JP5818433B2 - Fuel supply device - Google Patents

Description

  The present invention relates to a fuel supply device.

In general, a so-called in-tank type fuel supply device in which a fuel pump is disposed in a fuel tank is used as a fuel supply device for a motorcycle or a four-wheeled vehicle.
The ink tank type fuel supply device has a structure in which a flange unit is arranged at the upper part of the fuel pump and is attached to the upper part of the fuel tank (hereinafter referred to as “superscript type”), and a flange unit at the lower part of the fuel pump. There is a structure (hereinafter referred to as “subscript type”) that is arranged and attached to the bottom of the fuel tank.

Some subordinate type fuel supply devices include a fuel pump, a flange unit disposed at the lower end of the fuel pump and attached to the fuel tank, and an upper cup that covers the fuel pump from the outside.
Here, the subordinate type fuel supply device guides the fuel pumped up by the fuel pump from the bottom wall side of the fuel tank to the outside and pumps it toward the engine. For this reason, a fuel flow path unit including a first flow path pipe and a second flow path pipe for guiding fuel from the upper part of the fuel pump to the bottom wall of the fuel tank is integrally molded outside the upper cup. (For example, refer to Patent Document 1).

  In addition, a pressure regulator is provided above the first flow path pipe disposed outside the upper cup. The pressure regulator is for returning the fuel in the fuel flow path to the fuel tank when excessive pressure is applied in the fuel flow path, and always keeping the fuel pressure in the fuel flow path constant.

JP 2010-116793 A

  By the way, the pressure regulator of patent document 1 is arrange | positioned above the fuel flow path formed in the upper cup. Furthermore, this fuel flow path is arrange | positioned in the outer diameter side rather than the centerline seeing from the axial direction of a fuel pump. For this reason, a pressure regulator may protrude from the outer peripheral surface of an upper cup, and there exists a possibility that the upper cup periphery may enlarge. In particular, as in Patent Document 1, when the pressure regulator is disposed horizontally along the upper surface of the upper cup, the amount of protrusion of the pressure regulator increases, so that the periphery of the upper cup tends to further increase in size.

  Then, this invention makes it a subject to provide the fuel supply apparatus which can suppress an enlargement.

In order to solve the above problems, a fuel supply device according to claim 1 of the present invention is formed in a flange unit attached to an opening on a bottom surface of a fuel tank, a case body attached to the flange unit, and the case body. A mounting portion of the liquid level detector, a fuel pump provided in the case body and discharging fuel in the fuel tank from a fuel discharge port, a fuel flow path through which fuel discharged from the fuel discharge port passes, A pressure regulator that maintains a constant pressure of fuel in the fuel flow path, a discharge port fitting portion to which the fuel discharge port is connected, and a storage portion in which the pressure regulator is held. but with the protruded upper part of the case body, the fuel flow path above the discharge opening engaging portion and the receiving portion are integrally formed, the fuel flow It is characterized in that disposed in the fuel tank interior to the flange unit.

According to the present invention, the discharge port fitting portion to which the fuel discharge port is connected and the accommodating portion in which the pressure regulator is held are formed so as to protrude from the upper portion of the case body. The axial length of the fuel supply device can be reduced as compared with the case where the pressure regulator and the fuel flow path are arranged above the fuel flow path. Furthermore, the protrusion amount to a radial direction can be suppressed by arrange | positioning a discharge port fitting part and an accommodating part on the center axis | shaft of a fuel pump. Therefore, the fuel discharge port, the fuel flow path, and the pressure regulator can be efficiently arranged, and the fuel supply device can be reduced in size and layout.
In addition, when the fuel supply device is inserted and assembled from the fuel tank opening, the pressure regulator and the check valve are protected even if the fuel supply device comes into contact with the periphery of the fuel tank opening or surrounding parts. Similarly, there is no problem when packing and transporting. Furthermore, since the pressure regulator is a precision component that always regulates the fuel pressure with high accuracy, its high-precision fuel pressure adjustment function of the fuel supply device can be maintained over a long period of time by protecting the pressure regulator. .

  In the fuel supply device according to claim 2 of the present invention, the fuel flow path includes a first flow path connected to the fuel discharge port of the fuel pump, a second flow path connected to the pressure regulator, A third flow path formed along the axial direction of the case body and led out of the fuel tank, and the first flow path and the second flow path are arranged in a straight line. It is characterized by.

