JP2021110265A - Fuel supply device - Google Patents

Abstract

To provide a fuel supply device that can restrain an increase in size.SOLUTION: A fuel supply device comprises a flange member, a fuel pump, a case body, and a pressure regulating valve. A discharge port and a pair of power supply terminals are formed in an upper part of the fuel pump. A first fuel passage arranged above the fuel pump and extending linearly, and a second fuel passage connected to one end part of the first fuel passage are formed inside the case body. The pressure regulating valve is provided at the other end part of the first fuel passage. When a plane including both a first central axis and a second central axis is defined as a first plane, one of the pair of power supply terminals is arranged on one side of the first plane, and the other of the pair of power supply terminals is arranged on the other side of the first plane.SELECTED DRAWING: Figure 2

Description

The present disclosure relates to a fuel supply device including a fuel pump that is inserted into the fuel tank through an opening formed in the bottom surface of the fuel tank.

Patent Document 1 describes a fuel supply device attached to the bottom of a fuel tank. This fuel supply device includes a lid member that covers the opening of the fuel tank, and a fuel pump that is arranged on the lid member. A fuel piping section is connected to the fuel discharge port of the fuel pump. A pressure regulator is incorporated in the fuel piping section.

Japanese Patent No. 5992366

In the fuel supply device of Patent Document 1, two terminals to which two harnesses are connected are provided on the upper surface of the fuel pump. Above each terminal, it is necessary to secure a space for connecting the harness. Therefore, in the fuel supply device of Patent Document 1, the fuel piping portion incorporating the pressure regulator is arranged so as to avoid directly above the fuel pump. In such a case, it is difficult to arrange the fuel pump and the fuel pipe portion in which the pressure regulator is incorporated so as to overlap each other when viewed in the axial direction, so that the fuel supply device is particularly large in the radial direction. There was a problem that it became easy to become.

The present disclosure has been made in order to solve the above-mentioned problems, and an object of the present disclosure is to provide a fuel supply device capable of suppressing an increase in size.

The fuel supply device according to the present disclosure includes a flange member attached to an opening formed on the bottom surface of the fuel tank, a fuel pump supported by the flange member and inserted into the fuel tank through the opening, and the fuel pump. A case body covering at least a part above the fuel pump and a pressure adjusting valve provided on the discharge side of the fuel pump are provided, and a discharge port and a pair of power supply terminals are formed on the upper portion of the fuel pump. Inside the case body, a first fuel passage arranged above the fuel pump and extending linearly, and one end of the first fuel passage are connected to the flange member. An extended second fuel passage is formed, and the first central axis, which is the central axis of the fuel pump, and the second central axis, which is the central axis of the first fuel passage, intersect each other. , The pressure adjusting valve is provided at the other end of the first fuel passage, and the discharge port is a connection provided between the one end and the other end of the first fuel passage. When the plane including both the first central axis and the second central axis is the first plane, one of the pair of power feeding terminals is arranged on one side of the first plane. The other of the pair of power feeding terminals is arranged on the other side of the first plane.

According to the present disclosure, it is possible to suppress an increase in the size of the fuel supply device.

It is a side view which shows the structure of the fuel supply apparatus which concerns on Embodiment 1. FIG. It is a top view which shows the structure of the fuel supply apparatus which concerns on Embodiment 1. FIG. It is a partial cross-sectional view which shows the III-III cross section of FIG. It is a perspective view which shows the structure of the fuel pump of the fuel supply device which concerns on Embodiment 1. FIG. It is a side view which shows the structure which looked at the fuel supply apparatus which concerns on Embodiment 1 along the V direction of FIG. It is a bottom view which shows the structure of the fuel supply apparatus which concerns on Embodiment 1. FIG.

Embodiment 1.
The fuel supply device according to the first embodiment will be described. FIG. 1 is a side view showing a configuration of a fuel supply device according to the present embodiment. FIG. 2 is a top view showing the configuration of the fuel supply device according to the present embodiment. FIG. 3 is a partial cross-sectional view showing a section III-III of FIG. Here, the cross section shown in FIG. 3 corresponds to a cross section obtained by cutting the fuel supply device on the first plane P1 described later. In FIG. 3, an example of fuel flow is represented by an arrow. FIG. 4 is a perspective view showing the configuration of the fuel pump 20 of the fuel supply device according to the present embodiment. FIG. 5 is a side view showing a configuration of the fuel supply device according to the present embodiment as viewed along the V direction of FIG. FIG. 6 is a bottom view showing the configuration of the fuel supply device according to the present embodiment. In the present embodiment, the vertical directions of FIGS. 1 and 3 to 5 represent vertical vertical directions.

