JP5278171B2 - Member mounting structure to fuel tank - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a structure for attaching a member to a fuel tank, configured so that liquid inside an annularly formed attachment member can be discharged without particular discharge operation. <P>SOLUTION: An annular pump-side retainer 32 includes a bead 40 continued from the inner circumferential side to the outer circumferential side, and a recessed part 44 formed on a holding surface 34 side to continue from the inner circumferential side to the outer circumferential side. Since the recessed part 44 constitutes a flow passage 46 between it and a flange part 30 of a fuel pump module 16, the liquid is discharged from the inner circumferential side of the pump-side retainer 32 to the outer circumferential side. <P>COPYRIGHT: (C)2011,JPO&amp;INPIT

Description

  The present invention relates to a member attachment structure to a fuel tank for attaching a member to be attached to the surface of the fuel tank.

  As a structure for attaching a member to be attached to the surface of the fuel tank, Patent Document 1 describes a structure in which a protector member is attached to a pump module using a lock plate. The lock plate described in Patent Document 1 is formed in an annular shape, and the portion facing the pump module is in annular contact with the pump module. Therefore, for example, cleaning water used in a car wash or the like may accumulate inside the lock plate (upper surface of the pump module), and it is desirable to drain the accumulated liquid.

JP 2004-138010 A

  In view of the above facts, an object of the present invention is to obtain a member mounting structure for a fuel tank in which liquid inside the mounting member formed in an annular shape is discharged without particularly performing a discharging operation.

According to the first aspect of the present invention, there is provided an attachment member having a sandwiching surface that is formed in an annular shape and sandwiches a member to be attached disposed on the upper surface of the fuel tank with the surface of the fuel tank, and an outer periphery of the attachment member A vertical portion formed at an end, and engaged with a member to be engaged of the fuel tank in a state where the sandwiching surface is in contact with the member to be attached, so as to fix the member to be attached to the fuel tank. And a bead having a convex portion that is formed on a surface opposite to the sandwiching surface of the mounting member , and that projects from the inner peripheral end of the sandwiching surface to the vertical portion, and the convex portion. A recessed portion that is formed on the clamping surface of the mounting member so as to continue from the inner peripheral end to the vertical portion at a corresponding position, and is partially spaced from the mounted member.

  In this member attachment structure to the fuel tank, the attachment member disposed on the upper surface of the fuel tank is sandwiched between the attachment surface of the attachment member and the surface of the fuel tank. The mounting member is formed in an annular shape, and the sandwiching surface also contacts the mounted member in an annular shape. Then, with the clamping surface in contact with the attached member in this way, the engaging portion formed on the attaching member is engaged with the engaged member of the fuel tank, and the attached member is fixed to the fuel tank. .

A vertical portion is formed at the outer peripheral end of the mounting member, and the engaging portion includes this vertical portion. Further, a bead is formed on a surface of the engaging member opposite to the sandwiching surface, and the bead includes a convex portion that is convexly continuous from the inner peripheral end of the sandwiching surface to the vertical portion. Thereby, the rigidity of an attachment member is improved.
A concave portion is formed on the clamping surface of the mounting member so as to be continuous from the inner peripheral end to the vertical portion at a position corresponding to the convex portion, and the concave portion is partially spaced from the member to be mounted ( The separation portion) continues from the inner peripheral end of the sandwiching surface to the vertical portion of the outer peripheral end of the attached member. Therefore, the liquid on the inner side in the radial direction of the mounting member is discharged to the outside through this separated portion without particularly performing a discharge operation.
And the attachment member provided with both the convex part and the recessed part can be comprised by forming a bead in this way.

According to a second aspect of the present invention, in the first aspect of the present invention, in the first aspect of the present invention, an annular rising that rises in a direction away from the mounted member on the inner periphery of the mounting member rather than a surface opposite to the sandwiching surface. A wall is formed.

  The rising wall increases the rigidity of the mounting member. Since the rising wall rises in a direction away from the attached member than the surface opposite to the sandwiching surface, the amount of liquid that accumulates inside the attachment member increases, but this liquid is discharged to the outside by the recess. Can do.

According to a third aspect of the present invention, in the first or second aspect of the present invention, the tip of the tool is formed by restricting the movement of the tip of the tool in the circumferential direction of the mounting member that is formed on the attached member. Is formed on the mounting member so that a fulcrum member whose rotation is a fulcrum and a longitudinal intermediate portion of the tool whose tip movement is limited by the fulcrum member, and the rotation of the tool causes the circumferential direction of the mounting member And an action point member for applying a rotational force to the attachment member from the tool.

  The “tool” is a general-purpose tool that is restricted in movement at a fulcrum member, such as a driver-like one, a bar-like one, and the like, and can apply the rotational force to the mounting member by the action point member. Is included.

