e. The fuel discharged from the low-pressure pump 12 can be flowed into the inside of the tank section 82 via the fuel supply path.
In the first preferred embodiment, a float valve 84 is preferably disposed in the tank section 82. Note that the float valve 84 is an example of the “closing member” according to a preferred embodiment of the present invention. The float valve 84 preferably includes a needle valve 84a and a float section 84b. The needle valve 84a is positioned in the pipe section 81e and has a function to adjust a flow rate of the fuel flowed from the pipe section 81e into the tank section 82. The float section 84b is disposed in the tank section 82 so as to be floatable on the level of the fuel reserved in the tank section 82. The needle valve 84a and the float section 84b are connected by a lever member 84c. When the level of the fuel reserved in the tank section 82 drops below a predetermined level, the float section 84b is moved downward along with the level of the fuel and the lever member 84c is rotated about a rotation axis 84d in “A” direction. The needle valve is configured to be open as the lever member 84c rotates in “A” direction. In other words, when the level of the fuel reserved in the tank section 82 drops below the predetermined level, the float valve 84 is configured to operate such that the needle valve 84a is opened to allow fuel to flow into the tank section 82 from the pipe section 81e.
When the level of the fuel reserved in the tank section 82 exceeds the predetermined level, the float section 84b is moved upward along with the level of the fuel and the lever member 84c is rotated about the rotation axis 84d in “B” direction. The needle valve 84a is configured to be closed as the lever member 84c rotates in “B” direction. In other words, when the level of the fuel reserved in the tank section 82 exceeds the predetermined level, the float valve 84 is configured to operate such that the needle valve 84a is closed to reduce the flow rate of the fuel flowed into the tank section 82 from the pipe section 81e. Further, when the tank section 82 is filled with a predetermined amount of fuel, the float valve 84 is configured to operate such that the needle valve 84a is closed to close the pipe section 81e.
In the first preferred embodiment, as shown in
In this preferred embodiment, the lower portion of the mounting hole 81f for relief valve 85 is connected to the upper portion of a pipe section 80c. The pipe section 80c is preferably integral with the unit main body 80 of the vapor separator unit 8 to extend vertically. As shown
As configured as described above with the mounting hole 81f for relief valve 85, the pipe section 80c, and the fuel passage section 80b, it is possible to release fuel outward (to the suction side of the low-pressure pump 12) via the relief valve 85, the pipe section 80c, and the fuel passage section 80b when pressure applied to the fuel flowing through the fuel passage section 80b is larger than a predetermined value. In other words, when the needle valve 84a of the float valve 84 is closed due to the fact that the tank section 82 is filled with the predetermined amount of fuel, fuel is returned to the suction side of the low-pressure pump 12. Note that the mounting hole 81f for relief valve 85 and the pipe section 80c constitute the “relief path” according to a preferred embodiment of the present invention.
A filter 81g is disposed upstream of the mounting hole 81f for relief valve 85 of the fuel passage section 81b as well as upstream of the pipe section 81e. The filter 81g is arranged to cover the mounting hole 81f and the pipe section 81e. Since the filter 81g extends in “X” direction, it can filter out foreign matters over a wider area than the case where a filter is disposed only above the mounting hole 81f or only above the pipe section 81e. Thus, the life of the filter 81g can be extended.
As shown in
The discharge opening section 86c of the high-pressure pump 86 is connected to the lower end of a pipe section 81h. As shown in
A pressure regulator 87 is installed in the pipe section 81h. The pressure regulator 87 has a function to adjust the pressure (pressure in the pipe section 81h) of the fuel transported to the injector 21 in order to keep the injected amount of the fuel from the injector 21 at the constant level. As shown in
In the first preferred embodiment, a cooling section 88 for cooling the vapor separator unit 8 is provided on an outer wall section 8a (see
As shown in
In the first preferred embodiment, as described above, the relief path, which preferably includes the fuel passage section 80b, the pipe section 80c, and the mounting hole 81f, through which the fuel discharged by the low-pressure pump 12 is returned to the suction side of the low-pressure pump 12 is preferably integral with the vapor separator unit 8. Therefore, the relief path, which preferably includes the fuel passage section 80b, the pipe section 80c, and the mounting hole 81f, can be prevented from becoming complicated, in contrast to the case where the relief path is configured to be connected to a plurality of piping members. Thus, fuel piping can be prevented from becoming complicated.