  According to the present invention, since the first flow path and the second flow path are arranged in a straight line, the mold configuration at the time of molding the fuel flow path can be simplified. Therefore, a low-cost fuel supply device can be provided.

The fuel supply apparatus according to claim 3 of the present invention is characterized in that the discharge port fitting portion, the accommodating portion, and the fuel flow path are provided on the same center line of the fuel pump. .
According to the present invention, the fuel can be guided to the outside of the fuel tank by connecting the pressure regulator, the fuel discharge port, and the fuel flow path through the shortest path. For this reason, protrusion from the outer peripheral surface of the fuel pump of a fuel discharge port, a fuel flow path, and a pressure regulator can further be suppressed. Therefore, the fuel supply device can be reduced in size and layout.

The fuel supply apparatus according to claim 4 of the present invention is characterized in that the discharge port fitting portion, the accommodating portion, and the fuel flow path are connected to each other by a wall portion.
According to the present invention, the discharge port fitting portion, the housing portion, and the fuel flow path can be reinforced by connecting the wall portion with the discharge port fitting portion, the housing portion, and the fuel flow path. Stiffness can be increased.

According to a fifth aspect of the present invention, the fuel supply device includes a pair of motor terminals for supplying power to the fuel pump on the upper wall surface side of the case body of the fuel pump, An opening capable of exposing the motor terminal to the outside is formed at a position corresponding to the pair of motor terminals.
ADVANTAGE OF THE INVENTION According to this invention, a pair of motor terminal can be arrange | positioned effectively using the dead space formed in the upper wall of a case body, and size reduction and layout property of a fuel supply apparatus can be improved.

The fuel supply apparatus according to claim 6 of the present invention is characterized in that the pair of motor terminals and the opening are arranged on both sides of the center line of the fuel pump.
ADVANTAGE OF THE INVENTION According to this invention, a pair of motor terminal can be arrange | positioned effectively using the dead space formed in the upper wall of a case body, and size reduction and layout property of a fuel supply apparatus can be improved.

According to the present invention, the discharge port fitting portion to which the fuel discharge port is connected and the accommodating portion in which the pressure regulator is held are formed so as to protrude from the upper portion of the case body. The axial length of the fuel supply device can be reduced as compared with the case where the pressure regulator and the fuel flow path are arranged above the fuel flow path. Furthermore, the protrusion amount to a radial direction can be suppressed by arrange | positioning a discharge port fitting part and an accommodating part on the center axis | shaft of a fuel pump. Therefore, the fuel discharge port, the fuel flow path, and the pressure regulator can be efficiently arranged, and the fuel supply device can be reduced in size and layout.
In addition, when the fuel supply device is inserted and assembled from the fuel tank opening, the pressure regulator and the check valve are protected even if the fuel supply device comes into contact with the periphery of the fuel tank opening or surrounding parts. Similarly, there is no problem when packing and transporting. Furthermore, since the pressure regulator is a precision component that always regulates the fuel pressure with high accuracy, its high-precision fuel pressure adjustment function of the fuel supply device can be maintained over a long period of time by protecting the pressure regulator. .

It is a perspective view of a fuel supply apparatus. It is a top view of a fuel supply device when it sees from the central axis direction of a fuel pump. It is sectional drawing along the AA line of FIG.

Below, the fuel supply apparatus of embodiment is demonstrated with reference to drawings.
The in-tank type fuel supply device has a structure in which a flange unit is arranged at the upper part of the fuel pump and is attached to the upper part of the fuel tank (hereinafter referred to as “upper type”), and the flange unit is attached to the lower part of the fuel pump. There is a structure (hereinafter referred to as “substituting type”) that is arranged in the bottom and is attached to the bottom of the fuel tank. In the embodiment, a subscript type will be described as an example. Further, the relative position in the axial direction of the fuel pump is simply expressed as the upper side and the lower side.

(Fuel pump)
FIG. 1 is a perspective view of the fuel supply device 1.
FIG. 2 is a plan view of the fuel supply device 1 when viewed from the central axis direction of the fuel pump 3.
3 is a cross-sectional view taken along line AA in FIG.
As shown in FIGS. 1 to 3, the fuel supply device 1 of the present embodiment is disposed in a fuel tank 2 (see FIG. 3) and pumps up fuel in the fuel tank 2 and pumps it to an internal combustion engine. 3 is provided. The fuel pump 3 is formed in a substantially cylindrical shape, and includes a motor unit 30 disposed on the upper side of the fuel pump 3 and a pump unit 40 disposed on the lower side of the fuel pump 3. The outer peripheral surface of the fuel pump 3 is formed by a cylindrical housing made of, for example, metal.