  Therefore, if the movement of the tip of the tool is restricted by the fulcrum member, the tool can rotate with the tip as a fulcrum. When the tool is rotated in this state, since the tool is in contact with the action point member at the middle portion in the longitudinal direction, the rotational force in the circumferential direction of the attachment member acts on the attachment member from the tool. That is, the mounting member can be rotated in the circumferential direction by the lever principle. For example, even when the engaging force between the engaging portion and the engaged member is set high, it is possible to easily perform engagement and disengagement using a general-purpose tool.

According to a fourth aspect of the present invention, in the invention of the third aspect, the action point member is formed so as to penetrate the attachment member from a surface opposite to the sandwiching surface to the sandwiching surface. .

  That is, since the tool can be inserted into the working point member from the surface opposite to the sandwiching surface, the workability can be improved as compared with the structure in which the tool is inserted from a different direction (for example, the radial direction of the mounting member). Becomes higher.

According to a fifth aspect of the present invention, in the invention according to the third or fourth aspect of the present invention, the working set is constituted by the fulcrum member and the action point member, and acts on the mounting member in the circumferential direction. Are provided so as to have different phase differences in the circumferential direction.

  Therefore, by appropriately selecting from a plurality of action groups according to the position of the attachment member, and using the action group for applying a rotational force in the circumferential direction to the attachment member, the attachment members that are rotated by each action group Even if the rotation angle is small, the mounting member can be rotated at a large rotation angle with a plurality of action groups.

  Since the present invention is configured as described above, the liquid inside the annular mounting member is discharged without particularly performing a discharge operation.

It is a top view which shows the member attachment structure to the fuel tank of 1st Embodiment of this invention in the state which tightened the pump side retainer. It is the II-II sectional view taken on the line of FIG. 1 which shows the member attachment structure to the fuel tank of 1st Embodiment of this invention. It is a top view which shows the member attachment structure to the fuel tank of 1st Embodiment of this invention in the state before tightening a pump side retainer. It is a top view which shows the member attachment structure to the fuel tank of 1st Embodiment of this invention in the state in the middle of tightening a pump side retainer. It is a perspective view which expands partially and shows the member attachment structure to the fuel tank of 1st Embodiment of this invention in the state in the middle of tightening a pump side retainer. It is a perspective view which expands partially and shows the member attachment structure to the fuel tank of 1st Embodiment of this invention in the state which tightened the pump side retainer. It is explanatory drawing which shows the relationship between the penetration hole and holding hole in the member attachment structure to the fuel tank of 1st Embodiment of this invention in the state before tightening a pump side retainer. It is explanatory drawing which shows the relationship between the insertion hole and holding hole in the member attachment structure to the fuel tank of 1st Embodiment of this invention in the state in the middle of tightening a pump side retainer. It is explanatory drawing which shows the relationship between the insertion hole and holding hole in the member attachment structure to the fuel tank of 1st Embodiment of this invention in the state in the middle of tightening a pump side retainer. It is explanatory drawing which shows the relationship between the penetration hole and holding hole in the member attachment structure to the fuel tank of 1st Embodiment of this invention in the state which tightened the pump side retainer. It is explanatory drawing which shows the force applied when tightening a pump side retainer by the relationship with a tool, (A) is the case of the comparative example using an exclusive tool, (B) is the case of the present invention using a general-purpose tool. is there. It is explanatory drawing which shows the modification of the recessed part in the member attachment structure to this invention fuel tank. It is a top view which shows the modification of arrangement | positioning of the penetration hole or holding hole in the member attachment structure to this invention fuel tank. It is a top view which shows the modification of arrangement | positioning of the penetration hole or holding hole in the member attachment structure to this invention fuel tank. It is a top view which shows the modification of the action | operation point member in the member attachment structure to this invention fuel tank. It is a top view which shows the modification of the fulcrum member in the member attachment structure to this invention fuel tank.

  1 and 2 show a member mounting structure 12 to a fuel tank according to a first embodiment of the present invention. This member mounting structure 12 is a structure applied to detachably mount the fuel pump module 16 (the whole image is not shown) to the fuel tank 14 using the pump side retainer 32.

  As shown in FIG. 2, an opening 18 is formed in the fuel tank 14, and the fuel pump module 16 is inserted into the opening 18 from the outside. A flat cylindrical tank cylindrical portion 20 that rises substantially vertically from the periphery of the opening 18 is formed, and the upper portion of the tank cylindrical portion 20 is a support surface 22 on which a flange portion 30 described later is supported. .

  An annular groove 24 surrounding the opening 18 is formed in the support surface 22, and an annular seal ring 26 is accommodated in the groove 24. The upper portion of the seal ring 26 is exposed slightly above the support surface 22, and actually, the flange portion 30 is supported at this exposed portion.

