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 fuel supply pump and an outboard motor. The fuel supply pump supplies the fuel reserved in a second fuel tank connected to a first fuel tank mounted on a hull to a fuel injection device.
2. Description of the Related Art
Conventionally, a fuel supply system for a boat having a fuel supply pump that supplies the fuel reserved in a second fuel tank connected to a first fuel tank mounted on a hull to a fuel injection device is known (see JP-A-2001-152896, for example).
The fuel supply system for a boat described in JP-A-2001-152896 is a fuel supply system for a boat employed for an outboard motor. In JP-A-2001-152896, fuel pumped from a fuel tank (first fuel tank) mounted on a hull is reserved in a vapor separator tank (second fuel tank). The fuel reserved in the vapor separator tank is supplied to a fuel injection device by a fuel supply pump. Also, in JP-A-2001-152896, there is provided a so-called in-tank fuel supply pump that is disposed in the vapor separator tank.
In general, a fuel supply pump generates negative pressure to draw fuel therein. However, when negative pressure is generated in order to draw fuel, the fuel may boil under reduced pressure due to the negative pressure. In this case, the fuel becomes vapor, generating bubbles in the fuel supply pump. If bubbles occur in the fuel supply pump, normal fuel transportation will be hampered. Thus, if vapor exists in the fuel supply pump during engine starting, it is difficult to properly transport fuel to a fuel injection device due to the vapor in the fuel supply pump. Therefore, it is necessary to discharge vapor from the fuel supply pump. Accordingly, it takes time to discharge the vapor from the fuel supply pump during engine starting, resulting in deterioration in engine startability.
In view of the above, preferred embodiments of the present invention provide a fuel supply system for a boat and an outboard motor that minimize and prevent deterioration in engine startability.
A fuel supply system for a boat according to a first preferred embodiment of the present invention includes: a second fuel tank that is connected to a first fuel tank mounted on a hull and arranged to reserve fuel to keep an inner fuel level at a predetermined height; a fuel injection device arranged to supply fuel to an engine; and a fuel supply pump that is disposed outside the second fuel tank and that is arranged to supply the fuel reserved in the second fuel tank to the fuel injection device. The fuel supply pump includes a negative pressure generating portion therein arranged to generate negative pressure when the fuel supply pump draws fuel, the negative pressure generating portion being positioned generally at a same level as or lower than the fuel level in the second fuel tank.
In the fuel supply system for a boat according to the first preferred embodiment, as described above, the fuel supply pump is preferably configured such that the negative pressure generating portion arranged to generate negative pressure when the fuel supply pump draws fuel is positioned generally at a same level as or lower than the fuel level in the second fuel tank. Accordingly, fuel can be drawn into the fuel supply pump with a small negative pressure. That is, when the negative pressure generating portion is positioned higher than the fuel level in the second fuel tank, a large negative pressure is required to draw fuel from the second fuel tank into the fuel supply pump because the fuel needs to be lifted up to a position higher than the fuel level in the second fuel tank. In contrast, when the negative pressure generating portion is positioned generally at a same level as or lower than the fuel level in the second fuel tank, fuel can be drawn into the fuel supply pump with a small negative pressure because no force is required to move the fuel to the negative pressure generating portion. Thus, negative pressure applied to the fuel can be minimized, thereby preventing the fuel in the fuel supply pump from vaporizing due to boiling under reduced pressure caused by an increase of the negative pressure while drawing the fuel. As a result, deterioration in engine startability can be prevented.
The fuel supply system for a boat according to the first preferred embodiment further includes a pipe arranged to connect the fuel supply pump and the second fuel tank, and the negative pressure generating portion of the fuel supply pump is positioned generally at a same level as or lower than a suction opening of the pipe inserted into the second fuel tank.