(Motor part)
For the motor unit 30, for example, a DC motor with a brush (not shown) is used. On the upper side of the motor unit 30, a pair of motor terminals 32 electrically connected to the brush are erected along the central axis C on the upper side of the fuel pump 3.
As shown in FIG. 2, the pair of motor terminals 32 are arranged on both sides of the center axis C of the fuel pump 3. Specifically, each motor terminal 32 is arranged in the vicinity of the outer peripheral surface of the fuel pump 3 symmetrically with respect to the central axis C. Thereby, a sufficient separation distance can be secured between the motor terminals 32. Note that one side of the harness 6 is connected to the pair of motor terminals 32. The external power source and the motor unit 30 are electrically connected by the harness 6, and electric power for driving the motor unit 30 is supplied from the external power source.

(Pump part)
For example, a non-volumetric pump having an impeller (not shown) is used as the pump unit 40, and the impeller is driven by the motor unit 30. A suction port (not shown) for sucking fuel is provided below the pump unit 40. The suction port is a reservoir formed below the fuel pump 3 via a filter discharge pipe 51 (to be described later), a filter unit (not shown) separate from the fuel supply device 1, and a filter introduction pipe (not shown). It communicates with the section 11 (see FIG. 3). A discharge port for discharging fuel is provided on the upper side of the pump unit 40. The fuel pump 3 pumps the fuel stored in the reservoir unit 11 from the suction port of the pump unit 40 through the filter discharge pipe 51, a separate filter unit, and the filter introduction pipe. The pump unit 40 pumps the fuel to the fuel discharge port 31 disposed on the upper side of the motor unit 30.

(Check valve)
A check valve 74 is provided above the fuel pump 3. Specifically, the check valve 74 is provided between the fuel discharge port 31 disposed on the upper side of the motor unit 30 and a first flow path 53 of a fuel flow path unit 52 described later. The check valve 74 is for preventing the fuel from flowing backward from the first flow path 53 into the fuel pump 3.
That is, when the fuel pump 3 operates, the check valve 74 is opened, and the fuel is discharged from the fuel discharge port 31 and is pumped into the first flow path 53 of the fuel flow path unit 52 via the check valve 74. Is done.
When the fuel pump 3 stops, the check valve 74 is closed, and the fuel is held in the first flow path 53 without being discharged through the check valve 74.

(Flange unit)
The fuel supply device 1 includes a flange unit 4 that is disposed below the fuel pump 3 and attached to the bottom wall 2 b of the fuel tank 2. The flange unit 4 has a bottomed cylindrical unit body 10. The unit body 10 is a member made of resin or the like having excellent oil resistance, and is molded by injection.

The unit main body 10 is mainly composed of a substantially disk-shaped flange portion 12, a connector 14 formed on the lower side of the flange portion 12, and an engagement portion 15 formed on the upper side of the flange portion 12. ing. Further, a filter introduction pipe, a filter discharge pipe 51, and a fuel take-out pipe 57, which serve as fuel flow paths, are formed below the flange portion 12.
Further, a space is formed on the inner surface side of the unit body 10. This space functions as a reservoir 11 (see FIG. 3) in which fuel is stored. The fuel stored in the reservoir unit 11 is pumped up to the pump unit 40 via a filter unit separate from the fuel supply device 1.

(Flange part)
A substantially disc-shaped flange portion 12 is formed on the lower peripheral wall of the unit body 10. Then, by attaching the fuel supply device 1 to the fuel tank 2, the lower side than the flange portion 12 is exposed to the outside of the fuel tank 2. Further, the upper side of the flange portion 12 is immersed in the fuel in the fuel tank 2. A seal member (not shown) made of rubber or the like is provided between the flange portion 12 and the bottom wall 2b of the fuel tank 2 to ensure the sealing performance between the fuel supply device 1 and the fuel tank 2. It can be secured.