  The fuel pump module 16 has a pump cylindrical portion 28 formed in a substantially cylindrical shape at an upper portion thereof, and a fuel pump main body (not shown) is suspended and held below the pump cylindrical portion 28. From the upper part of the pump cylindrical part 28, the flange part 30 is extended toward the circumferential direction outer side. The opening 18 of the fuel tank 14 has a larger diameter than the pump cylindrical portion 28 and a smaller diameter than the flange portion 30. Accordingly, the pump cylindrical portion 28 is inserted into the opening 18, but the lower surface of the flange portion 30 contacts the upper portion (exposed portion) of the seal ring 26 around the opening 18.

  An annular tank side lock ring 62 is embedded in the tank cylindrical portion 20 of the fuel tank 14 so as to surround the periphery of the opening 18. The tank side lock ring 62 has a radially inner portion embedded in a resin constituting the fuel tank 14. The radially outer portion of the tank side lock ring 62 protrudes radially outward from the tank cylindrical portion 20. In the following description, “radial direction” and “circumferential direction” refer to the radial direction and circumferential direction of the tank cylindrical portion 20, and these refer to the radial direction of the tank side lock ring 62 and the pump side retainer 32. And coincides with the circumferential direction.

  As shown in FIG. 1, the pump side retainer 32 is formed in an annular shape. Further, as can be seen from FIG. 2, one end face (lower face) in the thickness direction is a sandwiching face 34. The sandwiching surface 34 contacts the upper portion of the seal ring 26 and sandwiches the flange portion 30 with the support surface 22.

  From the inner periphery of the pump side retainer 32, an annular rising wall 36 that rises substantially perpendicularly in a direction away from the support surface 22 is formed, and the rigidity of the pump side retainer 32 is improved. The upper end of the rising wall 36 is located further above the upper surface 38 (the surface opposite to the sandwiching surface 34) of the pump side retainer 32.

  The pump-side retainer 32 is formed with a plurality of beads 40 (eight in the present embodiment equally in the circumferential direction) spaced from the inner circumferential end to the outer circumferential end with a predetermined interval in the circumferential direction. As shown in FIGS. 5 and 6, each of the beads 40 is formed by locally bending a plate material constituting the pump side retainer 32 upward, and protrudes upward on the upper surface 38 side. A convex portion 42 is formed. Thereby, the rigidity of the pump side retainer 32 is improved. In particular, by forming a plurality of beads 40 (convex portions 42) equally in the circumferential direction, the rigidity deviation of the pump side retainer 32 is reduced.

  On the other hand, since the bead 40 is formed on the sandwiching surface 34 side, a concave portion 44 that is continuous from the inner peripheral side to the outer peripheral side is formed at a position corresponding to the bead 40. A flow path 46 is formed between them. The flow path 46 is a gap partially spaced from the support surface 22, and allows the liquid to move from the inner peripheral side to the outer peripheral side of the pump side retainer 32 (see arrow LF).

  As shown in detail in FIGS. 3 and 4, a plurality of (in the present embodiment, a total of eight, which are the same positions as the beads 40) are provided at predetermined intervals in the circumferential direction from the outer periphery of the pump side retainer 32. A joining piece 48 is formed. Each of the engagement pieces 48 includes a vertical portion 50 extending downward and a horizontal portion 52 extending radially inward from the lower end of the vertical portion 50.

  On the other hand, the tank side lock ring 62 is formed with a plurality of locking long holes 64 shaped along the circumferential direction at positions corresponding to the engagement pieces 48 of the pump side retainer 32. Each of the locking long holes 64 has a curved shape concentric with the tank side lock ring 62, and has a wide portion 64W on one end side in the longitudinal direction and a narrow portion 64N on the other end side. ing. The narrow portion 64N has a width that is slightly wider than the thickness (the length in the radial direction) of the vertical portion 50 of the engagement piece 48. The narrow portion 64N has a width that is slightly wider than the depth (the length in the radial direction) of the horizontal portion 52 of the engagement piece 48.

  Therefore, as shown in FIG. 3, when the horizontal portion 52 of the engagement piece 48 is made to correspond to the wide portion 64W of the locking long hole 64 and the pump side retainer 32 is approached from above, the horizontal portion 52 is obtained. Is inserted through the wide portion 64 </ b> W and reaches below the tank side lock ring 62. Here, when the pump side retainer 32 is rotated in the direction of the arrow R1, the vertical portion 50 of the engagement piece 48 moves within the narrow portion 64N of the locking long hole 64, as shown in FIGS. The direction of the arrow R1 is a direction for fastening the pump side retainer 32 to the tank side lock ring 62 and attaching the fuel pump module 16 to the fuel tank 14, and is hereinafter referred to as “tightening direction” as appropriate. Further, this opposite direction is a direction in which the pump side retainer 32 is loosened from the tank side lock ring 62, and is hereinafter referred to as a “relaxation direction”.

