JP3928733B2 - In-tank fuel pump system - Google Patents

Description

  The present invention relates to an in-tank type fuel pump apparatus provided with a fuel pump, a fuel filter, and a holding means for these inside a fuel tank.

  As disclosed in Patent Document 1 as a prior art, fuel discharged from a fuel pump provided in a fuel tank is pumped out of the fuel tank via a discharge pipe, and the pumped fuel is sent from a fuel injection valve (not shown). It is known that the fuel is injected and supplied to the combustion chamber of the engine and the surplus fuel is returned into the sub tank through the return pipe.

  In the in-tank type fuel pump disclosed in Patent Document 1, a mounting member for a functional part such as a fuel pump is made of metal, and screw fastening, clip fastening or the like is used as a fixing means for each part. There is a problem that the number of parts is increased, and more processing steps such as surface treatment such as brazing and welding are required.

  As another conventional technique, a fuel tube coupling device disclosed in Patent Document 2 includes a one-touch connector (quick) that improves workability compared to a flare joint coupling and a rubber hose coupling that are conventionally used in a pipe coupling section. Connector). In recent years, as for the piping around the fuel tank, the structure using a one-touch connector tends to be adopted for the connection of the tubes of the flange supporting the fuel pump to the anti-tank side.

Japanese Patent Laid-Open No. 3-105055 JP-A-5-262145

  However, since the connecting structure part called so-called quick connector is made of resin, and the tube on the other side to which this quick connector is connected is made of metal or resin, the strength of the quick connector is secured sufficiently high. Occasionally, for example, when an external force such as a stepping stone is applied during assembly work, the quick connector or tube may be damaged or destroyed. There is a risk of waking up. In addition, there is a problem that corrosion tends to proceed when an external foreign object such as dust or water enters from a damaged part or a damaged part of a damaged connector or tube.

  An object of the present invention is to provide an in-tank type fuel pump apparatus that can reduce the number of parts, make it possible to easily assemble these parts, and have multiple functions and can be manufactured at low cost. Another object of the present invention is to provide an in-tank type fuel pump device having a good protection force or protection performance when the connector pipe receives an external force from the outside.

  In order to solve the above-mentioned problem, an in-tank fuel pump apparatus according to claim 1 of the present invention is an in-tank fuel pump apparatus in which a fuel pump for pumping up fuel in a fuel tank is provided in the fuel tank. A resin-made pump case for housing the fuel pump, and an in-tank part case for housing the in-tank part mounted on the fuel tank, and the in-tank part case formed integrally with the outside of the pump case It is characterized by being. Further, the pump case has a vapor discharge hole.

The pump case includes a pump receiving surface that receives gravity acting on the fuel pump, and a pump side surface that restricts movement in a direction perpendicular to the direction of gravity acting on the fuel pump. Has a pump insertion opening at a portion facing the pump receiving surface so that the fuel pump can be inserted from above.

According to a tenth aspect of the present invention, the in-tank part case is a thermistor case that houses a thermistor. According to a tenth aspect of the present invention, the thermistor case has a lid on the top. According to a tenth aspect of the present invention, the lid is attached to the thermistor case with a hinge portion.
A ninth or eleventh aspect is characterized in that a claw portion is provided on an outer peripheral portion of the lid. According to a sixth aspect of the present invention, the in-tank part case is a capacitor case that houses a capacitor. According to a seventh aspect of the present invention, the in-tank part case is a sender gauge case that houses a sender gauge.

According to a first aspect of the present invention, the sender gauge case has a snap-fit fitting structure. According to a first aspect of the present invention , the counterpart sender gauge also has a snap-fit fitting structure. According to a first aspect of the present invention, the sender gauge case has a concave groove portion that forms a space portion with a narrowed tip portion.

In Claim 2 , it has a lower end wall surface in the front-end | tip part of the said concave groove part, It is characterized by the above-mentioned. According to a third aspect of the present invention, the sender gauge case has a convex protrusion that becomes wider toward the tip. According to a fourth aspect of the present invention, the pump case is formed with a return fuel passage portion having a fuel return passage outside thereof.

According to a fifth aspect of the present invention, the return fuel passage portion has a snap-fit fitting structure with a flange side member. According to a sixth aspect of the present invention, the return fuel passage part has a pipe detachable shape part at a lower end part.

(Operation and effect of the invention)
According to the in-tank type fuel pump device of the first aspect, the resin-made pump case accommodating the fuel pump and the tank internal part case accommodating one or more tank internal parts are formed by integral molding. Since the number of parts of the attachment parts for the tank parts can be reduced, there is an effect that the assembling work can be easily performed. Further, since the pump case has a vapor discharge hole, there are effects such as escape of vapor and reduction of abnormal noise .

According to the twelfth aspect, the fuel pump and the tank internal parts can be inserted in the same direction into the pump case and the other tank internal parts case from the opening formed in the opposing portion of the receiving surface, so that the assembling work can be easily performed. In claim 8, 9, 10 or 11 , when the in-tank part case is a thermistor case for accommodating the thermistor, the cover for attaching the thermistor is integrated, the cover is locked, the lock is released, the number of parts There are advantages such as ease of assembly work and parts management.