(Engagement part)
As shown in FIG. 1, an engaging portion 15 that engages with an engaging convex portion 25 a formed on a large-diameter portion 26 of an upper cup 25 described later is provided on the upper side of the flange portion 12. The engaging portion 15 has a substantially circular shape having a smaller diameter than the annular portion 13 when viewed from the axial direction. Further, a plurality of engaging pieces 15 a protruding upward are formed on the periphery of the engaging portion 15 (four in this embodiment). The engagement piece 15a is formed so as to be elastically deformable in the direction in which the upper end of the engagement piece 15a expands in diameter. Further, the engagement piece 15a is formed with an engagement hole that can be engaged with the engagement convex portion 25a formed in the upper cup 25. The flange portion 4 and the upper cup 25 are fixed by snap-fitting the engaging portion 15 to the large diameter portion 26 of the upper cup 25.

(Filter introduction pipe, filter discharge pipe, and fuel extraction pipe)
A filter introduction pipe, a filter discharge pipe 51, and a fuel extraction pipe 57 are provided below the flange portion 12.
The filter introduction pipe and the filter discharge pipe 51 communicate with a filter unit provided separately from the fuel supply device 1. The fuel in the fuel tank 2 is introduced into the filter unit through the filter introduction pipe.
Further, the fuel filtered and discharged by the filter unit is introduced into the suction port of the pump unit 40 through the filter discharge pipe 51.
The fuel extraction pipe 57 communicates with an internal combustion engine (not shown). The fuel stored in the reservoir unit 11 passes through the filter unit and is then pumped up from the suction port of the pump unit 40. Then, the fuel is pumped to the upper side of the motor unit 30, passes through each fuel flow path described later, and then is conveyed to the internal combustion engine through the fuel take-out pipe 57.

(connector)
A connector 14 is integrally formed below the flange portion 12. The connector 14 is a bottomed cylindrical member, and has a connector fitting surface that opens outward in the radial direction. The connector 14 is injection molded at the same time as the unit body 10 is formed. The connector 14 is fitted with an external connector (not shown) that is electrically connected to an external power source, a control device, or the like.

  Inside the connector 14, connector terminals 34 are provided for conducting the inside and outside of the fuel tank 2. The connector terminal 34 is a member made of a metal such as copper, and is formed by pressing. The connector terminal 34 is insert-molded, for example, when the connector 14 is molded. Each connector terminal 34 is electrically connected to the motor driving power source and the power source of the liquid level detector 60. The connector terminal 34 is formed in a substantially L shape. One end side 34 a of the connector terminal 34 protrudes inside the connector 14. The other end side 34 b of the connector terminal 34 protrudes above the flange portion 12 on the inner diameter side of the outer peripheral surface of the engaging portion 15. The other end side 34b of the connector terminal 34 is connected to a connection terminal 33b on the other side of the harness 6 described later.

(Harness)
The harness 6 is for connecting the connector terminal 34, the motor terminal 32, and the terminal of the liquid level detector 60. The harness 6 is formed by a core wire made of a metal such as copper and a coating covering the core wire made of an insulating material having oil resistance such as crosslinked polyethylene or vinyl chloride. Furthermore, a connection terminal 33a is provided on one end side of the harness 6, and a connection terminal 33b is provided on the other end side.

Four harnesses 6 are provided. The connection terminal 33 a on one end side of the harness 6 is fitted to the motor terminal 32 and the terminal of the liquid level detector 60. When the connection terminal 33a on one end side is fitted to the motor terminal 32, the connection terminal 33a on one end side is inserted through an opening 28 of the upper cup 25 described later. The other end side connection terminal 33 b is connected to the other end side 34 b of the connector terminal 34 protruding above the flange portion 12. Therefore, electric power can be supplied from the external power source to the motor unit 30 and the liquid level detector 60 via the harness 6, and a signal of the liquid level detector 60 can be output to the control device.
Further, the harness 6 is routed outside a cylinder portion 24 of an upper cup 25 described later. The movement of the harness 6 is restricted by a clip 29 provided on the outer peripheral surface of the cylindrical portion 24 of the upper cup 25.

(Upper cup)
The fuel supply device 1 includes an upper cup 25 (corresponding to a “case body” in the claims) formed so as to contain the fuel pump 3.
The upper cup 25 is a bottomed cylindrical member formed of a resin excellent in oil resistance, and is molded by injection. The upper cup 25 has a cylindrical portion 24 that is externally inserted into the fuel pump 3 from above the fuel pump 3.
In addition, a liquid level detector 60 is disposed above the upper cup 25. Therefore, an attachment portion 61 for the liquid level detector 60 is formed on the upper side of the cylindrical portion 24. The attachment portion 61 has a plate-like shape extending outward in the radial direction, and is molded by injection at the same time when the upper cup 25 is formed. The liquid level detector 60 is fixed to the mounting portion 61 by a snap fit or the like.

