JP5249011B2 - Vehicle fuel tank - Google Patents

Description

  The present invention relates to a vehicle fuel tank.

In a vehicle fuel tank equipped with a fuel pump, when the fuel remaining in the fuel tank is small, the fuel moves due to acceleration, deceleration, etc. of the vehicle, and if the fuel is biased to a part of the fuel tank, the fuel pump There is a possibility that the fuel near the suction port will be reduced, resulting in insufficient fuel supply. In order to prevent such a shortage of fuel supply due to the movement of fuel, in Patent Document 1, a fuel pump is attached to the bottom of the fuel tank, and a fuel reservoir in which a lower end suction portion of the fuel pump is opened is provided to restrict the movement of the fuel. A configuration is disclosed in which a fuel extraction pipe is provided on the stepped wall, and the fuel reservoir and the fuel extraction pipe are connected by an external pipe.
JP 2003-214274 A

  Here, an object of the present invention is to provide a vehicle fuel tank that can prevent a shortage of fuel supply during acceleration / deceleration of the vehicle when the remaining amount of fuel is small.

1st invention of this application is a fuel tank for vehicles, Comprising: It is provided in the lower part of the bottom of the main-body part of the said fuel tank. A recess in which a suction port of a fuel pump for supplying fuel is located, a partition wall standing on the bottom and surrounding the upper surface opening of the recess from the other in the front-rear direction and opening toward the front-rear direction; and And a first partition plate that covers a portion of the upper surface opening of the concave portion on the one side in the front-rear direction from above.

  According to the above configuration, when an inertial force is generated in the vehicle in the front-rear direction, the movement of the fuel coming out of the recess to the other space located in the other front-rear direction is restricted by the partition wall, and the fuel is placed in the recess. It is easy to stay and the fuel coming out of the recess is easy to return. Further, the movement of the fuel coming out of the recess to one space located in one of the front and rear directions is restricted by the first partition plate, so that the fuel stays in the recess. Therefore, even when the vehicle has little fuel in the fuel tank and the vehicle is accelerated or decelerated, the fuel can be easily retained around the suction port of the fuel pump, and insufficient fuel supply due to acceleration or deceleration can be prevented. In the present invention, the partition wall may be configured to surround the upper surface opening of the recess in the horizontal cross section, and the upper side may be opened.

The first invention of the present application preferably further comprises the following configuration.
(1) The partition wall is provided with a ceiling wall that covers the partition wall from above.
(2) Each of the partition walls is provided with a notch in the upper part of the opening on the left and right side surfaces.
(3) a second partition plate that partitions one space located on one side in the front-rear direction of the main body of the fuel tank into an upper portion and a lower portion;
A third partition plate that divides the other space of the main body of the fuel tank located on the other side in the front-rear direction with respect to the concave portion into an upper portion and a lower portion.
(4) The second partition plate and the third partition plate are provided so as to be directed downward toward the concave portion in the horizontal or front-rear direction.
(5) The 2nd partition plate and the 3rd partition plate have a crevice between fuel tank wall surfaces, or have a hole penetrated up and down.
(6) A filter housing space for housing a suction filter for removing impurities in the fuel is formed in the middle of the suction pipe that connects the fuel pump suction port and the fuel pump.
(7) A fuel tank for a motorcycle, wherein the recess is disposed at a rear position of the main frame of the motorcycle and at an upper position of the swing arm.

  According to the configuration (1), since the ceiling wall is provided on the partition wall, the fuel whose movement is restricted by the partition wall can be prevented from coming out from the upper part of the partition wall by colliding with the ceiling wall.

  According to the configuration (2), the left and right side surfaces of the partition wall are notched. Here, when the fuel moves during acceleration / deceleration of the vehicle, the liquid level of the fuel rarely reaches the upper end of the opening on the left and right side surfaces of the partition wall. Therefore, by cutting out the upper portions of the openings on the left and right side surfaces, it is possible to suppress a reduction in the regulation performance of the partition wall, which restricts the movement of fuel, and to achieve a weight reduction of the partition wall. And weight reduction of a fuel tank can be achieved by weight reduction of a partition wall. In addition, notching the opening side upper part of the left-right side surface of a partition wall means that the height of the opening side of the left-right side surface of a partition wall becomes lower than the height of the edge part on the opposite side to an opening side.

  According to the configuration (3), the movement of the fuel in the fuel tank from the lower part of the one space to the upper part is regulated by the second partition plate, and the fuel in the fuel tank is moved from the lower part of the other space. The movement to the upper part is restricted by the third partition plate. As a result, the fuel easily returns to the recess.

  According to the configuration (4), the second partition plate and the third partition plate are provided horizontally or downward. Therefore, when the inertial force in one direction in the front-rear direction is applied, the second partition plate regulates the fuel exceeding the second partition plate while restricting the movement of the fuel from the lower part to the upper part of the one space of the fuel tank. Can be easily sent to the recess using the upper surface of the second partition plate. Further, when the inertial force in the other side in the front-rear direction is applied, the third partition plate regulates the fuel exceeding the third partition plate while restricting the movement of the fuel from the lower portion of the other space to the upper portion of the fuel tank. Can be easily sent to the recess using the upper surface of the third partition plate.