  In the tank side lock ring 62, a tank side engagement portion 66 is formed at a predetermined position corresponding to the narrow portion 64N of the locking long hole 64. As shown in FIGS. 7 to 10, the tank side engaging portion 66 is formed by bending a plate material constituting the tank side lock ring 62 so as to locally protrude downward.

  A retainer side engaging portion 54 is also formed in the horizontal portion 52 of the engaging piece 48 of the pump side retainer 32. The retainer side engaging portion 54 is formed by bending a plate material constituting the engaging piece 48 so as to locally protrude upward.

  As shown in detail in FIGS. 5 and 6, the relative positional relationship between the tank side engaging portion 66 and the retainer side engaging portion 54 depends on the rotation of the pump side retainer 32 in the tightening direction (arrow R1 direction). As a result, the retainer side engaging portion 54 contacts the tank side engaging portion 66 while the vertical portion 50 of the engaging piece 48 is moving in the narrow portion 64N of the locking long hole 64 (see FIG. 5). Further, the pump side retainer 32 is further rotated in the tightening direction (arrow R1 direction), so that the retainer side engaging portion 54 gets over and engages with the tank side engaging portion 66 (see FIG. 6). Yes. In particular, in this embodiment, a plurality (eight) of the retainer side engaging portions 54 and the tank side engaging portions 66 are equally arranged in the circumferential direction, so that the pump side retainer 32 is attached to the tank side lock ring 62. It can be engaged and held all around.

  Here, as can be seen from FIGS. 7 to 10, both the tank side engaging portion 66 and the retainer side engaging portion 54 are slanted in the state before the engagement (the positional relationship shown in FIGS. 7 and 8). Opposing first tapered surfaces 68 are formed. Further, on the opposite side of the first tapered surface 68, a second tapered surface 70 that is diagonally opposed is formed in the state after engagement (the positional relationship shown in FIGS. 9 and 10). These tapered surfaces reduce the resistance when the retainer side engaging portion 54 gets over the tank side engaging portion 66.

  The horizontal portion 52 of the engagement piece 48 is set to have different heights (the rear portion 52R is higher) in the front portion 52F and the rear portion 52R of the retainer side engagement portion 54. The front side portion 52F is in contact with the tip (lower end) portion of the tank side engaging portion 66 before the retainer side engaging portion 54 engages with the tank side engaging portion 66, and the pump side retainer 32 is in contact with the front side portion 52F. Appropriate resistance to rotation is generated. On the other hand, since the rear portion 52R is positioned higher than the front portion 52F, the tip of the tank side engaging portion 66 is in a state where the retainer side engaging portion 54 is engaged with the tank side engaging portion 66. The lower end of the pump side retainer 32 is brought into contact with the (lower end) portion, so that a greater resistance is generated in the rotation of the pump side retainer 32 than in the state before the engagement, thereby preventing inadvertent rotation of the pump side retainer 32 in the loosening direction.

  As shown in FIGS. 1 to 4, the pump side retainer 32 is formed with a plurality of insertion holes 72 penetrating from the upper surface 38 to the sandwiching surface 34 at predetermined positions in the circumferential direction. A plurality of holding holes 74 are formed at predetermined positions in the circumferential direction. In the present embodiment, in particular, three insertion holes 72A, 72B, 72C are formed with a predetermined interval in the circumferential direction. Further, three holding holes 74 (holding holes 74A, 74B, and 74C) are formed corresponding to the three insertion holes 72A, 72B, and 72C, respectively.

  Each of the insertion holes 72 has the same shape, and has a shape and a position where a general-purpose tool 76 such as a driver (see FIGS. 7 to 10) can be inserted from the opposite side (upper side) of the sandwiching surface 34. ing. On the other hand, the holding holes 74 have the same shape, and can hold the tip of the general-purpose tool 76 inserted through the insertion hole 72 (the tip of the general-purpose tool 76 may be inserted slightly, but the insertion The shape is such that the insertion is stopped by contacting the inner surface or edge of the holding hole 74 in the middle. Therefore, the general-purpose tool 76 can rotate in the direction of arrow R3 and the direction of arrow R4 (see FIG. 7), which is the opposite direction, with its tip as a fulcrum.

  Further, when the general-purpose tool 76 whose tip is held in the holding hole 74 is rotated in the direction of the arrow R3 and the direction of the arrow R4, the general-purpose tool 76 comes into contact with the hole wall of the insertion hole 72 (excessive play). It is set as the hole width which can make the rotational force of the circumferential direction act on the pump side retainer 32 without attaching. That is, the general-purpose tool 76 functions as a “lever” in which a contact portion with the insertion hole 72 is an action point and a tip is a fulcrum.