In the first preferred embodiment, as described above, the fuel passage section 81b and pipe section 81e that connect between the discharge opening section 12c side of the low-pressure pump 12 and the tank section 82 of the vapor separator unit 8 preferably are integral with the vapor separator unit 8. As a result, the fuel passage section 81b and pipe section 81e are prevented from becoming complicated. Thus, the fuel piping including the relief path, which preferably includes the fuel passage section 80b, the pipe section 80c, and the mounting hole 81f, and the fuel supply path, which preferably includes the fuel passage section 81b and pipe section 81e, can be prevented from becoming complicated.
In the first preferred embodiment, as described above, the float valve 84 is provided in the tank section 82 of the vapor separator unit 8 to close the pipe section 81e (inlet) when the tank section 82 of the vapor separator unit 8 is filled with the predetermined amount of fuel. With the float valve 84, it is easy to prevent fuel from excessively flowing into the tank section 82 of the vapor separator unit 8.
In the first preferred embodiment, as described above, the filter 81g is disposed in the fuel passage section 81b upstream of the mounting hole 81f as well as upstream of the pipe section 81e, thereby protecting the relief valve 85 provided in the mounting hole 81f and the needle valve 84a provided in the pipe section 81e from foreign matters contained in the fuel.
In the first preferred embodiment, as described above, the filter 81g is preferably arranged to cover the mounting hole 81f and the pipe section 81e, thereby reliably protecting the mounting hole 81f and the pipe section 81e.
In the first preferred embodiment, as described above, the fuel passage section 81b and the pipe section 81e preferably are integral with the cover member 81 of the vapor separator unit 8. Accordingly, the fuel passage section 81b and the pipe section 81e can be formed simultaneously with the cover member 81.
In the first preferred embodiment, as described above, the fuel passage section 80b and the pipe section 80c preferably are integral with the vapor separator unit 8 so as to lie astride the unit main body 80 and the cover member 81. Accordingly, the fuel passage section 80b and the pipe section 80c can be formed simultaneously with the unit main body 80 and the cover member 81 of the vapor separator unit 8.
In the first preferred embodiment, as described above, the suction opening section 12b of the low-pressure pump 12 is attached to the unit main body 80 of the vapor separator unit 8 to be connected to the fuel passage section 80b and the pipe section 80c. Accordingly, no piping member such as a hose is required between the suction opening section 12b of the low-pressure pump 12 and the unit main body 80, thereby preventing fuel piping from becoming complicated.
In the first preferred embodiment, as described above, the discharge opening section 12c of the low-pressure pump 12 is attached to the cover member 81 of the vapor separator unit 8 to be connected to the fuel passage section 81b and the pipe section 81e. Accordingly, no piping member such as a hose is required between the discharge opening section 12c of the low-pressure pump 12 and the cover member 81, thereby preventing fuel piping from becoming complicated.
In the first preferred embodiment, as described above, the cooling section 88 configured to flow cooling water is provided on the outer wall section 8a of the vapor separator unit 8. With the cooling section 88, it is possible to cool the inside of the vapor separator unit 8 via the outer wall section 8a of the vapor separator unit 8.
In the first preferred embodiment, as described above, the cooling section 88 is configured to flow cooling water between the cover member 88a and the outer wall section 8a of the vapor separator unit 8. Thus, cooling water directly contacts the outer wall section 8a of the vapor separator unit 8, thereby effectively cooling the inside of the vapor separator unit 8.