In the fuel supply system for a boat according to the first preferred embodiment, preferably, the fuel supply pump includes: a fuel path; a first check valve that is provided in the fuel path and that allows the fuel to move from the second fuel tank to the fuel injection device to pass therethrough; a second check valve that is provided closer to the fuel injection device relative to the first check valve in the fuel path and that allows the fuel to move from the second fuel tank to the fuel injection device to pass therethrough; a reserve section that is provided between the first check valve and the second check valve and that reserves fuel; and a negative pressure generating mechanism that causes the negative pressure generating portion to generate negative pressure when the fuel supply pump draws fuel into the reserving section, and the negative pressure generating portion includes a vicinity of the first check valve. With this configuration, the negative pressure generating mechanism causes the negative pressure generating portion to generate negative pressure to draw fuel into the reserve section via the first check valve. In this regard, since the negative pressure generating portion in the vicinity of the first check valve is positioned generally at a same level as to or lower than the fuel level in the second fuel tank, no force (large negative pressure) is required to move fuel to the negative pressure generating portion. Therefore, fuel can be drawn into the fuel supply pump with a small negative pressure. This prevents the fuel in the fuel supply pump from vaporizing due to boiling under reduced pressure caused by an increase of the negative pressure while drawing the fuel.
In the fuel supply system for a boat according to the first preferred, the fuel supply pump is preferably disposed on the side of and adjacent to the second fuel tank. With this configuration, the pipe arranged to connect the second fuel tank and the fuel supply pump can be shortened, thereby decreasing a heat receiving area that receives radiated heat from the engine. This prevents an increase in the fuel temperature in the pipe arranged to connect the second fuel tank and the fuel supply pump, and thereby prevents generation of vapor in the fuel supply pump caused by an increase in the fuel temperature which is a factor of the generation of vapor.
In this case, the fuel supply pump is preferably fixed to the second fuel pump while being spaced apart from the engine. With this configuration, since the fuel supply pump is not directly supported by the heated engine, a temperature rise of the fuel supply pump caused by heat directly transmitted from the engine can be prevented, differing from the case where the fuel supply pump is supported by the engine via supporting members. This also prevents generation of vapor in the fuel supply pump.
In the configuration in which the fuel supply pump is fixed to the second fuel tank, the second fuel tank and the fuel supply pump are preferably disposed adjacent to a throttle body including a throttle valve arranged to adjust a flow rate of air suctioned by the engine. With this configuration, the second fuel tank and the fuel supply pump that receive radiated heat from the engine are cooled by the throttle body in relatively low temperature. More specifically, since air flows fastest in the throttle body, heat is rapidly absorbed by the air flowing fast or by vaporization of the injected fuel. As a result, the throttle body becomes resistant to temperature increases. The second fuel tank and the fuel supply pump that receive radiated heat from the engine can be cooled by arranging the throttle body in relatively low temperature adjacent to the second fuel tank and the fuel supply pump. Thus, temperature increase in the second fuel tank and the fuel supply pump can be prevented, thereby preventing generation of vapor (vaporized fuel) in the second fuel tank and the fuel supply pump.
In this case, the fuel injection device is preferably configured to be positioned adjacent to the throttle body and inject fuel in the throttle body. With this configuration, all of the fuel supply pump, the second fuel tank, and the fuel injection device can be disposed adjacent to the vicinity of the throttle body. This allows the fuel system to be arranged within a small space, thereby shortening pipes that connect the second fuel tank, the fuel supply pump, and the fuel injection device with each other. This decreases a heat-receiving area that receives radiated heat from the engine, thereby suppressing generation of vaporized fuel. Also, since the fuel system is disposed within a small space, the fuel supply system for a boat can be made compact.
In the fuel supply system for a boat according to the first preferred embodiment, preferably, the fuel supply pump further includes a pressure adjusting device arranged to release fuel when the pressure of the fuel supplied to the fuel injection device is equal to or larger than a predetermined value. With this configuration, the pressure adjusting device installed in the fuel supply pump can release fuel in such a case that the injection device is plugged. This prevents the fuel injection device and the fuel supply pump from being damaged by the excessive fuel pressure.
In this case, preferably, the second fuel tank includes a vapor separator tank arranged to separate a vaporized fuel from a liquid fuel, and the pressure adjusting device is configured to return fuel to the vapor separator tank when the pressure applied to the fuel supplied to the injection device is equal to or larger than the predetermined value. With this configuration, even when the fuel temperature increases to generate vapor in the fuel supply pump, it is possible to return the vapor to the second fuel tank and separate the vapor from the liquid fuel. This prevents vaporized fuel from collecting in the fuel supply pump, and thus it is possible to prevent fuel supply failure to the fuel injection device that is caused by the collected vapor in the fuel supply pump.