  Here, the corresponding holding holes 74A, 74B, and 74C and the insertion holes 72A, 72B, and 72C constitute an action set in the present invention, and the action sets are center angles α, β, γ, (center C1 The positions of the insertion hole 72 and the holding hole 74 are set so that the angles formed by the two diameters when the diameters of the holding hole 74 and the insertion hole 72 are different from each other. Specifically, as shown in FIG. 3, for example, the rotation position of the pump side retainer 32 is such that the horizontal portion 52 of the engagement piece 48 and the wide portion 64W of the locking long hole 64 correspond to each other. At this time, a circumferential phase difference is provided between the insertion hole 72 and the holding hole 74 so that the central angle α is the smallest and increases in the order of the central angle β and the central angle γ.

  Further, in this state, as shown in FIG. 7, the upstream side in the tightening direction of the pump side retainer 32 (the right side in FIG. 7) with respect to the holding holes 74A, 74B, and 74C corresponding to the insertion holes 72A, 72B, and 72C, respectively. These positional relationships are set so as to be located at ().

  Further, as shown in FIG. 7, the positions of the holding hole 74A and the insertion hole 72A in this state are inserted into the insertion hole 72A by inserting a general-purpose tool 76 such as a screwdriver from the opposite side (upper side) of the clamping surface 34. With the tip of the tool 76 held in the holding hole 74A, the inclination angle θ (angle measured from the vertical line passing through the holding hole 74) of the general-purpose tool 76 is within a predetermined range (for example, 25 degrees or less). Is set. Then, the pump side retainer 32 can be rotated by a predetermined angle in the tightening direction (arrow R1 direction) by rotating the general-purpose tool 76 in the arrow R3 direction around the tip. After the rotation, as shown in FIG. 8, the first tapered surfaces 68 of the retainer side engaging portion 54 and the tank side engaging portion 66 are in contact with each other.

  At this time, as can be seen from FIG. 8, the relative relationship between the holding hole 74B and the insertion hole 72B is such that the inclination angle θ of the general-purpose tool 76 in the holding hole 74B and the insertion hole 72B is within a predetermined range (for example, 25 degrees or less). Position is set. Therefore, the pump-side retainer 32 can be rotated by a predetermined angle in the tightening direction (arrow R1 direction) by inserting the general-purpose tool 76 into the insertion hole 72B and holding it in the holding hole 74B and further rotating it in the arrow R3 direction. it can. By this rotation, as shown in FIG. 9, the retainer side engaging portion 54 gets over the tank side engaging portion 66.

  In this state, as can be seen from FIG. 9, the holding hole 74C and the insertion hole 72C are arranged so that the inclination angle θ of the general-purpose tool 76 in the holding hole 74C and the insertion hole 72C is within a predetermined range (for example, 25 degrees or less). The relative position is set. Therefore, the pump-side retainer 32 is further rotated by a predetermined angle in the tightening direction (arrow R1 direction) by inserting the general-purpose tool 76 into the insertion hole 72C and holding the tip in the holding hole 74C and further rotating in the arrow R3 direction. Can be made. By this rotation, the retainer side engaging portion 54 moves in the tightening direction and is separated from the tank side engaging portion 66 as shown in FIG. Even in this state, when the retainer side engaging portion 54 moves in the loosening direction, the retainer side engaging portion 54 and the tank side engaging portion 66 are engaged with each other because the tank side engaging portion 66 comes into contact. Will be maintained.

  In this way, by providing a plurality of action groups (insertion holes 72 and holding holes 74) and sequentially changing the insertion holes 72 (and the holding holes 74 holding the tips) through which the general-purpose tool 76 is inserted, the pump side The rotation stroke of the retainer 32 in the tightening direction (arrow R1 direction) can be ensured to be large as compared with the case where a single action group is used.

  An induction taper surface 56 that is inclined obliquely downward toward the distal end is formed on the distal end side in the tightening direction of the horizontal portion 52 of the engagement piece 48. The guide taper surface 56 prevents the front end of the engagement piece 48 from abutting against the first taper surface 68 when the engagement piece 48 moves in the tightening direction, and the engagement piece 48 smoothly moves in the tightening direction. It has a function of slightly guiding (guiding) the engaging piece 48 so as to move.

  Next, a method for attaching the fuel pump module 16 to the fuel tank 14 using the member attachment structure 12 of the present embodiment and the operation of the member attachment structure 12 will be described.

  In order to attach the fuel pump module 16 to the fuel tank 14, first, the fuel pump module 16 is inserted into the fuel tank 14 through the opening 18 (see FIG. 2), and the flange portion 30 is in contact with the seal ring 26. 3, the horizontal portion 52 of the engagement piece 48 of the pump side retainer 32 is positioned in the wide portion 64W in the locking long hole 64 of the tank side lock ring 62, and the pump side retainer 32 is placed in the fuel tank 14. Move towards.