In the first preferred embodiment, as described above, the cooling section 88 is configured to cool the fuel flowing through the pipe section 80c and the fuel reserved in the tank section 82. Therefore, the fuel flowing through the pipe section 80c to return to the suction opening section 12b side of the low-pressure pump 12 can be cooled and vaporization of the fuel reserved in the tank section 82 can be prevented.
In the second preferred embodiment, as shown in
In the second preferred embodiment, the vapor separator unit 208 includes a tank section 282 for reserving fuel supplied to the engine section 2 and the low-pressure pump housing section 289 configured to house the low-pressure pump 12. The tank section 282 and the low-pressure pump housing section 289 are respectively configured to be enclosed by the unit main body 280 and the cover member 281.
The suction opening section 12b of the low-pressure pump 12 is attached to the unit main body 280 of the vapor separator unit 208 while the discharge opening section 12c of the low-pressure pump 12 is attached to the cover member 281 of the vapor separator unit 208. Specifically, a mounting hole 280a for suction opening to which the suction opening section 12b of the low-pressure pump 12 is mounted is formed in the low-pressure pump housing section 289 of the unit main body 280 of the vapor separator unit 208. In the mounting hole 280a for suction opening, the suction opening section 12b of the low-pressure pump 12 is fitted via the seal member 13. Also, a mounting hole 281a for discharge opening to which the discharge opening section 12c of the low-pressure pump 12 is mounted is formed in the cover member 281 of the vapor separator unit 208. In the mounting hole 281a for discharge opening, the discharge opening section 12c of the low-pressure pump 12 is fitted via the seal member 14.
In the second preferred embodiment, a fuel passage section 280b is provided below the mounting hole 280a for suction opening in the unit main body 280 of the vapor separator unit 208. The fuel passage section 280b is arranged to extend horizontally and is provided with a pipe mounting member 15 that is inserted into one side of the fuel passage section 280b. An upper surface of the fuel passage section 280b is connected to the lower end of the mounting hole 280a for suction opening. Further, a fuel passage section 281b is located above the mounting hole 281a for discharge opening in the cover member 281 of the vapor separator unit 208. Note that the fuel passage section 281b is an example of the “fuel supply path” according to a preferred embodiment of the present invention. The fuel passage section 281b preferably includes a channel section 281c formed in an upper surface of the cover member 281 to extend horizontally and a metallic lid member 281d for covering the channel section 281c.
A pipe section 281e extending downward is provided in the other side of the channel section 281c of the fuel passage section 281b. Note that the pipe section 281e is an example of the “fuel supply path” and the “inlet” according to a preferred embodiment of the present invention.
In the second preferred embodiment, a mounting hole 281f is provided in the channel section 281c of the fuel passage section 281b to be sandwiched between the mounting hole 281a for suction opening and the pipe section 281e. The mounting hole 281f is configured to penetrate downward from the bottom of the channel section 281c. The relief valve 285 is mounted to the mounting hole 281f. The lower portion of the mounting hole 281f for relief valve 285 is connected to the upper portion of the low-pressure pump housing section 289. The low-pressure pump housing section 289 is configured to house the low-pressure pump 12. Specifically, the low-pressure pump housing section 289 is configured to house the pump main body 12a of the low-pressure pump 12.
In the second preferred embodiment, the low-pressure pump housing section 289 preferably is integral with the unit main body 280 of the vapor separator unit 208 so as to be positioned adjacent to the tank section 282. A pipe section 280c is connected to the lower portion of the low-pressure pump housing section 289 to extend downward. The pipe section 280c preferably is integral with the unit main body 280 of the vapor separator unit 208. The lower portion of the pipe section 280c is connected to the other side of the fuel passage section 280b. That is, the relief valve 285 is configured to be connected to the suction opening section 12b of the low-pressure pump 12.