In the fuel supply system for a boat according to the first preferred embodiment, the fuel supply pump preferably includes a pump main portion having the fuel path and a pump driving section separated from the fuel path of the pump main portion. With this configuration, even when the pump driving section generates heat, an increase in the fuel temperature due to the generated heat in the pump driving section can be prevented. Accordingly, generation of vapor (vaporized fuel) in the fuel supply pump can be prevented.
In this case, the pump driving section is preferably configured to drive the pump main portion with a driving force of the engine. With this configuration, an extra driving source such as a motor is not required to drive the pump main portion as the pump driving section.
In the configuration in which the pump main portion through which fuel passes is driven by the pump driving section through which fuel does not pass, the pump driving section is preferably configured to drive the pump main portion with a driving force of a motor separated from the fuel path of the pump main portion. With this configuration, an increase in the fuel temperature caused by the heated motor can be prevented even when the motor is utilized to drive the pump main portion. Accordingly, generation of vapor (vaporized fuel) in the fuel supply pump can be prevented.
An outboard motor according to a second preferred embodiment of the present invention includes: an engine; a second fuel tank that is connected to a first fuel tank mounted on a hull and arranged to reserve fuel to keep an inner fuel level at a predetermined height; a fuel injection device arranged to supply fuel to the engine; and a fuel supply pump that is disposed outside the second fuel tank and that is arranged to supply the fuel reserved in the second fuel tank to the fuel injection device. The fuel supply pump preferably includes a negative pressure generating portion that generates negative pressure when the fuel supply pump draws fuel, the negative pressure generating portion being positioned generally at a same level as or lower than the fuel level in the second fuel tank.
In the outboard motor according to the second preferred embodiment, as described above, the fuel supply pump is preferably configured such that the negative pressure generating portion arranged to generate negative pressure when the fuel supply pump draws fuel is positioned generally at a same level as or lower than the fuel level in the second fuel tank. Accordingly, fuel can be drawn into the fuel supply pump with a small negative pressure. That is, when the negative pressure generating portion is positioned higher than the fuel level in the second fuel tank, a large negative pressure is required to draw fuel from the second fuel tank into the fuel supply pump because the fuel needs to be lifted up to a position higher than the fuel level in the second fuel tank. In contrast, when the negative pressure generating portion is positioned generally at a same level as or lower than the fuel level in the second fuel tank, fuel can be drawn into the fuel supply pump with a small negative pressure because no force is required to move the fuel to the negative pressure generating portion. Thus, negative pressure applied to the fuel can be minimized, thereby preventing the fuel in the fuel supply pump from becoming vapor due to boiling under reduced pressure caused by an increase of the negative pressure while drawing the fuel. As a result, deterioration in engine startability can be prevented.
Other features, elements, 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.
Now, preferred embodiments of the present invention will be described in the following sections based on the drawings.
As shown in
As shown in
As shown in
As shown in
As shown in
As shown in
As shown in
The fuel sent out by the low-pressure fuel pump 43 is discharged from an outlet 45a (see
The vapor separator tank 45 holds the fuel pumped up from the fuel tank 102 and separates the vaporized fuel (vapor) or air from the liquid fuel. As shown in
At the bottom of the vapor separator tank 45, there is provided a water sensor 45e to detect water collected at the bottom of the vapor separator tank 45. Specifically, a central portion 45f of the bottom of the vapor separator tank 45 is protruded upward. The protruded portion defines a recess as seen from the outside below the vapor separator tank 45. Two leads 451, 452 are disposed in the recess, and tips of the leads 451, 452 are connected to each other. Also, a pair of floats 45g that are floatable in water are provided at the bottom of the vapor separator tank 45. Each of the paired floats 45g has a built-in magnet (not shown). When water is collected at the bottom of the vapor separator tank 45, the float 45g having a magnet ascends as a water level “Q” ascends. When the floats 45g ascend up to a predetermined position, the tip of the lead 451 and the tip of the lead 452 are separated from each other by magnetic force of the magnets. Accordingly, the connection between the leads 451, 452 is broken. With the water sensor 45e configured as above, it is possible to detect whether or not water is collected in an equal or greater quantity than a predetermined quantity at the bottom of the vapor separator tank 45.