  In the state where the horizontal portion 52 reaches below the tank side lock ring 62, as shown in FIG. 7, the general-purpose tool 76 is inserted into the insertion hole 72A, and the tip is held in the holding hole 74A. At this time, the upper part of the general-purpose tool 76 is inclined toward the loosening direction. Then, as shown in FIG. 11B, the general-purpose tool 76 is rotated in the direction of arrow R3 by applying a force with the tip as a fulcrum FL and the upper end as a force point PF. At this time, since the tank side lock ring 62 is embedded and fixed in the fuel tank 14, the tank side lock ring 62 does not rotate in the circumferential direction, but the insertion portion of the general-purpose tool 76 into the insertion hole 72 becomes the point of action PA, and the pump side retainer 32 A rotational force (torque) in the tightening direction (arrow R1 direction) acts (the principle of leverage).

  Here, in this embodiment, the force required for the rotation can be reduced as compared with the conventional structure in which the pump side retainer 32 is rotated using a dedicated tool. This will be described with reference to FIGS. 11A and 11B.

  FIG. 11A shows a state in which the pump side retainer 32 is rotated using a conventional dedicated tool 90 as a comparative example to the present invention. The dedicated tool 90 is a lever-like member having a center C1 of the pump side retainer 32 as a fulcrum FL, an action point PA at the substantially longitudinal center, and an end opposite to the fulcrum FL having a force point PF. , The pump side retainer 32 is pressed to apply a force F1, so that a rotational force (torque) T1 is applied to the pump side retainer 32 at the point of application PA.

  When such a dedicated tool 90 is used, in order to reduce the force F1 applied to the force point PF, the distance D2 between the fulcrum FL and the force point PF is relatively compared with the distance D1 between the fulcrum FL and the action point PA. It is preferable to make it long. However, the distance D1 between the fulcrum FL and the action point PA is determined in advance according to the size of the pump side retainer 32, and since this distance D1 cannot be shortened, the force point PF is inevitably set at a farther position. There is a need. However, in practice, it is difficult to increase the size of the dedicated tool 90 and set the force point PF at a distant position because of the space inside the vehicle body or the relationship with other members. There are limits.

  On the other hand, in this embodiment, as can be seen from FIG. 11B, the lower end of the general-purpose tool 76 is the fulcrum FL, the middle portion is the action point PA, and the upper end portion is the force point PF. Here, as compared with the structure of the comparative example, the distance D1 between the fulcrum FL and the action point PA is set to be short, so even if the position of the force point PF is close to the fulcrum FL, the action point PA is moved to the pump side retainer 32. The acting rotational force (torque) T1 becomes relatively large. That is, even if the force F1 applied to the force point PF is small, a large rotational force (torque) T1 can be secured and the pump side retainer 32 can be rotated.

  As shown in FIG. 7, when the pump side retainer 32 rotates in the tightening direction, the induction taper surface 56 contacts the tank side engaging portion 66 at the initial stage of rotation, and the horizontal portion 52 of the engaging piece 48 is guided downward. Is done. Thereafter, the front portion 52F of the horizontal portion 52 of the retainer side engaging portion 54 comes into contact with the tip (lower end) portion of the tank side engaging portion 66, but sufficient rotational force (torque in the tightening direction of the pump side retainer 32). Therefore, the pump side retainer 32 can be continuously rotated in the tightening method. The first tapered surface 68 of the retainer side engaging portion 54 comes into contact with the first tapered surface 68 of the tank side engaging portion 66.

  In this state, the general-purpose tool 76 is removed from the insertion hole 72A, and this time is replaced with the insertion hole 72B, and the tip is held in the holding hole 74B. That is, in this state, the insertion hole 72B approaches the holding hole 74B so that the inclination angle of the general-purpose tool 76 that is inserted into the insertion hole 72B and whose tip is held in the holding hole 74B is about 25 degrees. Yes. Then, when the general-purpose tool 76 is rotated in the direction of the arrow R3 with the tip as a fulcrum FL, the pump side retainer 32 rotates in the tightening direction, and the retainer side engaging portion 54 gets over the tank side engaging portion 66, and the pump The side retainer 32 is engaged with the tank side lock ring 62.

  In this state, the general-purpose tool 76 is removed from the insertion hole 72B, and this time is replaced with the insertion hole 72C, and the tip is held in the holding hole 74C (inserted so that the inclination angle of the general-purpose tool 76 is about 25 degrees). The hole 72C is close to the holding hole 74C). Then, the general-purpose tool 76 is rotated in the direction of the arrow R3 with the tip as a fulcrum, and the retainer side engaging portion 54 is moved further in the tightening direction than the tank side engaging portion 66. At this time, the rear portion 52R of the horizontal portion 52 of the retainer side engaging portion 54 comes into contact with the tip (lower end) portion of the tank side engaging portion 66, but the pump side retainer 32 is sufficiently engaged in the tightening direction. Since the rotational force (torque) can be applied, the pump side retainer 32 can be continuously rotated in the tightening method.