The fuel supply device according to the present embodiment supplies fuel in the fuel tank to a fuel consuming device such as an engine. As particularly shown in FIGS. 1 to 5, the fuel supply device includes a fuel pump 20, a suction filter 10, and a pressure regulating valve 30. The fuel pump 20 is configured to suck in the fuel in the fuel tank, pressurize the sucked fuel, and discharge the fuel. The suction filter 10 is provided on the suction side of the fuel pump 20, that is, on the upstream side of the fuel pump 20 in the flow of fuel. The suction filter 10 is configured to remove impurities floating in the fuel sucked into the fuel pump 20. The pressure regulating valve 30 is provided on the discharge side of the fuel pump 20, that is, on the downstream side of the fuel pump 20 in the flow of fuel. The pressure adjusting valve 30 is configured to adjust the pressure on the discharge side of the fuel pump 20 and return the fuel not consumed by the fuel consuming device into the fuel tank.

In the present embodiment, as the fuel supply device, a fuel supply device for a vehicle, particularly a fuel supply device for a motorcycle is exemplified. The fuel supply device for a motorcycle is inserted into the fuel tank through an opening formed in the bottom surface of the fuel tank due to structural restrictions of the vehicle body, and is installed so as to stand up from the bottom surface of the fuel tank. The fuel supply device of the present embodiment has a flange member 40 attached to the opening of the fuel tank, and a case body 50 arranged above the flange member 40, that is, inside the fuel tank. Each of the flange member 40 and the case body 50 is formed by integral molding using a thermoplastic resin such as POM (PolyOxyMethylene). The lower part of the case body 50 is connected to the upper part of the flange member 40. The housing 60 of the fuel supply device is formed by connecting the flange member 40 and the case body 50. The suction filter 10, the fuel pump 20, and the pressure regulating valve 30 are supported by the housing 60.

The flange member 40 has a flat plate portion 41, a cup portion 42, a fuel storage wall 43, a discharge pipe 44, and a power supply connector 45. The flat plate portion 41, the cup portion 42, the fuel storage wall 43, the discharge pipe 44, and the power supply connector 45 are integrally formed by integral molding using a thermoplastic resin.

The flat plate portion 41, together with the cup portion 42, functions as a lid portion that closes the opening of the fuel tank. When the fuel supply device is attached to the fuel tank, the upper surface 41a of the flat plate portion 41 faces the inside of the fuel tank, and the lower surface 41b of the flat plate portion 41 faces the outside of the fuel tank. The outer peripheral portion of the flat plate portion 41 projects radially outward over the entire circumference so as to serve as a flange fixed to the opening of the fuel tank. The outer edge 41c, which is the outer peripheral end of the flat plate portion 41, is formed in a circular shape in a plan view.

The cup portion 42 is formed on the inner peripheral side of the flat plate portion 41. The cup portion 42 has a shape that bulges downward with respect to the flat plate portion 41. The cup portion 42 is formed in a cup shape with an opening at the upper side. The cup portion 42 has a tubular side wall 42a and a bottom portion 42b that closes the lower end of the side wall 42a. The side wall 42a is formed substantially perpendicular to the flat plate portion 41.

The fuel storage wall 43 is formed on the outer peripheral side of the fuel pump 20 and the suction filter 10. The fuel storage wall 43 has the same shape as the side wall 42a of the cup portion 42 when viewed from above. The fuel storage wall 43 has a shape that rises upward in a tubular shape from the open end of the cup portion 42, that is, the boundary between the side wall 42a of the cup portion 42 and the flat plate portion 41. The fuel storage wall 43 is formed substantially perpendicular to the flat plate portion 41. The fuel storage wall 43 and the cup portion 42 are integrated to form a tubular body in which the lower end is closed and the upper end is open. A part of the fuel in the fuel tank is stored in the internal space of the fuel storage wall 43 and the cup portion 42. That is, the fuel storage wall 43 and the cup portion 42 function as a sub tank provided in the fuel tank. The fuel storage wall 43 also has a function of supporting the case body 50.