As configured as described above with the mounting hole 281f for relief valve 285, the pipe section 280c, and the fuel passage section 280b, it is possible to release fuel outward (to the suction side of the low-pressure pump 12) via the relief valve 285, the pipe section 280c, and the fuel passage section 280b when pressure applied to the fuel flowing through the fuel passage section 280b is larger than a predetermined value. In other words, when the tank section 282 is filled with a predetermined amount of fuel, which causes the needle valve 84a of the float valve 84 to be closed, fuel is returned to the suction side of the low-pressure pump 12. Note that the mounting hole 281f, the low-pressure pump housing section 289, and the pipe section 280c constitute the “relief path” of the present invention. A filter 281g is disposed upstream of the mounting hole 281f for relief valve 285 of the fuel passage section 281b as well as upstream of the pipe section 281e.
Other constructions of the second preferred embodiment are preferably the same as those of the first preferred embodiment.
In the second preferred embodiment, as described above, the relief path (low-pressure pump housing section 289) in which fuel is released from the relief valve 285 is configured to house the low-pressure pump 12. Thus, the relief path (low-pressure pump housing section 289) covers the low-pressure pump 12, thereby protecting the fuel supply pump 12 from physical shock.
Other effects, operations and advantages of the second preferred embodiment are similar to those of the first preferred embodiment.
In the third preferred embodiment, as shown in
In the third preferred embodiment, the vapor separator unit 308 includes a tank section 382 for reserving fuel supplied to the engine section 2 and the low-pressure pump housing section 389 configured to house the low-pressure pump 12. The tank section 382 and the low-pressure pump housing section 389 are respectively configured to be enclosed by the unit main body 380 and the cover member 381.
The suction opening section 12b of the low-pressure pump 12 is attached to the unit main body 380 of the vapor separator unit 308 while the discharge opening section 12c of the low-pressure pump 12 is attached to the cover member 381 of the vapor separator unit 308. Specifically, a mounting hole 380a for suction opening to which the suction opening section 12b of the low-pressure pump 12 is mounted is formed in the low-pressure pump housing section 389 of the unit main body 380 of the vapor separator unit 308. In the mounting hole 380a for suction opening, the suction opening section 12b of the low-pressure pump 12 is fitted via the seal member 13. Also, a mounting hole 381a for discharge opening to which the discharge opening section 12c of the low-pressure pump 12 is mounted is formed in the cover member 381 of the vapor separator unit 308. In the mounting hole 381a for discharge opening, the discharge opening section 12c of the low-pressure pump 12 is fitted via the seal member 14.
In the third preferred embodiment, a fuel passage section 380b is formed below the mounting hole 380a for suction opening in the unit main body 380 of the vapor separator unit 308. The fuel passage section 380b is arranged to extend horizontally and is provided with the pipe mounting member 15 that is inserted into one side of the fuel passage section 380b. An upper surface of the fuel passage section 380b is connected to the lower end of the mounting hole 380a for suction opening. Further, a fuel passage section 381b is formed above the mounting hole 381a for discharge opening in the cover member 381 of the vapor separator unit 308. Note that the fuel passage section 381b is an example of the “fuel supply path” according to a preferred embodiment of the present invention. The fuel passage section 381b preferably includes a channel section 381c formed in an upper surface of the cover member 381 to extend horizontally and a metallic lid member 381d for covering the channel section 381c.
A pipe section 381e extending downward is provided in the other side of the channel section 381c of the fuel passage section 381b. Note that the pipe section 381e is an example of the “fuel supply path” and the “inlet” according to a preferred embodiment of the present invention.
In the third preferred embodiment, a pipe section 381f is provided in the channel section 381c of the fuel passage section 381b to be sandwiched between the mounting hole 381a for discharge opening and the pipe section 381e. The pipe section 381f is arranged to connect between the fuel passage section 381b and the low-pressure pump housing section 389. The low-pressure pump housing section 389 preferably is integral with the unit main body 380 of the vapor separator unit 308 to be positioned adjacent to the tank section 382. The low-pressure pump housing section 389 is configured to house the low-pressure pump 12. Specifically, the low-pressure pump housing section 389 is configured to house the pump main body 12a of the low-pressure pump 12.