  Thus, the fuel pump module 16 is attached to the fuel tank 14 in a state where the pump side retainer 32 is rotated in the tightening direction and the retainer side engaging portion 54 and the tank side engaging portion 66 are engaged.

  When removing the fuel pump module 16 from the fuel tank 14, the reverse operation is performed. That is, first, when the general-purpose tool 76 is inserted into the insertion hole 72C and held in the holding hole 74C, the upper portion of the general-purpose tool 76 is inclined in the tightening direction side. Then, by rotating the general-purpose tool 76 in the arrow R4 direction, the pump side retainer 32 is rotated in the loosening direction. Thereafter, the general-purpose tool 76 is sequentially inserted into the insertion hole 72B and the insertion hole 72A, the general-purpose tool 76 is rotated in the direction of the arrow R4, and the pump-side retainer 32 is rotated in the loosening direction.

  Thus, in this embodiment, even when the pump side retainer 32 is rotated in any direction, a set of a plurality of insertion holes 72 and holding holes 74 having different phase differences is set, and the pump side retainer 32 is set in accordance with the position. Thus, the general-purpose tool 76 is sequentially inserted into the insertion hole 72 to rotate the pump side retainer 32 little by little. For example, even when the engaging force between the retainer side engaging portion 54 and the tank side engaging portion 66 is set high, the pump side retainer 32 can be reliably rotated. In particular, in the present embodiment, the positional relationship between the corresponding insertion hole 72 and the holding hole 74 is set to a position where the inserted general-purpose tool 76 rotates within a range of an inclination angle of about 25 degrees. Therefore, the pump-side retainer 32 can be rotated more easily than the configuration in which the general-purpose tool 76 is rotated in the direction of the arrow R3 (see FIGS. 7 to 9) in a state where the inclination angle of the general-purpose tool 76 is larger than this.

  In addition, the general-purpose tool 76 can be used to rotate the pump side retainer 32, and the dedicated tool 90 (see FIG. 11A) is not necessary, so that the work load on the operator is reduced.

  The pump side retainer 32 of the present embodiment is formed with a rising wall 36 and a bead 40, and the rigidity is improved. Therefore, the member mounting structure 12, that is, the fuel pump module 16 is mounted on the fuel tank 14. The state can be reliably maintained. Further, since the rigidity is improved in this way, inadvertent deformation is suppressed even when the pump side retainer 32 is rotated in the tightening direction or the loosening direction.

  By the way, since the pump side retainer 32 is formed in an annular shape, for example, assuming a shape in which the concave portion 44 according to the present embodiment is not configured, in such a pump side retainer, on the inside thereof, at the time of car wash Liquid L such as cleaning water may accumulate. In particular, when the annular rising wall 36 is formed, the amount of the liquid L that accumulates on the inside increases. However, a recess 44 is formed in the pump side retainer 32 of the present embodiment, and a flow path 46 is formed between the sandwiching surface 34 and the support surface 22. Therefore, the liquid L is indicated by the arrow LF through the flow path 46 without retaining the liquid L in the radially inner portion of the pump side retainer 32 without particularly performing the operation of discharging the liquid L. Discharged.

  In the above embodiment, the bead 40 is formed in the pump side retainer 32 to form the recess 44 in the sandwiching surface 34 to ensure drainage. From the viewpoint of securing the drainage in this way. In short, it suffices if the recess 44 is formed. For example, as shown in FIG. 12, a structure in which only the concave portion 44 is formed on the sandwiching surface 34 (the bead 40 is not formed and the convex portion 42 is not provided) may be employed. Of course, it is preferable to form the bead 40 as in the above embodiment because the rigidity of the pump side retainer 32 can be improved with a simple structure.

  The recess 44 does not need to reach the outer peripheral end of the pump side retainer 32, and as can be seen from FIG. 2, the pump side retainer is provided as long as it is continuous to the outer peripheral side of the flange portion 30 that is a mounted member. A flow path 46 through which the liquid L is discharged from the radially inner portion of 32 can be configured.

  In the above embodiment, the insertion hole 72 of the pump side retainer 32 and the holding hole 74 of the tank side lock ring 62 are dispersed in the circumferential direction of the pump side retainer 32 and the tank side lock ring 62, and the same number is provided. However, in short, if the pump side retainer 32 can be rotated in the tightening direction and the loosening direction with respect to the tank side lock ring 62 using the general-purpose tool 76, it is inserted. The positions and numbers of the holes 72 and the holding holes 74 are not limited, and it is not necessary that these numbers match. In other words, as the action set according to the present invention, a plurality of action sets may be configured by selectively disposing a plurality of holding holes 74 with respect to one insertion hole 72, and conversely, A plurality of action groups may be configured by selectively arranging a plurality of insertion holes 72 with respect to one holding hole 74. A configuration in which a plurality of action sets are provided by providing a plurality of insertion holes 72 and a plurality of holding holes 74 and selecting one of the insertion holes 72 and one of the holding holes 74 from among them is also possible. .