Further, the lower part of the fuel pump 20 and the lower part of the suction filter 10 are housed in the internal spaces of the fuel storage wall 43 and the cup portion 42. The upper part of the fuel pump 20 and the upper part of the suction filter 10 are located above the upper end 43a of the fuel storage wall 43.

The discharge pipe 44 is formed so as to penetrate the flat plate portion 41. The discharge pipe 44 is provided on the outer peripheral side of the fuel storage wall 43 and the cup portion 42. The discharge pipe 44 includes an upper pipe 44a protruding upward from the upper surface 41a of the flat plate portion 41, a lower pipe 44b protruding downward from the lower surface 41b of the flat plate portion 41, and the upper pipe 44a and the lower pipe penetrating the flat plate portion 41. It has a penetrating portion 44c that connects the 44b. The upper pipe 44a projects from the upper surface 41a in a direction substantially perpendicular to the flat plate portion 41. The lower pipe 44b protrudes from the lower surface 41b in a direction substantially perpendicular to the flat plate portion 41, is bent in an L shape, and extends in a direction parallel to the flat plate portion 41. The pipeline in the discharge pipe 44 constitutes a part of the discharge flow path through which the fuel discharged from the fuel pump 20 flows.

The power supply connector 45 is formed so as to straddle the upper surface 41a side and the lower surface 41b side of the flat plate portion 41. The power supply connector 45 is provided on the outer peripheral side of the fuel storage wall 43 and the cup portion 42. The power supply connector 45 has a plurality of terminals 46 including a terminal for power supply connected to the fuel pump 20 and a terminal for a sensor signal connected to a fuel level sensor (not shown). Each terminal 46 penetrates from the upper surface 41a side to the lower surface 41b side. The electric power for driving the fuel pump 20 in the fuel tank is supplied from outside the fuel tank via the power supply connector 45. The output signal from the fuel level sensor in the fuel tank is output to the outside of the fuel tank via the power supply connector 45.

The fuel pump 20 has a cylindrical housing 21 having a top surface 21a and a bottom surface 21b. The fuel pump 20 is provided upright in the cup portion 42 and is supported by the flange member 40. The first central axis Lz, which is the central axis of the fuel pump 20, is substantially perpendicular to the flat plate portion 41. A suction port 22 for sucking fuel is formed in the lower part of the housing 21, for example, the bottom surface 21b. The suction port 22 is connected to the suction filter 10. Although not shown, the inside of the housing 21 houses a pump unit that pressurizes the fuel sucked from the suction port 22 and a motor unit that drives the pump unit. A discharge port 23 for discharging the fuel pressurized by the pump portion is formed on the upper portion of the housing 21, for example, the upper surface 21a. The discharge port 23 is provided at a position deviated from the first central axis Lz. The discharge port 23 is formed in a cylindrical shape, and is provided upward so as to face a direction parallel to the first central axis Lz.

A pair of power supply terminals 24a and 24b for supplying electric power to the motor portion of the fuel pump 20 are formed on the upper portion of the housing 21, for example, the upper surface 21a, so as to project upward. The power supply terminal 24a and the power supply terminal 24b have different polarities from each other. For example, the power supply terminal 24a is a positive electrode terminal, and the power supply terminal 24b is a negative electrode terminal. The power supply terminal 24a and the power supply terminal 24b are electrically connected to the power supply terminal of the power supply connector 45 via a wire harness. The power supply terminal 24a and the power supply terminal 24b are arranged below the first fuel passage 51 and the cylindrical portion 50a, which will be described later. When viewed along the first central axis Lz, both the power feeding terminal 24a and the power feeding terminal 24b overlap with the cylindrical portion 50a.

The case body 50 is provided so as to cover at least a part of the fuel pump 20 and above the upper pipe 44a, and is supported by the flange member 40. A first fuel passage 51, a second fuel passage 52, and a connecting passage 53 are formed inside the case body 50. The case body 50 is integrally formed by integral molding using a thermoplastic resin.