  According to said structure (5), the 2nd partition plate and the 3rd partition plate have a clearance gap between the inner walls of a fuel tank, or have the hole penetrated up and down. As a result, part of the fuel exceeding the second partition plate and the third partition plate flows into the recess through the gap, or flows into the recess through the hole, and the second partition plate and the second partition plate The fuel exceeding the three partition plates can be promptly sent to the recess.

  According to the configuration (6), the filter housing space for housing the suction filter is formed in the middle of the suction pipe. As a result, the suction port located at the lower end of the suction pipe of the fuel pump can be positioned below the recess rather than the suction filter, preventing the fuel supply from becoming insufficient even if a small amount of fuel remains. it can.

  According to said structure (7), the recessed part is arrange | positioned in the space formed with the main frame and swing arm of a motorcycle. Therefore, the concave portion can be arranged in an empty space, and the concave portion can be arranged at the lowermost part of the fuel tank.

  According to a second aspect of the present invention, there is provided a fuel tank for a motorcycle, which is provided at a bottom portion of a main body portion of the fuel tank, in which fuel in the fuel tank is sucked into the fuel supply portion of the engine. And a first partition plate that covers a portion of one side in the front-rear direction of the upper surface opening of the recess from above, and the recess includes the motorcycle. It is characterized by being arranged at the rear position of the main frame and at the upper position of the swing arm.

  According to the above configuration, the recess is disposed in a space formed by the main frame and the swing arm of the motorcycle, and the first partition plate covers a part of the upper surface opening of the recess. As a result, the concave portion can be disposed in an empty space between the main frame and the swing arm, and the concave portion can be disposed at the lowermost portion of the fuel tank so that the fuel in the fuel tank can be accumulated in the concave portion. Furthermore, since the movement of the fuel that exits the recess is restricted by the first partition plate, the fuel can remain in the recess. Therefore, when the fuel in the fuel tank is small, it is possible to prevent the fuel supply from being insufficient due to the movement of the fuel during acceleration / deceleration of the motorcycle.

  In short, according to the present invention, it is possible to provide a vehicle fuel tank having a simpler structure that can prevent a shortage of fuel supply during acceleration / deceleration of the vehicle when the remaining amount of fuel is small.

  Hereinafter, a vehicle fuel tank according to the present invention will be specifically described with reference to the accompanying drawings.

(First embodiment)
FIG. 1 is a left side perspective schematic view of a motorcycle fuel tank 1 to which a first embodiment of the present invention is applied. As shown in FIG. 1, when a fuel tank is mounted on the motorcycle body, the left side of the figure that is the front side of the motorcycle is “front”, and the right side of the figure that is the rear side of the motorcycle is “rear”. Will be described below. That is, in the first embodiment, one front-rear direction is the front and the other front-rear direction is the rear. FIG. 2 is a left side perspective schematic view of the motorcycle in which the fuel tank 1 is disposed.

  The fuel tank 1 has a main body 2 and a recess 4. The main body 2 has a bottom 3 at a position to be the bottom. The recessed part 4 is provided in the lower part of the bottom part 3 by attachment / detachment structures, such as a volt | bolt and a nut, and is comprised so that attachment and detachment to the bottom part 3 are possible.

  As shown in FIG. 2, the fuel tank 1 is disposed in a space formed by a main frame 91 and a swing arm 92 of the motorcycle. Specifically, the recess 4 of the fuel tank 1 is disposed at the rear position of the main frame 91 and at the rear position of the cross member 94 of the main frame 91. The recess 4 is disposed above the swing arm 92. Further, the concave portion 4 is disposed in front of and above the rear wheel, and is disposed at a position higher than the mudguard member 97 connected to the swing arm 92. The mudguard member 97 is disposed above the front part of the rear wheel.

  The main frame 91 extends rearward from the head pipe 93 and supports the engine and the like. The main frame 91 has a right part and a left part, and the right part and the left part are connected by cross members 94 and 95. A cross member 94 in front of the recess 4 supports the lower end of the fuel tank 1. The swing arm 92 is connected to the main frame 91 via a pivot shaft 96 and can be angularly displaced around the pivot shaft 96.

  The main body 2 forms an internal space including an opening that opens downward. In the present embodiment, the main body 2 is formed in a shape similar to an elliptical rotator formed by rotating an ellipse around its major axis. The wall surface of the main body 2 is formed so as to be inclined downward toward the bottom 3.

  FIG. 3 is an enlarged view of the recess 4 of FIG. The recess 4 forms an internal space including an opening that opens upward. The recess 4 is formed in a weight shape in which a cross-sectional space perpendicular to the vertical axis is reduced in diameter from the opening toward the lowermost end. The opening of the recess 4 is arranged at a position facing the opening of the bottom 3. The recess 4 is configured to block the opening of the bottom 3, and the internal space of the main body 2 and the internal space of the recess 4 are communicated with each other through the openings. And the space enclosed by the main-body part 2 and the recessed part 4 is a sealed space.