  A clip 29 is integrally formed on the peripheral wall of the upper cup 25. The clip 29 is formed at a location corresponding to the wiring position of the harness 6 (in the present application, above the connector terminal 34), and holds the harness 6. The clip 29 suppresses flapping of the harness 6 due to vibration during vehicle travel. Moreover, the slack of the harness 6 is prevented, and the harness 6 is prevented from being caught by the fuel tank 2 and peripheral parts of the fuel tank when the fuel supply device 1 is assembled.

(Cylinder part)
The cylindrical portion 24 of the upper cup 25 is configured by a small diameter portion 27 disposed on the upper side and a large diameter portion 26 disposed on the lower side.
The small diameter portion 27 is fitted on the upper side of the fuel pump 3. The small diameter portion 27 is formed so that its central axis is coaxial with the central axis C of the fuel pump 3. The inner peripheral surface of the small diameter portion 27 is formed to be substantially the same as or slightly larger than the outer diameter of the fuel pump 3.
The large diameter portion 26 is formed by expanding the lower side of the small diameter portion 27 and providing a step. The large-diameter portion 26 is formed such that its central axis is shifted to the outer diameter side from the small-diameter portion 27 and the central axis C of the fuel pump 3. That is, the large-diameter portion 26, the small-diameter portion 27, and the fuel pump 3 are in an eccentric state when viewed from the axial direction.
On the outer peripheral surface of the large-diameter portion 26, an engagement convex portion 25a is formed at a position corresponding to the engagement hole of the engagement piece 15a provided in the flange unit 4. The engagement projection 25a of the upper cup 25 and the engagement piece 15a of the flange unit 4 are snap-fitted to each other so that the upper cup 25 and the flange unit 4 are integrated.

(Aperture)
As shown in FIG. 2, a pair of openings 28 are separately formed on the upper wall surface 27 a of the cylindrical portion 24 corresponding to the motor terminals 32. The opening portion 28 communicates the inside and the outside of the tube portion 24. The outer shape of the opening 28 is larger than the outer shapes of the motor terminal 32 and the connection terminal 33a. Thereby, the motor terminal 32 can be exposed to the outside of the cylindrical portion 24 from the opening 28. Further, the connection terminal 33 a can be inserted into the opening 28 and can be fitted to the motor terminal 32.
A pair of motor terminals 32 are exposed from the opening 28. The height of the upper wall surface 27a of the cylindrical portion 24 may be set so that the upper end portion of the motor terminal 32 is slightly higher than the upper wall surface 27a of the small diameter portion 27 of the upper cup 25, or may be slightly lower. May be set.

(Fuel flow path)
On the upper wall surface 27a of the cylinder portion 24, a fuel flow path unit 52 through which fuel passes, a pressure regulator 76 that keeps the fuel pressure of the fuel flow path unit 52 constant, a storage section 76a for storing the pressure regulator 76, and a fuel pump A discharge port fitting portion 74a for fitting the three fuel discharge ports 31 is provided.
The fuel flow path unit 52 is formed in a substantially L-shaped cross section from the upper wall surface 27 a of the cylindrical portion 24 to the outer peripheral surface of the cylindrical portion 24. The fuel flow path unit 52 is mainly configured by the fuel flow paths of the first flow path 53, the second flow path 54, and the third flow path 55.

The first flow channel 53 is formed in a substantially L shape by extending along the central axis C on the upper side of the check valve 74 and then extending outward in the radial direction. The fuel discharged from the fuel pump 3 flows into the first flow path 53 via the check valve 74.
The second flow channel 54 extends horizontally from the upper end of the first flow channel 53 toward the radially outer side opposite to the first flow channel 53, and then extends along the central axis C. By extending toward the side, it is formed in a substantially L shape. That is, the second flow path 54 is formed above the fuel discharge port 31, a discharge port fitting portion 74 a provided on the upper wall surface 27 a of the cylindrical portion 24, and a pressure regulator 76 described later.
The third flow channel 55 extends from the upper side to the lower side along the outer peripheral surface of the small diameter portion 27. The third flow channel 55 is disposed in a dead space formed between the outer peripheral surface of the large-diameter portion 26 and the outer peripheral surface of the small-diameter portion 27 that are arranged eccentrically when viewed from the axial direction. That is, the third flow path 55 is disposed inside the large diameter portion 26 without protruding from the outer peripheral surface of the large diameter portion 26.