  For example, in the example shown in FIG. 13, a plurality of (four in the illustrated example) insertion holes 72 are formed at one circumferential position of the pump side retainer 32, and only one holding hole 74 corresponding to this is formed. doing. In the example shown in FIG. 14, a plurality of (three in the illustrated example) insertion holes 72 are formed in each of a plurality of circumferential positions (three in the illustrated example) of the pump side retainer 32. In the example shown in FIGS. 13 and 14, a plurality of holding holes 74 may be formed instead of the insertion holes 72 or a plurality of positions.

  Furthermore, the shape of the insertion hole 72 is not particularly limited as long as the general-purpose tool 76 can be inserted, and may be an elliptical hole or a polygonal hole in addition to a circular hole. . The action point member of the present invention does not need to have the above-described hole shape, and may be a notch 78 having a shape that opens toward the outer peripheral side of the pump side retainer 32 as shown in FIG.

  The fulcrum member of the present invention does not need to have a hole shape like the above-described holding hole 74. In short, the tip of the general-purpose tool 76 is held by holding the tip of the general-purpose tool 76 and restricting movement in the circumferential direction. Can be used as a fulcrum of rotation. For example, as shown in FIG. 16, it may be a vertical wall 80 erected upward from the tank side lock ring 62. That is, the tip of the general-purpose tool 76 can be applied to and held by the root portion of the vertical wall 80. In addition, the notch 78 and the vertical wall 80 may be used in combination.

  In the above description, the general-purpose tool 76 can be inserted into the insertion hole 72 from the opposite side of the clamping surface 34. For example, the general-purpose tool 76 is moved from the radially outer side of the pump side retainer 32 toward the radially inner side. It may be the position of the insertion hole 72 and the holding hole 74 to be inserted. It is preferable that the general-purpose tool 76 can be inserted into the insertion hole 72 from the opposite side of the clamping surface 34 toward the fuel tank 14 as in the above-described embodiment, because workability is improved.

  The attached member according to the present invention is not limited to the flange portion 30 of the fuel tank module 16 described above, and may be a member attached to the upper surface of the fuel tank 14.

12 Member mounting structure 14 Fuel tank 16 Fuel pump module 30 Flange (attached member)
32 Pump side retainer (mounting member)
34 sandwiching surface 36 rising wall 40 bead 42 convex portion 44 concave portion 46 channel 48 engaging piece 54 retainer side engaging portion (engaging portion)
62 Tank-side lock ring 64 Slot for locking 66 Tank-side engaging portion (member to be engaged)
72 Insertion hole (working point member)
74 Holding hole (fulcrum member)
76 General-purpose tool 80 Vertical wall (fulcrum member)
90 Special tool L Liquid

Claims (5)

An attachment member having a sandwiching surface that is formed in an annular shape and sandwiches a member to be attached disposed on the upper surface of the fuel tank with the surface of the fuel tank;
The mounting member is provided with a vertical portion formed at the outer peripheral end of the mounting member, and is engaged with the engaged member of the fuel tank in a state where the sandwiching surface is in contact with the mounted member. An engaging portion for fixing;
A bead provided with a convex portion that is formed on a surface opposite to the sandwiching surface of the mounting member and that is convexly continuous from an inner peripheral end of the sandwiching surface to the vertical portion;
A concave portion formed on the clamping surface of the mounting member so as to continue from the inner peripheral end to the vertical portion at a position corresponding to the convex portion, and partially spaced from the mounted member;
A member mounting structure to a fuel tank. 2. The member attachment to the fuel tank according to claim 1 , wherein an annular rising wall is formed on an inner periphery of the attachment member so as to rise in a direction away from the attached member than a surface opposite to the sandwiching surface. Construction. A fulcrum member that is formed on the attached member and restricts the movement of the tip of the tool in the circumferential direction of the attachment member and uses the tip of the tool as a fulcrum of rotation;
It is formed on the mounting member so that the longitudinal intermediate portion of the tool whose movement of the tip is restricted by the fulcrum member contacts, and the rotation force of the mounting member in the circumferential direction acts on the mounting member by the rotation of the tool. An action point member for causing
The member attachment structure to the fuel tank according to claim 1 or claim 2 , wherein The member attachment structure to the fuel tank according to claim 3 , wherein the action point member is formed so as to penetrate the attachment member from a surface opposite to the sandwiching surface to the sandwiching surface. The fulcrum member and the working set for applying a rotational force of said configured by the action point member in the circumferential direction on the mounting member, circumferentially different phase differences become as claimed in claim 3 or claims provided with a plurality Item 5. A member mounting structure to a fuel tank according to Item 4 .

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