A leading end 46h of a pipe 46f is inserted in an upper portion of the vapor separator tank 45. The pipe 46f is connected to the high-pressure fuel pump 46, which will be described later. The fuel returned from the high-pressure fuel pump 46 is discharged from the leading end 46h of the pipe 46f into the vapor separator tank 45. A buffer plate 45h is disposed below the leading end 46h of the pipe 46f and above the float 45c in the vapor separator tank 45. A plurality of small holes are provided in the buffer plate 45h. Fuel that is discharged from the leading end 46h of the pipe 46f is reserved again in the vapor separator tank 45 via the holes of the buffer plate 45h. When the fuel discharged from the leading end 46h of the pipe 46f bubbles, the buffer plate 45h can drip the liquid fuel into the vapor separator tank 45 without dropping bubbles.
The vapor separator tank 45 and the throttle body 32 are connected via a check valve 45i. The check valve 45i is configured to pass vapor (vaporized fuel) or air only in one direction from the vapor separator tank 45 to the throttle body 32. When vapor occurs, and thus internal pressure of the vapor separator tank 45 increase, the check valve 45i is opened by the pressure to discharge the vapor from the vapor separator tank 45 to the throttle body 32. Also, when the engine (engine section 2) is operated, the negative pressure in the throttle body 32 opens the check valve 45i to discharge the vapor from the vapor separator tank 45 to the throttle body 32.
As shown in
As shown in
An upper end of the plunger 463 abuts on a lower surface of the swash plate 462. As the swash plate 462 rotates with the rotary shaft 46c, the plunger 463 reciprocates in a vertical direction. When the plunger 463 moves upward, fuel is drawn from the vapor separator tank 45 into the reserving chamber 465 via the inlet 461 and the filter 464. When the plunger 463 moves downward, fuel is pushed out from the reserving chamber 465 to the reserving chamber 467. There are provided a lead valve 465a and a lead valve 465b respectively between the filter 464 and the reserving chamber 465 and between the reserving chamber 465 and the reserving chamber 467. These valves open when fuel flows in a transport direction (direction from the inlet 461 to the outlet 469) and close when fuel attempts to flow in the opposite direction. Note that the lead valves 465a and 465b are an example of the “first check valve” and the “second check valve” according to a preferred embodiment of the present invention. When fuel is drawn from the filter 464 into the reserving chamber 465, the lead valve 465a opens and the lead valve 465b closes at the same time as the plunger 463 moves upward. When fuel is pushed out from the reserving chamber 465 to the reserving chamber 467, the lead valve 465a closes and the lead valve 465b opens at the same time as the plunger 463 moves downward.
Also, when fuel is drawn from the filter 464 into the reserving chamber 465, the plunger 463 moves upward to generate negative pressure in a negative pressure generating portion 46i in the vicinity (between the filter 464 and the reserving chamber 467) of the lead valve 465a. The negative pressure generating portion 46i is positioned at a height “R.” In this preferred embodiment, as shown in
As shown in
In this preferred embodiment, as described above, the high-pressure fuel pump 46 is configured such that the negative pressure generating portion 46i that generates negative pressure as a suction force when the high-pressure fuel pump 46 draws fuel is positioned lower than the fuel level “P” in the vapor separator tank 45. This makes it possible to draw fuel into the high-pressure fuel pump 46 with a small negative pressure. That is, when the negative pressure generating portion 46i is positioned higher than the fuel level “P” in the vapor separator tank 45, a large negative pressure is required to draw fuel from the vapor separator tank 45 into the high-pressure fuel pump 46 because the fuel needs to be lifted up to a position higher than the fuel level “P” in the vapor separator tank 45. In contrast, when the negative pressure generating portion 46i is positioned lower than the fuel level “P” in the vapor separator tank 45, fuel can be drawn into the high-pressure fuel pump 46 with a small negative pressure because no force is required to move the fuel to the negative pressure generating portion 46i. Thus, negative pressure applied on the fuel can be reduced, thereby preventing the fuel in the high-pressure fuel pump 46 from vaporizing due to boiling under reduced pressure caused by an increase of the negative pressure while drawing the fuel. As a result, deterioration in the startability of the engine section 2 can be prevented.