  A lower end portion of the third flow path 55 is connected to a fuel extraction pipe 57 formed on the lower side of the flange unit 4. Therefore, the fuel discharged from the fuel pump 3 passes through each fuel flow path in the order of the first flow path 53, the second flow path 54, and the third flow path 55, passes through the fuel take-out pipe 57, and is not shown. It is conveyed to.

  Further, a pressure regulator 76 and a housing portion 76 a for housing the pressure regulator 76 are provided on the opposite side of the third flow path 55 across the central axis C. The pressure regulator 76 is for keeping the fuel pressure in each fuel flow path constant, and when excessive pressure is applied in each fuel flow path of the fuel flow path unit 52, the fuel in each fuel flow path is reduced. Is returned to the fuel tank 2. The pressure regulator 76 and the first flow path 53 are connected via a second flow path 54 formed above the pressure regulator 76 and the accommodating portion 76a.

By the way, the fuel supply apparatus of patent document 1 is arrange | positioned in the state which the pressure regulator exposed to the exterior of the upper cup. Here, the assembly of the subordinate type fuel supply device is performed by inserting the upper cup side of the fuel pump from the outside of the fuel tank toward the opening of the fuel tank. At this time, in the fuel supply device of Patent Document 1, the front end side of the upper cup may come into contact with the periphery of the opening of the fuel tank, the peripheral parts of the fuel tank, and the like, which may affect the function of the pressure regulator.
In addition, it is conceivable to add a member that protects the pressure regulator to the fuel supply device of Patent Document 1, but this may increase the size of the fuel pump itself.

  However, in the fuel supply device 1 of the present embodiment, the pressure regulator 76 is covered with the accommodating portion 76 a that is provided integrally with the cylindrical portion 24 of the upper cup 25. Further, the fuel flow path unit 52 is disposed above the pressure regulator 76. Thus, when the fuel supply device 1 is assembled, even if the pressure regulator 76 comes into contact with the periphery of the opening 2a of the fuel tank 2 or peripheral parts, the influence on the pressure regulator 76 can be suppressed. Further, in the fuel supply device 1 of the present embodiment, since the pressure regulator 76 is disposed in the housing portion 76a provided integrally with the cylinder portion 24 of the upper cup 25, the enlargement of the fuel supply device 1 is suppressed. However, the pressure regulator 76 can be protected.

(Wall)
Further, the upper wall surface 27a of the cylindrical portion 24 is provided with the above-described fuel flow path unit 52, the accommodating portion 76a of the pressure regulator 76, and the wall portion 50 that connects the fuel discharge port. The wall portion 50 is erected upward from the upper wall surface 27a of the cylinder portion 24. The wall portion 50 extends horizontally on the upper wall surface 27a of the cylindrical portion 24 along a direction substantially orthogonal to a straight line connecting the pair of motor terminals 32.

The height of the wall portion 50 in the axial direction is formed to be higher than the height of the connection terminal 33a when the connection terminal 33a is fitted to the motor terminal 32. The thickness of the wall 50 is set so as to be substantially the same as or smaller than the separation distance of the motor terminal 32. The horizontal length of the wall portion 50 is set to be substantially the same as or longer than the diameter of the upper wall surface 27a of the cylindrical portion 24. By setting each dimension of the wall part 50 as mentioned above, the wall part 50 can be arrange | positioned between each motor terminal 32 and each connection terminal 33a.
Further, a meat stealing portion 65 is formed on the wall portion 50. The meat stealer 65 is disposed around the fuel flow path unit 52, the fuel discharge port 31, and the accommodating portion 76 a of the pressure regulator 76, and the fuel flow path unit 52, the fuel discharge port 31, and the accommodating portion 76 a of the pressure regulator 76. It is formed along the outer diameter.