The first fuel passage 51 is arranged above the fuel pump 20 and extends linearly. The second central axis Lx, which is the central axis of the first fuel passage 51, is orthogonal to the first central axis Lz, which is the central axis of the fuel pump 20. The first fuel passage 51 passes on the axis of the first central axis Lz and extends in a direction perpendicular to the first central axis Lz. The first fuel passage 51 is a part of the case body 50 and is defined by a cylindrical portion 50a having a cylindrical shape. In the present embodiment, the first central axis Lz and the second central axis Lx are orthogonal to each other, but the first central axis Lz and the second central axis Lx intersect at an angle other than 90 °. May be good.

The first fuel passage 51 is formed between one end portion 51a located on one end side in the stretching direction, the other end portion 51b located on the other end side in the stretching direction, and one end portion 51a and the other end portion 51b. It has a connecting portion 51c and. In the connecting portion 51c, the first fuel passage 51 and the connecting passage 53 are connected in a T shape. The connecting portion 51c of the first fuel passage 51 is connected to the discharge port 23 of the fuel pump 20 via the connecting passage 53.

The connection passage 53 extends in a direction parallel to the first central axis Lz so as to be coaxial with the discharge port 23 of the fuel pump 20. The upper end of the connection passage 53 is connected to the connection portion 51c. The lower end of the connecting passage 53 is open to the lower surface of the case body 50. The open end formed on the lower surface of the case body 50 is connected to the discharge port 23 of the fuel pump 20 by using the seal member 70. The seal member 70 is in close contact with both the inner peripheral surface of the open end of the case body 50 and the outer peripheral surface of the discharge port 23. As a result, the fuel pump 20 and the case body 50 are liquid-tightly coupled.

The second fuel passage 52 is connected to one end portion 51a of the first fuel passage 51, and extends linearly downward from the one end portion 51a toward the flange member 40. The extension direction of the second fuel passage 52 is, for example, parallel to the first central axis Lz. The lower end side of the second fuel passage 52 is formed in the cylindrical portion 54 which is a part of the case body 50. The cylindrical portion 54 is connected to the upper pipe 44a of the flange member 40 by using the sealing member 71. The seal member 71 is in close contact with both the inner peripheral surface of the cylindrical portion 54 and the outer peripheral surface of the upper pipe 44a. As a result, the case body 50 and the flange member 40 are liquid-tightly coupled.

The other end 51b of the first fuel passage 51 is open to the side surface of the case body 50. A pressure adjusting valve 30 is connected to the open end formed on the side surface of the case body 50 by using a sealing member 72. The seal member 72 is in close contact with both the inner peripheral surface of the open end of the case body 50 and the outer peripheral surface of the pressure regulating valve 30. As a result, the case body 50 and the pressure regulating valve 30 are liquidtightly coupled.

The pressure regulating valve 30 is fixed to the case body 50 by the holder 31. The pressure regulating valve 30 has a configuration that is axisymmetric. The pressure regulating valve 30 is provided on the axis of the second central axis Lx coaxially with the first fuel passage 51. The pressure regulating valve 30 is arranged so as to be orthogonal to the first central axis Lz.

The pressure regulating valve 30 is a differential pressure valve that opens and closes based on the pressure on the discharge side of the fuel pump 20, that is, the pressure in the first fuel passage 51 and the pressure in the fuel tank. The pressure regulating valve 30 is configured to be normally closed and opened when the differential pressure exceeds a set value. When the pressure regulating valve 30 is opened, a part of the fuel in the first fuel passage 51 is discharged to the fuel tank through the discharge port of the pressure regulating valve 30. The discharge port of the pressure regulating valve 30 is provided on the axis of the second central axis Lx coaxially with the first fuel passage 51.

When the case body 50 is integrally formed by integral molding, the fuel passage inside the case body 50 is formed in an L-shape or a T-shape due to the structure of the mold. When the fuel passage inside the case body 50 is formed in a T shape, a liquid-tight fuel passage is formed by closing an unnecessary opening among the three openings with another part or by welding. Need to form.

In the present embodiment, one end portion 51a of the first fuel passage 51 is liquidtightly connected to the discharge pipe 44 via the second fuel passage 52. The other end 51b of the first fuel passage 51 is liquidtightly connected to the pressure regulating valve 30. The connection passage 53 is liquidtightly connected to the discharge port 23 of the fuel pump 20. Therefore, in the present embodiment, a liquid-tight fuel passage can be formed without adding new parts. Therefore, according to the present embodiment, the number of parts and the assembly man-hours of the fuel supply device can be reduced.