In this preferred embodiment, as described above, the high-pressure fuel pump 46 is preferably disposed outside the vapor separator tank 45. Accordingly, the high-pressure fuel pump 46 can be easily arranged such that the negative pressure generating portion 46i is positioned lower than the fuel level “P.”
In this preferred embodiment, as described above, the high-pressure fuel pump 46 is preferably disposed on the side of and adjacent to the vapor separator tank 45. Therefore, the pipe 46f for connecting the high-pressure fuel pump 46 and the vapor separator tank 45 can be shortened, thereby decreasing a heat-receiving area that receives radiated heat from the engine 20. This prevents an increase in the fuel temperature in the pipe 46f for connecting the high-pressure fuel pump 46 and the vapor separator tank 45, and thereby prevents generation of vapor in the high-pressure fuel pump 46 caused by an increase in the fuel temperature which is a factor of the generation of vapor.
In this preferred embodiment, as described above, the high-pressure fuel pump 46 is fixed to the vapor separator tank 45, and is not directly supported by the high-temperature engine 20. Therefore, differing from the case where the high-pressure fuel pump 46 is supported by the engine 20 via supporting members, it is possible to prevent an increase in the temperature of the high-pressure fuel pump 46 caused by heat directly transmitted from the engine 20 via the supporting members.
In this preferred embodiment, as described above, the vapor separator tank 45 and the high-pressure fuel pump 46 preferably are disposed adjacent to the throttle body 32. Accordingly, the vapor separator tank 45 and the high-pressure fuel pump 46 that receives radiated heat from the engine 20 can be cooled by the throttle body 32 in relatively low temperature. More specifically, since air flows fastest in the throttle body 32, heat is rapidly absorbed by the air flowing fast or by vaporization of the injected fuel. As a result, the throttle body 32 becomes resistant to temperature increases. Being disposed adjacent to the throttle body 32 in relatively low temperature, the vapor separator tank 45 and the high-pressure fuel pump 46 that receives radiated heat from the engine 20 can be cooled by the throttle body 32 in relatively low temperature. Thus, the temperature increase in the vapor separator tank 45 and the high-pressure fuel pump 46 can be prevented, thereby preventing generation of vapor (vaporized fuel) in the vapor separator tank 45 and the high-pressure fuel pump 46.
In this preferred embodiment, as described above, the injector 47 is preferably configured to be disposed adjacent to the throttle body 32 and inject fuel in the throttle body 32. Thus, each of the vapor separator tank 45, the high-pressure fuel pump 46, and the injector 47 can be disposed in the vicinity of the throttle body 32. Since the fuel system 40 is thus disposed within a small space, the pipes 46e, 46f, 46g arranged to connect the vapor separator tank 45, the high-pressure fuel pump 46, and the injector 47 can be shortened. This decreases a heat-receiving area that receives radiated heat from the engine 20, thereby preventing generation of vaporized fuel. Since the fuel system 40 is disposed within a small space, the outboard motor 1 can be made compact.
In this preferred embodiment, as described above, the relief valve 468 is provided in the high-pressure fuel pump 46. Therefore, in such a case that the injector 47 is plugged with fuel, fuel can be discharged via the relief valve 468 contained in the high-pressure fuel pump 46. This prevents the injector 47 and the high-pressure fuel pump 46 from being damaged by the excessive fuel pressure.
In this preferred embodiment, as described above, when the pressure of the fuel supplied to the injector 47 becomes equal to or larger than the predetermined value, the fuel is returned to the vapor separator tank 45 via the relief valve 468 and the pipe 46f. Accordingly, when the fuel temperature rises and vapor occurs in the pump main portion 46a, the vapor is returned to the vapor separator tank 45 where the vapor and the liquid fuel can be separated. This prevents vapor from collecting in the pump main portion 46a of the high-pressure fuel pump 46, thereby preventing uncontrolled fuel supply to the injector 47 that is caused from the collected vapor in the pump main portion 46a.
In this preferred embodiment, as described above, the pump main portion 46a having a fuel path is preferably driven by the pulley 46d separated from the fuel path. Thus, differing from the case where the high-pressure fuel pump 46 is driven by a motor through which fuel passes, the high-pressure fuel pump 46 can be prevented from generating heat. This prevents an increase in the fuel temperature in the high-pressure fuel pump 46. Accordingly, generation of vapor (vaporized fuel) in the high-pressure fuel pump 46 can be prevented.