(effect)
According to the present embodiment, the discharge port fitting portion 74a to which the fuel discharge port 31 is connected and the accommodating portion 76a in which the pressure regulator 76 is held project from the upper portion of the upper cup 25. The axial length of the fuel supply device 1 can be reduced as compared with the case where the pressure regulator 76 and the fuel flow path unit 52 are arranged above the fuel flow path unit 52 as in Patent Document 1. Further, by arranging the discharge port fitting portion 74a and the accommodating portion 76a on the central axis of the fuel pump 3, the amount of protrusion in the radial direction can be suppressed. Therefore, the fuel discharge port 31, the fuel flow path unit 52, and the pressure regulator 76 can be efficiently arranged to reduce the size and layout of the fuel supply device 1.
Further, when the fuel supply device 1 is inserted and assembled from the opening 2a of the fuel tank 2, the pressure regulator 76 and the check valve 74 are protected even if they contact the periphery of the opening 2a of the fuel tank 2 or peripheral parts. The Similarly, there is no problem when packing and transporting. Furthermore, since the pressure regulator 76 is a precision component that always regulates the fuel pressure with high accuracy, the pressure regulator 76 can protect the pressure so that the highly accurate fuel pressure adjustment function of the fuel supply device 1 can be maintained over a long period of time. It is.

  Further, according to the present embodiment, since the first flow path 53 and the second flow path 54 are arranged in a straight line, the mold configuration at the time of molding the fuel flow path unit 52 can be simplified. Therefore, the low-cost fuel supply device 1 can be provided.

  Further, according to the present embodiment, the fuel can be guided to the outside of the fuel tank 2 by connecting the pressure regulator 76, the fuel discharge port 31, and the fuel flow path unit 52 through the shortest path. For this reason, the protrusion from the outer peripheral surface of the fuel pump 3 of the fuel discharge port 31, the fuel flow path unit 52, and the pressure regulator 76 can further be suppressed. Therefore, the fuel supply device 1 can be reduced in size and layout.

Further, according to the present embodiment, the discharge port fitting portion 74a, the accommodating portion 76a, and the fuel flow path unit 52 can be reinforced with each other by being connected by the wall portion 50, so that the discharge port fitting protruding from the upper cup 25 can be provided. The rigidity of the portion 74a, the accommodating portion 76a, and the fuel flow path unit 52 can be increased.
Further, according to the present embodiment, the pair of motor terminals 32 can be disposed by effectively utilizing the dead space formed on the upper wall surface 27a of the upper cup 25, and the fuel supply device 1 can be reduced in size and layout. Can be improved.

The present invention is not limited to the embodiment described above .

DESCRIPTION OF SYMBOLS 1 Fuel supply apparatus 2 Fuel tank 2b Bottom wall 3 Fuel pump 4 Flange unit 24 Tube part 25 Upper cup (case body)
27a Upper wall surface (upper wall)
28 Opening 31 Fuel Discharge Port 32 Motor Terminal 50 Wall 52 Fuel Channel Unit (Fuel Channel)
53 1st flow path 54 2nd flow path 55 3rd flow path 74a Discharge port fitting part 76 Pressure regulator 76a Storage part

Claims (6)

A flange unit attached to the opening on the bottom of the fuel tank;
A case body attached to the flange unit;
A mounting portion of the liquid level detector formed on the case body,
A fuel pump provided in the case body and discharging the fuel in the fuel tank from a fuel discharge port;
A fuel flow path through which fuel discharged from the fuel discharge port passes;
A pressure regulator that maintains a constant pressure of the fuel in the fuel flow path;
In a fuel supply device having
A discharge port fitting portion to which the fuel discharge port is connected and a housing portion in which the pressure regulator is held are formed to protrude from the upper portion of the case body,
The fuel flow path is integrally formed above the discharge port fitting portion and the accommodating portion ,
The fuel flow path, the fuel supply apparatus characterized by being arranged in the fuel tank interior to the flange unit. The fuel flow path is
A first flow path connected to the fuel outlet of the fuel pump;
A second flow path connected to the pressure regulator;
A third flow path formed along the axial direction of the case body and led out of the fuel tank,
The fuel supply device according to claim 1, wherein the first flow path and the second flow path are arranged in a straight line.   The fuel supply device according to claim 1, wherein the discharge port fitting portion, the accommodating portion, and the fuel flow path are provided on the same center line of the fuel pump.   4. The fuel supply device according to claim 1, wherein the discharge port fitting portion, the housing portion, and the fuel flow path are connected to each other by a wall portion. 5.   A pair of motor terminals for supplying electric power to the fuel pump is provided on the upper wall surface side of the case body of the fuel pump, and the motor terminals are provided at locations corresponding to the pair of motor terminals on the upper wall surface. The fuel supply device according to any one of claims 1 to 4, wherein an opening that can be exposed to the outside is formed.   6. The fuel supply device according to claim 5, wherein the pair of motor terminals and the opening are disposed on both sides of a center line of the fuel pump.

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