Here, the plane including both the first central axis Lz and the second central axis Lx is referred to as the first plane P1. At this time, the discharge port 23 is arranged on the first plane P1. Further, the connecting portion 51c is arranged on the first plane P1. The power feeding terminal 24a is arranged on one side of the first plane P1. For example, the power supply terminal 24a in FIG. 4 is arranged on the right side of the first plane P1. The power feeding terminal 24b is arranged on the other side of the first plane P1. For example, the power supply terminal 24b in FIG. 4 is arranged on the left side of the first plane P1. That is, the first plane P1 is sandwiched between the power feeding terminal 24a and the power feeding terminal 24b.

Further, a plane including the first central axis Lz and perpendicular to the second central axis Lx is referred to as a second plane P2. At this time, the discharge port 23 and the connecting portion 51c are arranged on one side of the second plane P2. For example, the discharge port 23 and the connection portion 51c in FIG. 3 are arranged on the right side of the second plane P2. The other end 51b of the first fuel passage 51 is arranged on the other side of the second plane P2. For example, the other end 51b in FIG. 3 is arranged on the left side of the second plane P2. That is, the second plane P2 is sandwiched between the discharge port 23 and the other end portion 51b, and is sandwiched between the connection portion 51c and the other end portion 51b.

The case body 50 is supported by the flange member 40 by a fitting structure. The flange member 40 is formed with a first fitting portion 47 that partially protrudes upward from the upper end 43a of the fuel storage wall 43. A fitting protrusion 47a is formed on the outer peripheral surface of the first fitting portion 47. The case body 50 is formed with a second fitting portion 57 that partially protrudes downward so as to overlap the outer peripheral side of the first fitting portion 47. A fitting hole portion 57a into which the fitting protrusion 47a is fitted is formed on the inner peripheral surface of the second fitting portion 57. The fitting hole portion 57a of the present embodiment penetrates from the inner peripheral surface to the outer peripheral surface of the second fitting portion 57. A set of fitting structures is formed by the first fitting portion 47 and the second fitting portion 57. A plurality of sets of fitting structures are provided as needed.

The suction filter 10 is bent so as to have a substantially cylindrical shape. The suction filter 10 is provided upright in the cup portion 42 of the flange member 40 together with the fuel pump 20. When viewed along the first central axis Lz of the fuel pump 20, the suction filter 10 is arranged on the outer peripheral side of the fuel pump 20 and on the inner peripheral side of the fuel storage wall 43 and the side wall 42a. At least the lower part of the suction filter 10 is curved along the inner peripheral surface of the fuel storage wall 43 and the inner peripheral surface of the side wall 42a.

On the other hand, the upper portion of the suction filter 10 is exposed from the fuel storage wall 43. For example, a part of the upper part of the suction filter 10 is located on the outer peripheral side of the case body 50.

The first fitting portion 47 and the second fitting portion 57 are arranged on the outer peripheral side of the suction filter 10 when viewed along the first central axis Lz. As a result, the upper portion of the suction filter 10 exposed from the fuel storage wall 43 is held by at least one of the first fitting portion 47 and the second fitting portion 57.

In the present embodiment, the first fitting portion 47 is formed on the flange member 40 and the second fitting portion 57 is formed on the case body 50, but the first fitting portion 47 is formed on the case body 50. , The second fitting portion 57 may be formed on the flange member 40.

As shown in FIG. 6, the lower surface 41b of the flat plate portion 41 is used for positioning the lower pipe 44b of the discharge pipe 44, the power supply connector 45, and the fuel tank as a structure protruding downward with respect to the flat plate portion 41. The positioning protrusion 48 to be formed is formed.