  Due to the configuration of the main body 2 and the recess 4 as described above, the fuel replenished in the internal space of the main body 2 flows through the wall surface of the main body 2 toward the opening of the bottom 3, and passes through the internal space of the recess 4. After filling, it is stored in the internal space of the main body 2. Further, when the fuel in the fuel tank 1 is consumed, the liquid level of the fuel stored in the internal space of the main body portion 2 gradually decreases while the internal space of the recess 4 is filled with fuel.

  The fuel pump 5 sucks the fuel in the fuel tank 1 and supplies the fuel to a fuel supply unit (not shown) of the engine. The fuel pump 5 is attached to the bottom 3 of the fuel tank 1. A discharge pipe 51 is attached to the upper part serving as the discharge part of the fuel pump 5, and a suction pipe 6 is attached to the lower part serving as the suction part of the fuel pump 5. The discharge pipe 51 is connected to an engine fuel supply unit, for example, an injector. The suction pipe 6 is fixed to the bottom 3.

  The suction pipe 6 has a suction part 62 and a suction auxiliary part 63. The suction portion 62 is formed in a cylindrical shape whose both ends are open, one end is connected to the suction portion of the fuel pump 5, and the other end is connected to the suction filter 7. The suction auxiliary portion 63 is formed in a cylindrical shape whose one end is opened and the other end is closed, and the suction port 61 on one end on the open side is arranged at a position near the lowermost end of the recess 4. A filter housing space 8 for housing the suction filter 7 is formed on the other end side which is the closing side. One end side of the suction auxiliary portion 63 is formed in a pipe shape having a smaller inner diameter than the filter housing space 8. In the present embodiment, the suction auxiliary portion 63 and the filter housing space 8 are housed in the internal space of the recess 4.

  As shown in FIG. 1, the front portion of the main body 2 is provided with a second partition plate 21 that partitions one space 201 positioned forward with respect to the recess 4 into an upper portion 2011 and a lower portion 2012. Yes. Further, a third partition plate 22 that partitions the other space 202 positioned rearward with respect to the recess 4 into an upper portion 2021 and a lower portion 2022 is provided at the rear portion of the main body portion 2.

  4 is a schematic cross-sectional view taken along the line IV-IV in FIG. As shown in FIG. 4, the left side of the figure is called “front”, the right side of the figure is called “rear”, the upper side of the figure is called “right”, and the lower side of the figure is called “left”. The second partition plate 21 is attached to the front wall 211, the front left wall 212, and the front right wall 213 of the main body 2 with gaps X1, X2, and X3, respectively. 2 extends inwardly from one peripheral edge of the front side. The second partition plate 21 may be provided with a hole 210 penetrating in the vertical direction. As shown in FIG. 1, in a state where the fuel tank 1 is mounted on a motorcycle disposed on a horizontal ground, the second partition plate 21 is horizontal or downward (angle α) toward the rear. It is provided as follows. When the second partition plate 21 faces downward toward the rear, the angle α is set to 0 ° or more and less than 45 °. Preferably, the angle α is set to 30 ° or less. More preferably, the angle α is set to 5 °. The second partition plate 21 is provided so as to have a gap with respect to the fuel pump 5.

  As shown in FIG. 4, the third partition plate 22 is attached to the rear wall 214, the rear left wall 215, and the rear right wall 216 of the main body 2 with gaps Y1, Y2, and Y3, respectively. The tank 1 extends inward from one peripheral edge on the rear side of the main body 2 of the tank 1. And the 3rd partition plate 22 may be provided with the hole 220 penetrated to an up-down direction. As shown in FIG. 1, the third partition plate 22 is horizontal or downward (angle β) toward the front in a state where the fuel tank 1 is mounted on a motorcycle arranged on a horizontal ground. Is provided. When the third partition plate 22 faces downward toward the front, the angle β is set to 0 ° or more and less than 45 °. Preferably, the angle β is set to 30 ° or less. More preferably, the angle β is set to 5 °. The third partition plate 22 is provided so as to have a gap with respect to the fuel pump 5.

  The second partition plate 21 and the third partition plate 22 are disposed below the vertical center of the fuel tank 1. In the case where the fuel tank 1 is formed from two vertically divided members, the inside of the fuel tank 1 is formed by joining the two divided members with the second partition plate 21 and the third partition plate 22 formed on the lower member. In addition, the second partition plate 21 and the third partition plate 22 can be easily formed.

  FIG. 5 is a schematic VV cross-sectional view of FIG. 5, the left side of the figure is called “front”, the right side of the figure is called “rear”, the upper side of the figure is called “right”, and the lower side of the figure is called “left”. The bottom 3 is provided with an opening 31 for sending the fuel existing in the bottom 3 to the recess 4. A first partition plate 32 is provided on the bottom portion 3 so as to partially cover the front portion of the opening 31.

  The bottom 3 is provided with a partition wall 33 having a U-shaped horizontal cross section so as to surround the left side, the right side, and the rear side of the opening 31. The partition wall 33 has a left wall 332, a right wall 333, and a rear wall 334. The left wall 332 is formed in a plate shape, is located to the left of the opening 31 and extends in the front-rear direction. The right wall 333 is formed in a plate shape, is located to the right of the opening 31 and extends in the front-rear direction. The rear wall 334 is formed in a plate shape, is positioned behind the opening 31 and extends in the left-right direction. The rear end portion of the left wall 332 and the rear end portion of the right wall 333 are connected to each other via the rear wall 334.