In the third preferred embodiment, a mounting hole 380c for a valve is provided in the lower portion of the low-pressure pump housing section 389. The mounting hole 380c is configured to connect the lower portion of the low-pressure pump housing section 389 and the fuel passage section 380b. The relief valve 385 is mounted to the mounting hole 380c. That is, the relief valve 385 is configured to be connected to the suction opening section 12b of the low-pressure pump 12.
As configured as described above with the pipe section 381f, the low-pressure pump housing section 389, and the mounting hole 380c for relief valve 385, it is possible to release fuel outward (to the suction side of the low-pressure pump 12) via the low-pressure pump housing section 389 and the mounting hole 380c for relief valve 385 when pressure applied to the fuel flowing through the fuel passage section 381b is larger than a predetermined value. In other words, when the tank section 382 is filled with a predetermined amount of fuel, which causes the needle valve 84a of the float valve 84 to be closed, fuel is returned to the suction side of the low-pressure pump 12. Note that the pipe section 381f, the low-pressure pump housing section 389, and the mounting hole 380c constitute the “relief path” according to a preferred embodiment of the present invention. A filter 381g is disposed upstream of the mounting hole 381f for relief valve 385 of the fuel passage section 381b as well as upstream of the pipe section 381e. The filter 381g is configured to cover the mounting hole 381f and the pipe section 381e.
The other constructions of the third preferred embodiment are the same as those of the second preferred embodiment.
In the third preferred embodiment, as described above, the relief valve 385 is provided in the vicinity of the suction opening section 12b of the low-pressure pump 12 to flow fuel to the suction opening section 12b side of the low-pressure pump 12 when the tank section 382 is filled with the predetermined amount of fuel. Thus, when the tank section 382 is filled with the predetermined amount of fuel, it is easy to return fuel to the suction opening section 12b side of the low-pressure pump 12.
Other effects, operations and advantages of the third preferred embodiment are similar to those of the first and the second preferred embodiments.
Note that the preferred embodiments disclosed in this specification are merely examples in every aspect, and it is intended not to limit the scope of the present invention. The scope of this invention is not defined by the aforementioned description of the preferred embodiments, but by the claims. Also the scope of this invention includes every modification within the equivalent meaning and scope of the claims.
For example, in the first to third preferred embodiments, a relief valve is preferably provided in such a relief path as the fuel passage section. However, the present invention is not limited thereto. Any device such as a pressure regulator other than a relief valve may be applied in such a relief path as the fuel passage section.
In the first to third preferred embodiments, in order to cool the vapor separator unit, a cooling section configured to flow cooling water through the outer wall section of the vapor separator unit is preferably provided. However, the present invention is not limited thereto. For example, a cooling section configured to flow cooling water in the vapor separator unit or in a wall section of the vapor separator unit may be provided.
In the first to third preferred embodiments, a float valve is preferably applied to the closing member. However, the present invention is not limited thereto. For example, any valve member such as a solenoid valve other than a float valve may be applied to the closing member.
In the first to third preferred embodiments, the vapor separator unit is preferably formed by casting, for example. However, the present invention is not limited thereto. For example, the vapor separator unit may be formed by welding a plurality of metallic members or by molding resins, for example.
In the first to third preferred embodiments, gasoline is preferably used for fuel, for example. However, the present invention is not limited thereto. Fuel may be alcohol or other suitable fuel alternative.
In the first to third preferred embodiments, the fuel supply system for a boat of the present invention is preferably applied to an outboard motor. However, the present invention is not limited thereto. The fuel supply system for a boat according to a preferred embodiment of the present invention may be applied to an inboard motor or an inboard/outboard motor in which an engine section is mounted on a hull.
While preferred embodiments of the present invention have been described above, it is to be understood that variations and modifications will be apparent to those skilled in the art without departing the scope and spirit of the present invention. The scope of the present invention, therefore, is to be determined solely by the following claims.
Number | Date | Country | Kind |
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2008-166091 | Jun 2008 | JP | national |