The cup portion 42 has a first side wall portion 42a1, a second side wall portion 42a2, and a third side wall portion 42a3 as a part of the side wall portion 42a. The first side wall portion 42a1 faces the outer peripheral surface of the power feeding connector 45 at a distance. The first side wall portion 42a1 is formed in a curved surface shape that is concave inside the cup portion 42 along the shape of the outer peripheral surface of the power supply connector 45. The second side wall portion 42a2 faces the outer peripheral surface of the positioning projection 48 at a distance. The second side wall portion 42a2 is formed in a curved surface shape that is concave inside the cup portion 42 along the shape of the outer peripheral surface of the positioning protrusion 48. The third side wall portion 42a3 is aligned with the outer edge 41c of the flat plate portion 41 at a distance. The third side wall portion 42a3 is formed in a cylindrical surface shape that is convex outward along the shape of the outer edge 41c. The first side wall portion 42a1 and the second side wall portion 42a2 are smoothly connected by a flat or curved side wall that is a part of the side wall 42a. Similarly, between the second side wall portion 42a2 and the third side wall portion 42a3, and between the third side wall portion 42a3 and the first side wall portion 42a1, each has a planar or curved surface shape which is a part of the side wall portion 42a. It is smoothly connected by the side wall of.

In this way, the side wall 42a is formed so as to surround a wider range while avoiding a structure protruding downward. As a result, the volume of the cup portion 42 is expanded, so that more fuel can be stored in the internal space of the cup portion 42. Therefore, even when the liquid level of the fuel in the fuel tank is tilted, such as when traveling on a slope, when stopping, or when starting, it is possible to suppress fuel shortage in the fuel supply device. Therefore, according to the present embodiment, the reliability of the fuel supply device can be improved.

Here, the operation of the fuel supply device according to the present embodiment will be described with reference to FIG. When the fuel pump 20 operates, the fuel in the fuel tank is sucked into the fuel pump 20 from the suction port 22 through the suction filter 10. The sucked fuel is pressurized by the pump portion of the fuel pump 20, and is discharged from the fuel pump 20 through the discharge port 23. The discharged fuel flows into the first fuel passage 51 through the connecting passage 53. Since the pressure regulating valve 30 is normally closed, all the fuel that has flowed into the first fuel passage 51 flows to the one end portion 51a side and passes through the second fuel passage 52 and the pipeline in the discharge pipe 44. It is supplied to the engine.

When the amount of fuel supplied from the fuel supply device to the engine increases with respect to the amount of fuel consumed by the engine, the pressure in the first fuel passage 51 rises, so that the pressure regulating valve 30 is opened. As a result, a part of the fuel discharged from the fuel pump 20 flows through the first fuel passage 51 toward the other end 51b side, and is returned into the fuel tank from the pressure adjusting valve 30.

As described above, the fuel supply device according to the present embodiment includes a flange member 40, a fuel pump 20, a case body 50, and a pressure regulating valve 30. The flange member 40 is attached to an opening formed in the bottom surface of the fuel tank. The fuel pump 20 is supported by the flange member 40 and is inserted into the fuel tank through the opening. The case body 50 covers at least a part of the fuel pump 20 above. The pressure regulating valve 30 is provided on the discharge side of the fuel pump 20. A discharge port 23 and a pair of power supply terminals 24a and 24b are formed on the upper portion of the fuel pump 20. A first fuel passage 51 and a second fuel passage 52 are formed inside the case body 50. The first fuel passage 51 is arranged above the fuel pump 20 and extends linearly. The second fuel passage 52 is connected to one end portion 51a of the first fuel passage 51 and extends toward the flange member 40. The first central axis Lz, which is the central axis of the fuel pump 20, and the second central axis Lx, which is the central axis of the first fuel passage 51, intersect each other. The pressure regulating valve 30 is provided at the other end 51b of the first fuel passage 51. The discharge port 23 is connected to a connection portion 51c provided between one end portion 51a and the other end portion 51b of the first fuel passage 51. The plane including both the first central axis Lz and the second central axis Lx is defined as the first plane P1. At this time, one of the pair of power feeding terminals 24a and 24b is arranged on one side of the first plane P1. The other of the pair of power feeding terminals 24a and 24b is arranged on the other side of the first plane P1.

According to this configuration, when viewed along the first central axis Lz, a pair of power feeding terminals 24a and 24b are arranged on both sides of the second central axis Lx of the first fuel passage 51. Therefore, the first fuel passage 51 can be arranged so as to pass above the fuel pump 20 through the first central axis Lz. As a result, the fuel pump 20 and the first fuel passage 51 are arranged so as to overlap each other when viewed along the first central axis Lz, so that the position of the fuel pump 20 is brought closer to the center of the entire fuel supply device. be able to. Therefore, according to the above configuration, since each component of the fuel supply device can be arranged spatially and efficiently, it is possible to suppress an increase in the size of the fuel supply device.