  The lower part of the partition wall 33 is located at the bottom 3, and the upper end part of the partition wall 33 is located above the second partition plate 21 and the third partition plate 22. The partition wall 33 has a gap in the front-rear direction with respect to the second partition plate 21 and the third partition plate 22. A ceiling wall 331 is provided at an upper end portion of the partition wall 33 so as to cover an upper portion of the partition wall 33. The ceiling wall 331 is provided so as not to interfere with the fuel pump 5. Specifically, a part of the fuel pump 5 is disposed above the ceiling wall 331, and a gap through which the fuel pump 5 is inserted is formed in the ceiling wall 331.

  The partition wall 33 and the ceiling wall 331 form a receiving space that opens forward and is closed in the rear and left-right directions. This receiving space communicates with the internal space of the recess 4 through the opening 31. The volume of the receiving space is formed larger than the volume of the internal space of the recess 4. And the rear wall which forms the internal space of the recessed part 4, and the rear wall 334 of the partition wall 33 which forms the said receiving space are connected smoothly.

  As shown in FIG. 3, the left wall 332 and the right wall 333 of the partition wall 33 have a trapezoidal shape in a side view in which a front upper portion is notched and an upper side is shorter than a lower side. The vertical dimension Z1 on the front side is smaller than the vertical dimension Z2 on the rear side. FIG. 6 is an enlarged view of the recess 4 in FIG. 1 showing the fuel level during acceleration of the motorcycle. The inclination angles of the notch surfaces 3321 and 3331 with respect to the horizontal plane are substantially the same as the inclination angles L1 and L2 of the liquid level of the fuel in the fuel tank 1 during the maximum acceleration of the motorcycle with respect to the horizontal plane. L 1 and L 2 are liquid levels corresponding to the amount of fuel in the fuel tank 1, and L 2 is a liquid level when the internal space of the recess 4 is filled with fuel. For example, the inclination angle is set to the liquid level when a forward 2G inertial force is applied.

  FIG. 7 is an enlarged view of the recess 4 in FIG. 1 showing the fuel level during deceleration of the motorcycle. L3 and L4 indicate the liquid level of the fuel in the fuel tank 1 during maximum deceleration of the motorcycle, and L4 indicates the liquid level when the internal space of the recess 4 is filled with fuel. For example, the inclination angle is set to the liquid level when a 2G inertial force directed backward is applied. As shown in FIGS. 6 and 7, the position of the suction port 61 is below the liquid level of the fuel at the time of maximum acceleration and maximum deceleration of the motorcycle with the internal space of the recess 4 filled with fuel. It is arranged to be.

(Function)
When the fuel is sucked by the fuel pump 5, as shown by an arrow L in FIG. 3, the fuel stored in the lowermost region of the inner space of the recess 4 is filtered from the suction port 61 at one end of the suction auxiliary portion 63. It is sucked into the accommodation space 8. The fuel in the filter housing space 8 is filtered by the suction filter 7 and sucked from one end of the suction portion 62 to the suction port of the fuel pump 5. The fuel pump 5 sends fuel to the fuel supply part of the engine via the discharge pipe 51. When the fuel in the recess 4 decreases, the fuel flows from the main body 2 through the opening 31 of the bottom 3 into the recess 4.

  When the fuel is present in the main body 2 of the fuel tank 1, when the motorcycle decelerates, the fuel in the fuel tank 1 tends to move to the upper portion 2011 of the one space 201 of the fuel tank 1. Here, the movement of the fuel about to move to the upper part 2011 is restricted by the second partition plate 21. As a result, the fuel is easily held in the recess 4 and the fuel pump 5 can be prevented from sucking air. In addition, some fuel may exceed the second partition plate 21 and come to the upper portion 2011. However, since the second partition plate 21 is provided horizontally or downward, the fuel is provided in the upper part 2011. It travels along the upper surface of the two partition plates 21 and can move to the recess 4. Further, since the second partition plate 21 is provided with the inner wall of the fuel tank 1 and the gaps X1, X2, and X3, a part of the fuel that exceeds the second partition plate 21 passes from the gap to the recess 4. Can flow into. Further, when the second partition plate 21 has a hole 210 penetrating vertically, a part of the fuel exceeding the second partition plate 21 can flow into the recess 4 from the hole 210.

  When fuel is present in the main body 2 of the fuel tank 1, when the motorcycle accelerates, the fuel in the fuel tank 1 tends to move to the upper portion 2021 of the other space 202 of the fuel tank 1. Here, the movement of the fuel about to move to the upper portion 2021 is restricted by the third partition plate 22. As a result, the fuel is easily held in the recess 4 and the fuel pump 5 can be prevented from sucking air. In addition, some fuel may exceed the third partition plate 22 and come to exist in the upper portion 2021. However, since the third partition plate 22 is provided horizontally or downwardly, the fuel is disposed in the upper portion 2021. It travels along the upper surface of the three partition plates 22 and can move to the recess 4. Further, since the third partition plate 22 is provided with the inner wall of the fuel tank 1 and the gaps Y1, Y2, and Y3, a part of the fuel that exceeds the third partition plate 22 passes from the gap to the recess 4. Can flow into. Further, when the third partition plate 22 has a hole 220 penetrating vertically, a part of the fuel exceeding the third partition plate 22 can flow into the recess 4 from the hole 220.