In this preferred embodiment, as described above, the pump main portion 46a is preferably driven by the driving force of the engine 20 using the rotary shaft 46c and the pulley 46d without providing an extra driving source such as a motor to drive the pump main portion 46a.
Note that the above preferred embodiment is only an example in every aspect, and it should not be considered to limit the present invention. The scope of this invention is not defined by the aforementioned description of the above preferred embodiment, 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 above preferred embodiment, the high-pressure fuel pump 46 preferably transports fuel by driving the plunger 463 with the swash plate 462. However, the present invention is not limited thereto. Other types of the high-pressure fuel pump such as a vane-type pump, a screw-type pump, or a trochoid-type pump may be used. In the case where such a fuel pump as mentioned above is employed, the high-pressure fuel pump can also be configured in such a manner that a negative pressure generating portion in the high-pressure pump is positioned generally at a same level as or lower than the fuel level “P” in a vapor separator tank. Further, if there are provided a plurality of negative pressure generating portions in the high-pressure fuel pump, all the plurality of negative pressure generating portions are preferably positioned generally at a same level as or lower than the fuel level “P” in a vapor separator tank. For example, a vane-type high-pressure fuel pump 300 according to a first variation as shown in
In the above preferred embodiment, the high-pressure fuel pump 46 is preferably configured in such a manner that the negative pressure generating portion 46i is positioned lower than the fuel level “P” in the vapor separator tank 45. However, the present invention is not limited thereto. When the negative pressure generated in the negative pressure generating portion 46i is small, the negative pressure generating portion 46i may be positioned generally at a same level as the fuel level “P” in the vapor separator tank 45.
In the above preferred embodiment, the pulley 46d fixed to the rotary shaft 46c of the high-pressure fuel pump 46 preferably is meshed with the belt 26 for driving the camshaft 27 to drive the high-pressure fuel pump 46 using the driving force of the engine 20. However, the present invention is not limited to thereto. As in a high-pressure fuel pump 400 according to a second variation shown in
In the above preferred embodiment, the rotary shaft 46c of the high-pressure fuel pump 46 preferably is rotated by the pulley 46d and the belt 26. However, the present invention is not limited thereto. The rotary shaft 46c maybe rotated by transmitting rotation of the camshaft 27 to the rotary shaft 46c of the high-pressure fuel pump 46 by using a gear and the like.
In the above preferred embodiment, gasoline is preferably used for fuel. However, the present invention is not limited thereto. Fuel may be alcohol, for example.
In the above preferred embodiment, the fuel supply system for a boat of the present invention is preferably applied to the outboard motor 1. However, the present invention is not limited thereto. The fuel supply system for a boat of the present invention may be applied to an inboard motor in which an engine section is mounted on a hull or to an inboard/outboard motor (stern drive).
In the above preferred embodiment, the present invention is preferably applied to the outboard motor 1 that utilizes the two-cylinder engine section 2 with the two cylinders 21. However, the present invention is not limited thereto. The present invention may be applied to an outboard motor utilizes an engine section with one cylinder or more than two cylinders. For example, a three-cylinder engine section 2a according to a third variation shown in
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 |
---|---|---|---|
2008-142622 | May 2008 | JP | national |
Number | Name | Date | Kind |
---|---|---|---|
4794889 | Hensel | Jan 1989 | A |
4809666 | Baltz | Mar 1989 | A |
4848283 | Garms et al. | Jul 1989 | A |
4876993 | Slattery | Oct 1989 | A |
4887559 | Hensel et al. | Dec 1989 | A |
5103793 | Riese et al. | Apr 1992 | A |
5309885 | Rawlings et al. | May 1994 | A |
5555858 | Katoh | Sep 1996 | A |
5579740 | Cotton et al. | Dec 1996 | A |
5647331 | Swanson | Jul 1997 | A |
6095774 | Tanaka et al. | Aug 2000 | A |
20010001955 | Kanno | May 2001 | A1 |
Number | Date | Country |
---|---|---|
2001-152896 | Jun 2001 | JP |
Number | Date | Country | |
---|---|---|---|
20090293843 A1 | Dec 2009 | US |