Further, according to the above configuration, when viewed along the first central axis Lz, the pair of power supply terminals 24a and 24b are arranged on both sides of the first fuel passage 51, so that the pair of power supply terminals 24a and 24b It is easy to secure a space for connection work above each of the above. Therefore, when manufacturing the fuel supply device, the wire harness can be easily connected to each of the pair of power supply terminals 24a and 24b even after the flange member 40 and the case body 50 are assembled with the fuel pump 20 sandwiched between them. can do.

In the fuel supply device according to the present embodiment, the plane including the first central axis Lz and perpendicular to the second central axis Lx is defined as the second plane P2. At this time, the discharge port 23 is arranged on one side of the second plane P2. The other end 51b of the first fuel passage 51 is arranged on the other side of the second plane P2.

According to this configuration, the other end 51b of the first fuel passage 51 provided with the pressure adjusting valve 30 can be arranged on the opposite side of the discharge port 23 with the second plane P2 interposed therebetween. Therefore, the pressure regulating valve 30 can be spatially and more efficiently arranged above the fuel pump 20. Therefore, according to the above configuration, it is possible to further suppress the increase in size of the fuel supply device.

The fuel supply device according to the present embodiment further includes a suction filter 10 provided on the suction side of the fuel pump 20. The flange member 40 has a fuel storage wall 43 formed on the outer peripheral side of the fuel pump 20. The lower portion of the suction filter 10 is arranged on the outer peripheral side of the fuel pump 20 and on the inner peripheral side of the fuel storage wall 43. One of the case body 50 and the flange member 40 has a first fitting portion 47 on which a fitting protrusion 47a is formed. The other side of the case body 50 and the flange member 40 has a second fitting portion 57 in which a fitting hole portion 57a into which the fitting protrusion 47a is fitted is formed. The first fitting portion 47 and the second fitting portion 57 are arranged on the outer peripheral side of the suction filter 10.

In this configuration, the lower portion of the suction filter 10 is arranged on the outer peripheral side of the fuel pump 20 and on the inner peripheral side of the fuel storage wall 43. Therefore, the shape of the suction filter 10 can be maintained by the fuel pump 20 and the fuel storage wall 43 without using a filter holding member separately. For example, when the suction filter 10 is provided in a partially cylindrically bent state, the suction filter 10 can be prevented from opening in a flat plate shape by the fuel pump 20 and the fuel storage wall 43. Further, in the above configuration, the first fitting portion 47 and the second fitting portion 57 are arranged on the outer peripheral side of the suction filter 10. Therefore, it is possible to prevent the suction filter 10 from being tilted in the vertical direction by the first fitting portion 47 or the second fitting portion 57 without using a filter holding member separately. Therefore, according to the above configuration, it is possible to suppress deformation and inclination of the suction filter 10 while suppressing an increase in the number of parts of the fuel supply device.

In the fuel supply device according to the present embodiment, the flange member 40 has a flat plate portion 41, a cup portion 42, a power supply connector 45, and a positioning protrusion 48. The cup portion 42 is formed on the inner peripheral side of the flat plate portion 41 and has a shape that bulges downward. The power supply connector 45 is formed on the flat plate portion 41 and is electrically connected to the pair of power supply terminals 24a and 24b. The positioning protrusion 48 is formed on the lower surface of the flat plate portion 41 and is used for positioning with respect to the fuel tank. The cup portion 42 has a first side wall portion 42a1, a second side wall portion 42a2, and a third side wall portion 42a3. The first side wall portion 42a1 faces the outer peripheral surface of the power supply connector 45 at a distance, and is recessed inside the cup portion 42 along the shape of the outer peripheral surface of the power supply connector 45. The second side wall portion 42a2 faces the outer peripheral surface of the positioning protrusion 48 at a distance, and is concave inside the cup portion 42 along the shape of the outer peripheral surface of the positioning protrusion 48. The third side wall portion 42a3 extends along the outer edge 41c of the flat plate portion 41 at a distance, and is convex to the outside of the cup portion 42 along the shape of the outer edge 41c of the flat plate portion 41.