  When the fuel exists only in the recess 4, when the motorcycle accelerates, the fuel in the recess 4 comes out of the recess 4 and moves to the other space 202 of the fuel tank 1. Here, the movement of the fuel that comes out of the recess 4 and moves to the other space 202 is restricted by the partition wall 33. As a result, since the fuel tends to stay in the recess 4, the fuel pump 5 can be prevented from sucking air. Further, a part of the fuel is not restricted by the partition wall 33 and moves from the left side or the right side of the partition wall 33 to the other space 202. Here, the fuel that has moved to the other space 202 is restricted from moving to the upper portion 2021 of the other space 202 by the third partition plate 22. In addition, some fuel may exceed the third partition plate 22, but those fuels travel along the upper surface of the third partition plate 22 because the third partition plate 22 is provided horizontally or downward. It becomes possible to move to the recess 4. Further, since the third partition plate 22 is provided with the inner wall of the fuel tank 1 and the gaps Y1, Y2, and Y3, a part of the fuel that exceeds the third partition plate 22 passes from the gap to the recess 4. Can flow into. Further, since the third partition plate 22 has a hole 220 penetrating vertically, a part of the fuel exceeding the third partition plate 22 can flow into the recess 4 from the hole 220.

  When the fuel exists only in the recess 4, when the motorcycle decelerates, the fuel in the recess 4 comes out of the recess 4 and tries to move to the one space 201 of the fuel tank 1. Here, the fuel that comes out of the recess 4 and moves to the one space 201 is regulated by the first partition plate 32. As a result, since the fuel is held in the recess 4, the fuel pump 5 can be prevented from sucking air.

  According to the fuel tank 1 of the said structure, the following effects can be exhibited.

(1) Since the recess 4 is provided in the lower part of the bottom 3 of the fuel tank 1, the fuel is held in the recess 4 when the remaining fuel is small. A suction port 61 of the fuel pump 5 is positioned in the recess 4. Therefore, the fuel tank 1 has a configuration in which the fuel supply is unlikely to be insufficient even when the remaining fuel is small.

(2) Since the concave portion 4 is disposed in a space formed by the main frame 91 and the swing arm 92 of the motorcycle, the concave portion 4 can be disposed in an empty space between the main frame 91 and the swing arm 92. And the recessed part 4 can be arrange | positioned in the lowest part of the fuel tank 1, and the fuel in the fuel tank 1 can be collected in the recessed part 4. FIG.

(3) The movement of the fuel in the main body 2 of the fuel tank 1 from the lower part 2012 to the upper part 2011 of the one space 201 is regulated by the second partition plate 21, and the fuel in the main part 2 of the fuel tank The movement from the lower portion 2022 of the other space 202 to the upper portion 2021 is restricted by the third partition plate 22. The movement of the fuel in the recess 4 to the other space 202 is regulated by the partition wall 33 so that the fuel is held in the recess 4. Further, the first partition plate 32 restricts the fuel in the recess 4 from coming out of the recess 4 and trying to move to the one space 201. As described above, since the movement of the fuel is restricted by the second partition plate 21, the third partition plate 22, the partition wall 33, and the first partition plate 32, the fuel is held in the recess 4. Therefore, when the fuel in the fuel tank 1 is small, it is possible to prevent the fuel supply from being insufficient due to the movement of the fuel during acceleration / deceleration of the motorcycle.

(4) The second partition plate 21 is provided horizontally or downward. Accordingly, the second partition plate 21 restricts the movement of the fuel to the upper portion 2011 of the one space 201 of the fuel tank 1, and the fuel exceeding the second partition plate 21 is supplied to the second partition plate 21 without using a separate pump or the like. Using the upper surface of the two partition plates 21, the fuel can be sent to the recess 4 quickly by its own weight.

(5) The third partition plate 22 is provided horizontally or downward. Therefore, the third partition plate 22 restricts the movement of the fuel to the upper portion 2021 of the other space 202 of the fuel tank 1 and allows the fuel exceeding the third partition plate 22 to be supplied without using a separate pump or the like. Using the upper surface of the three partition plates 22, the fuel can be quickly sent to the recess 4 by its own weight.

(6) The second partition plate 21 and the third partition plate 22 are provided with a gap from the inner wall of the fuel tank 1. A part of the fuel exceeding the second partition plate 21 and the third partition plate 22 flows into the recess 4 through the gap. Therefore, the fuel exceeding the 2nd partition plate 21 and the 3rd partition plate 22 can be sent to the recessed part 4 rapidly.

(7) When the second partition plate 21 and the third partition plate 22 have holes 210 and 220 penetrating vertically, one of the fuels exceeding the second partition plate 21 and the third partition plate 22 The part flows into the recess 4 from the hole. Therefore, the fuel exceeding the 2nd partition plate 21 and the 3rd partition plate 22 can be sent to the recessed part 4 rapidly.

(8) A suction filter 7 is provided in the middle of the suction pipe 6, and the suction filter 7 is located in the filter housing space 8 in the recess 4. Therefore, the suction port 61 located at the lower end of the suction pipe 6 of the fuel pump 5 can be located at the bottom of the recess 4, and even if the remaining fuel is small, it is possible to prevent the fuel supply from becoming insufficient. Further, even if the liquid level of the fuel in the recess 4 is inclined due to acceleration / deceleration of the motorcycle, the filter housing space 8 is filled with the fuel, and the suction filter 7 can be prevented from sucking air.

(9) The recess 4 is formed integrally with the suction pipe 6 of the fuel pump 5 and is configured to be attached to and detached from the bottom 3 of the fuel tank 1. Therefore, it can be formed in advance so that the suction port 61 is positioned at the bottom of the recess 4.

(10) At the time of maximum acceleration and maximum deceleration of the motorcycle in a state where the internal space of the recess is filled with fuel, the suction port 61 is disposed so as to be below the fuel level. . Therefore, when accelerating / decelerating within the set range, the fuel pump 5 can be prevented from sucking air.

(11) Since the ceiling wall 331 is provided on the partition wall 33, it is possible to prevent the fuel whose movement is restricted by the partition wall 33 from coming out from the upper part of the partition wall 33.

(12) The inclination angle of the notch surface 3321 of the left wall 332 of the partition wall 33 and the inclination angle of the notch surface 3331 of the right wall 333 are the same as the inclination angle of the liquid level of the fuel at the maximum acceleration of the motorcycle. The form is substantially the same. Therefore, the left wall 332 and the right wall 333 are notched leaving a wall surface necessary for restricting the movement of fuel. As a result, weight reduction of the partition wall 33 can be achieved without degrading the performance of the partition wall 33 that restricts the movement of fuel. And weight reduction of the fuel tank 1 can be achieved by weight reduction of the partition wall 33.

(13) Since the volume of the receiving space formed by the partition wall 33 and the ceiling wall 331 is larger than the volume of the internal space of the recess 4, the fuel held by the partition wall 33 flows into the recess 4, so that the suction port 61 can be easily located below the liquid level of the fuel.

(14) Since the rear wall of the recess 4 and the rear wall 334 of the partition wall 33 are smoothly connected, the fuel held by the partition wall 33 easily flows into the recess 4.

(15) Since the partition wall 33 has the left wall 332 and the right wall 333, even when the motorcycle travels on an inclined road surface or an uneven road surface, the fuel in the concave portion 4 is directed to the main body portion 2. The effect of restricting the movement and holding the fuel in the recess 4 can be exhibited.

(Second Embodiment)
FIG. 8 is a left side perspective schematic view of a motorcycle fuel tank to which the second embodiment of the present invention is applied. As shown in FIG. 8, when a fuel tank is mounted on the motorcycle body, the left side of the figure that is the front side of the motorcycle is “front”, and the right side of the figure that is the rear side of the motorcycle is “rear”. Will be described below. And in 2nd Embodiment, the opening of the partition wall 33 of 1st Embodiment has faced back, and the 1st partition plate 32 is arrange | positioned so that a part of rear part of the opening part 31 of the bottom part 3 may be covered. . That is, in the second embodiment, one front-rear direction is the rear and the other front-rear direction is the front. Other configurations are the same as those of the first embodiment, and the same parts and portions as those of the first embodiment are denoted by the same reference numerals.

  The bottom 3 is provided with a partition wall 33 having an inverted U-shaped horizontal cross section so as to surround the left side, the right side, and the front side of the opening 31. The bottom of the partition wall 33 is positioned at the bottom 3, and the upper end of the partition wall 33 is positioned above the second partition plate 21 and the third partition plate 22. The partition wall 33 has a gap with the second partition plate 21 and the third partition plate 22. A ceiling wall 331 is provided at an upper end portion of the partition wall 33 so as to cover an upper portion of the partition wall 33. The ceiling wall 331 is provided so as not to interfere with the fuel pump 5.

  The left wall 332 and the right wall 333 of the partition wall 33 have a trapezoidal shape in which a rear upper part is notched and an upper side is shorter than a lower side. The inclination angle of notch surfaces 3321 and 3331 with respect to the horizontal plane is substantially the same as the inclination angle of the liquid level of fuel in fuel tank 1 with respect to the horizontal plane during maximum deceleration of the motorcycle.

(Function)
When the fuel exists only in the recess 4, when the motorcycle decelerates, the fuel in the recess 4 comes out of the recess 4 and tries to move to the other space 202 of the fuel tank 1. Here, the movement of the fuel that comes out of the recess 4 and moves to the other space 202 is restricted by the partition wall 33. As a result, since the fuel is held in the recess 4, the fuel pump 5 can be prevented from sucking air. Further, a part of the fuel is not restricted by the partition wall 33 and moves from the left side or the right side of the partition wall 33 to the other space 202. Here, the fuel that has moved to the other space 202 is restricted from moving to the upper portion 2021 of the other space 202 by the third partition plate 22. In addition, some fuel may exceed the third partition plate 22, but those fuels travel along the upper surface of the third partition plate 22 because the third partition plate 22 is provided horizontally or downward. It becomes possible to move to the recess 4. Further, since the third partition plate 22 is provided with a gap from the inner wall of the fuel tank 1, part of the fuel that exceeds the third partition plate 22 may flow into the recess 4 from the gap. it can.