According to this configuration, since the volume of the cup portion 42 can be expanded, more fuel can be stored in the internal space of the cup portion 42. As a result, even when the liquid level of the fuel in the fuel tank is tilted, it is possible to suppress the fuel shortage in the fuel supply device. Therefore, according to the above configuration, the reliability of the fuel supply device can be improved.

10 suction filter, 20 fuel pump, 21 housing, 21a top surface, 21b bottom surface, 22 suction port, 23 discharge port, 24a, 24b power supply terminal, 30 pressure control valve, 31 holder, 40 flange member, 41 flat plate part, 41a top surface , 41b lower surface, 41c outer edge, 42 cup part, 42a side wall, 42a1 first side wall part, 42a2 second side wall part, 42a3 third side wall part, 42b bottom part, 43 fuel storage wall, 43a upper end, 44 discharge pipe, 44a upper pipe , 44b lower pipe, 44c penetration, 45 power supply connector, 46 terminal, 47 first fitting part, 47a fitting protrusion, 48 positioning protrusion, 50 case body, 50a cylindrical part, 51 first fuel passage, 51a one end, 51b other end, 51c connection, 52 second fuel passage, 53 connection passage, 54 cylindrical part, 57 second fitting part, 57a fitting hole part, 60 housing, 70, 71, 72 seal member, Lxth 2 central axis, Lz 1st central axis, P1 1st plane, P2 2nd plane.

Claims (4)

A flange member attached to the opening formed on the bottom of the fuel tank,
A fuel pump supported by the flange member and inserted into the fuel tank through the opening.
A case body that covers at least a part of the fuel pump and
A pressure regulating valve provided on the discharge side of the fuel pump and
With
A discharge port and a pair of power supply terminals are formed on the upper part of the fuel pump.
Inside the case body,
A first fuel passage arranged above the fuel pump and extending linearly,
A second fuel passage, which is connected to one end of the first fuel passage and extends toward the flange member, is formed.
The first central axis, which is the central axis of the fuel pump, and the second central axis, which is the central axis of the first fuel passage, intersect each other.
The pressure regulating valve is provided at the other end of the first fuel passage, and is provided.
The discharge port is connected to a connection portion provided between the one end portion and the other end portion of the first fuel passage.
When the plane including both the first central axis and the second central axis is defined as the first plane,
One of the pair of power feeding terminals is arranged on one side of the first plane.
The other of the pair of power feeding terminals is a fuel supply device arranged on the other side of the first plane. When the plane including the first central axis and perpendicular to the second central axis is defined as the second plane,
The discharge port is arranged on one side of the second plane.
The fuel supply device according to claim 1, wherein the other end is arranged on the other side of the second plane. Further provided with a suction filter provided on the intake side of the fuel pump,
The flange member has a fuel storage wall formed on the outer peripheral side of the fuel pump.
The lower part of the suction filter is arranged on the outer peripheral side of the fuel pump and on the inner peripheral side of the fuel storage wall.
One of the case body and the flange member has a first fitting portion on which a fitting protrusion is formed.
The other of the case body and the flange member has a second fitting portion in which a fitting hole portion into which the fitting protrusion is fitted is formed.
The fuel supply device according to claim 1 or 2, wherein the first fitting portion and the second fitting portion are arranged on the outer peripheral side of the suction filter. The flange member is
Flat plate and
A cup portion formed on the inner peripheral side of the flat plate portion and having a shape that bulges downward.
A power supply connector formed on the flat plate portion and electrically connected to the pair of power supply terminals.
A positioning protrusion formed on the lower surface of the flat plate portion and used for positioning with respect to the fuel tank,
Have and
The cup part
A first side wall portion that faces the outer peripheral surface of the power supply connector at a distance and is concave inside the cup portion along the shape of the outer peripheral surface of the power supply connector.
A second side wall portion that faces the outer peripheral surface of the positioning protrusion at a distance and is concave inside the cup portion along the shape of the outer peripheral surface of the positioning protrusion.
A third side wall portion that is convex to the outside of the cup portion along the shape of the outer edge of the flat plate portion at a distance from the outer edge of the flat plate portion, and a third side wall portion.
The fuel supply device according to any one of claims 1 to 3.

Images