  When the fuel exists only in the recess 4, when the motorcycle accelerates, the fuel in the recess 4 comes out of the recess 4 and moves to the one space 201 of the fuel tank 1. Here, the fuel that comes out of the recess 4 and moves to the one space 201 is regulated by the first partition plate 32. As a result, since the fuel is held in the recess 4, the fuel pump 5 can be prevented from sucking air.

  The operation of the present embodiment in which the motorcycle accelerates and decelerates when the fuel is present in the main body 2 of the fuel tank 1 is the same as that of the first embodiment.

  According to the fuel tank 1 of the said structure, the following effects can be exhibited.

(1) The movement of the fuel in the main body 2 of the fuel tank 1 from the lower part 2012 to the upper part 2011 of the one space 201 is regulated by the second partition plate 21, and the fuel in the main part 2 of the fuel tank The movement from the lower portion 2022 of the other space 202 to the upper portion 2021 is restricted by the third partition plate 22. Then, the movement of the fuel in the recess 4 to the other space 202 of the fuel is restricted by the partition wall 33 so that the fuel is held in the recess 4. Further, the first partition plate 32 restricts the fuel in the recess 4 from coming out of the recess 4 and trying to move to the one space 201. As described above, since the movement of the fuel is restricted by the second partition plate 21, the third partition plate 22, the partition wall 33, and the first partition plate 32, the fuel is held in the recess 4. Therefore, when the fuel in the fuel tank 1 is small, it is possible to prevent the fuel supply from being insufficient due to the movement of the fuel during acceleration / deceleration of the motorcycle.

(2) The inclination angle of the notch surface 3321 of the left wall 332 of the partition wall 33 and the inclination angle of the notch surface 3331 of the right wall 333 are the same as the inclination angle of the liquid level of the fuel at the maximum deceleration of the motorcycle. The form is substantially the same. Therefore, the left wall 332 and the right wall 333 are notched leaving a wall surface necessary for restricting the movement of fuel. As a result, weight reduction of the partition wall 33 can be achieved without degrading the performance of the partition wall 33 that restricts the movement of fuel. And weight reduction of the fuel tank 1 can be achieved by weight reduction of the partition wall 33.

(3) The effects of the other configurations are the same as in the first embodiment.

(4) Since the amount of fuel consumed during acceleration is larger than that during deceleration, it is preferable that the partition wall 33 having a large fuel holding capacity be opened forward in order to hold a large amount of fuel. Therefore, in the second embodiment in which the partition wall 33 opens rearward, it is preferable that the concave portion 4 is larger than the first embodiment so that a large amount of fuel can be held in the concave portion 4.

The present invention is a technique that can be applied to a vehicle in general, but is particularly preferably used for a vehicle that has a relatively large acceleration / deceleration and a small fuel tank 1. In particular, among small vehicles, saddle-riding type vehicles,
For example, the present invention is preferably applied to vehicles such as motorcycles, small planing boats such as PWC, ATVs (All Terrain Vehicles), snow vehicles and the like.

  The fuel pump 5 may have another shape. For example, if the suction port 61 is disposed in the recess 4, the main body of the fuel pump 5 may be fixed to the inner upper wall of the fuel tank 1. Further, the main body of the fuel pump 5 may be formed outside the fuel tank 1. Further, the attachment position of the discharge pipe 51 is not limited.

  The first partition plate 32, the second partition plate 21, the third partition plate 22, and the partition wall 33 may be formed separately from the inner wall of the fuel tank 1, and integrated with the inner wall of the fuel tank 1. It may be formed.

  The partition wall 33 may be configured to have an opening on one side in the front-rear direction and cover the opening 31, and the horizontal cross section may be U-shaped.

  The notch surface 3321 of the left wall 332 and the notch surface 3331 of the right wall 333 of the partition wall 33 are formed for the case where the left wall 332 and the right wall 333 of the partition wall 33 are rectangular. Regardless of the shape of the partition wall 33, it is sufficient that the vertical dimension Z1 on the opening side is smaller than the vertical dimension Z2 on the opposite side to the opening side in the front-rear direction.

  The upper end portion of the partition wall 33 may be disposed below the second partition plate 21 and the third partition plate 22. The first partition plate 32 may be inclined downward toward the opening 31 of the bottom 3.

  The fuel pump 5 may be integrally fixed to the recess 4. In this case, the fuel pump 5 may be detachable from the main body 2 of the fuel tank 1 together with the recess 4. In this case, the cross-sectional area of the fuel pump 5 is formed smaller than the opening area of the opening 31 of the bottom 3. The fuel pump 5 can be easily fixed to the fuel tank 1 by fixing the recess 4 to the main body 2 while the fuel pump 5 is fixed to the recess 4.

  The gap between the second partition plate 21 and the main body 2 of the fuel tank 1 may not be formed on all of the front, left, and right sides, and may be formed on any one of them. Further, the gap between the third partition plate 22 and the main body 2 may not be formed on all of the rear, left, and right sides, and may be formed on any one of them. Moreover, as long as it has a clearance gap between the 2nd partition plate 21 and the 3rd partition plate 22, the 2nd partition plate 21 and the 3rd partition plate 22 may not have a main-body part and a clearance gap.

  The shape of the main body 2 of the fuel tank 1 may not be an elliptical rotor shape. For example, a saddle shape that is asymmetrical in the front and rear direction may be used. Further, it may be an arc shape curved downward from the front to the rear in a side view.

  In the above embodiment, the horizontal sectional shape of the fuel tank 1 is substantially square (rectangular), but may be elliptical or circular. Similarly, the horizontal sectional shapes of the second partition plate 21, the third partition plate 22, and the first partition plate 32 are square (rectangular), but may be elliptical or circular.

  In the said embodiment, although the up-down direction position of the 2nd partition plate 21 and the up-down direction position of the 3rd partition plate 22 are the same, each up-down direction position may differ.

  In the above embodiment, the filter housing space 8 is provided in the recess 4, and the suction filter 7 is provided in the filter housing space 8. However, as shown in FIG. 9, the suction filter 7 may be provided at the tip of the suction pipe 6 without providing the filter housing space.

  Various modifications and changes can be made without departing from the spirit and scope of the invention as set forth in the appended claims.

  In the present invention, when the remaining amount of fuel is small, it is possible to provide a simpler vehicle fuel tank 1 that can prevent a shortage of fuel supply at the time of acceleration / deceleration of the vehicle. Therefore, the industrial utility value is great. .

1 is a left side perspective schematic view of a motorcycle fuel tank 1 to which a first embodiment of the present invention is applied. FIG. 2 is a left side perspective schematic view of a motorcycle in which a fuel tank 1 is disposed. It is an enlarged view of the recessed part 4 of FIG. FIG. 4 is a schematic sectional view taken along the line IV-IV in FIG. 1. It is a VV cross-sectional schematic of FIG. It is an enlarged view of the recessed part 4 of FIG. 1 which described the liquid level of the fuel at the time of acceleration of a motorcycle. It is an enlarged view of the recessed part 4 of FIG. 1 which described the liquid level of the fuel at the time of the deceleration of a motorcycle. FIG. 6 is a left side perspective schematic view of a motorcycle fuel tank 1 to which a second embodiment of the present invention is applied. It is an enlarged view of the recessed part 4 of another embodiment which provided the filter 7 for suction in the front-end | tip part of the suction pipe 6. FIG.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Fuel tank 2 Main part 201 One space 2011 Upper part 2012 Lower part 202 Other space 2021 Upper part 2022 Lower part 21 2nd partition plate 22 3rd partition plate 3 Bottom part 31 Opening part 32 1st partition plate 33 Partition wall 4 Concave part 5 Fuel pump 51 Discharge pipe 6 Suction pipe 61 Suction port 62 Suction part 63 Suction auxiliary part 7 Suction filter 8 Filter housing space 91 Main frame 92 Swing arm 94 Cross member

Claims (8)

A fuel tank for a vehicle,
A recess provided in a lower portion of the bottom of the main body of the fuel tank, in which an intake port of a fuel pump that sucks fuel in the fuel tank and supplies fuel to a fuel supply unit of the engine is located in an internal space;
A partition wall that stands on the bottom and surrounds the upper surface opening of the recess from the other in the front-rear direction and opens toward the front-rear direction;
A fuel tank, comprising: a first partition plate that covers, from above, a portion on one side in the front-rear direction of the upper surface opening of the recess.
The partition wall is provided with a ceiling wall that covers the partition wall from above,
The fuel tank according to claim 1 , wherein a volume of a receiving space formed by the partition wall and the ceiling wall is larger than a volume of an internal space of the recess .
A portion of the fuel pump is disposed above the ceiling wall;
The fuel tank according to claim 2, wherein a gap through which the fuel pump is inserted is formed in the ceiling wall.
The fuel tank according to any one of claims 1 to 3, wherein the recess is formed integrally with a suction pipe of the fuel pump and is configured to be attached to and detached from the bottom.
A second partition plate that partitions one space located on one side in the front-rear direction with respect to the concave portion of the main body portion of the fuel tank into an upper portion and a lower portion;
A third partition plate that partitions the other space of the main body portion of the fuel tank located on the other side in the front-rear direction with respect to the concave portion into an upper portion and a lower portion;
The said 2nd partition plate and the said 3rd partition plate have a clearance gap between fuel tank wall surfaces, or have the hole penetrated up and down, Any one of Claims 1-4 The fuel tank as described in.
A fuel tank for a motorcycle,
The fuel tank according to claim 1, wherein the recess is disposed in a space formed by a main frame and a swing arm.
The fuel tank according to claim 6, wherein the recess is disposed at a rear position of the main frame.
The fuel tank according to any one of claims 1 to 7, wherein a wall surface of the main body portion is formed to be inclined downward toward the bottom portion.

Images