In the fourth or fifth aspect , when the return fuel passage portion having the fuel return passage is formed outside the pump case, the number of parts can be reduced and the assembly is facilitated. Moreover, since the return fuel passage portion has a snap-fit fitting structure with the flange side member, the return passage portion and the flange side member can be easily attached and detached. Further, in claim 6 , since the lower end portion of the return fuel passage portion has the pipe detachable shape portion, the fuel vapor pump suction can be prevented by attaching the return tube.

Embodiments of the present invention will be described below with reference to the drawings.
(First embodiment)
One embodiment of the in-tank fuel pump device of the present invention is shown in FIGS. 7 shows an in-tank type fuel pump device attached to the fuel tank, FIGS. 1 to 4 are external perspective views of the in-tank type fuel pump device, and FIG. 5 is a cross-sectional view taken along the line VV in FIG. 6 is a cross-sectional view taken along the line VI-VI shown in FIG.

  As shown in FIG. 7, an in-tank fuel pump device 2 is mounted inside the fuel tank 1. The metallic upper tank 3 and lower tank 4 are clamped and fixed by an insulator 5, bolts 11 and nuts 12. A supply pipe 6 is connected to the oil filler port 10 of the upper tank 3 with a rubber boot 7 interposed therebetween. A sub tank 8 is installed inside the lower tank 4, and a communication pipe 9 that connects the inside and the outside of the sub tank 8 is provided.

A flange 21 is attached to the opening 3 a of the upper tank 3, and a pump case 16 that houses the fuel pump 14, the electrical component 31, and the sender is suspended from the flange 21. Next, components of the in-tank fuel pump device 2 will be described with reference to FIG.
A fuel pump 14 is attached inside the pump case 16, and a fuel filter 13, a sender gauge 41, and an electrical component 31 are attached outside the pump case 16. Hereinafter, (1) fuel filter 13, (2) fuel pump 14, (3) pump case 16, (4) flange, (5) sender gauge 41, (6) electrical component 31, (7) pump cushion 51 and (8 The discharge component 61 will be described.

(1) Fuel filter 13
The fuel filter 13 is provided in a sub-tank 8 provided outside the intake type fuel pump device of the present invention, and has a function of removing and filtering foreign matters in the fuel in the sub-tank 8. The fuel filter 13 is attached to the bottom of the fuel pump 14.

(2) Fuel pump 14
The fuel pump 14 includes a pump unit 71 that sucks fuel, a motor unit 72 that drives the pump unit, and a discharge unit 73 that discharges fuel from the pump unit 71 through the inside of the motor unit 72. The fuel pump 14 has an electric supply unit 74 for supplying a drive current for the motor. The fuel pump 14 is accommodated in a resin pump case 16.

(3) Pump case 16
The details of the pump case 16 are shown in FIGS. The pump case 16 includes (i) a pump mounting portion 81, (ii) a suspension fixing portion 82, (iii) a capacitor mounting portion 83, (iv) a return fuel passage portion 84, (v) a remaining amount warning display portion 85 and ( vi) It consists of a sender mounting portion 86.

(I) The pump mounting portion 81 includes a bottomed cylindrical cylindrical body 24 for housing the fuel pump 14. A discharge port 25 for discharging the fuel vapor is formed at the bottom of the cylindrical body 24.
(Ii) The suspension fixing part 82 is provided with claw parts 27 and 28 for fixing the pump case 16 to the flange on the outer periphery of the upper end of the cylinder 24. At the time of assembly, the claw portions 27 and 28 are elastically fitted into the fitting grooves of the flange 21.
Thereby, the pump case 16 is suspended and fixed to the flange 21. Further, the flange 21 comes into contact with the contact surfaces 16a to 16e provided on the pump case 16, whereby the height of the pump case 16 from the flange 21 is defined.

(Iii) The capacitor mounting portion 83 is formed with a capacitor case portion 831 for accommodating the capacitor 32 described later, claw portions 833, 834, 835 for elastically fitting and fixing the capacitor 32, and a capacitor lead wire fixing portion 832. The claw portion 835 is formed with a hook convex portion 836 for preventing the capacitor 32 from coming off.
(Iv) The return fuel passage portion 84 has a communication hole 841 formed in parallel to the cylindrical body 24 outside the pump mounting portion 81. The communication hole 841 is connected to a communication hole 216 formed in the flange 21 on the upper end side, and a cylindrical return tube lower end portion connected to the return tube 842 on the lower end side. A snap fit mounting hole 844 for fitting and fixing is formed on the upper end side with the claw portion 55 of the male collector portion 221 of the flange 21.

  (V) The remaining amount warning indicator mounting portion 85 includes a thermistor case portion 851 for mounting the thermistor 48 and a thermistor cap portion 852 that blocks the upper end opening of the thermistor case portion as shown in FIG. The thermistor cap portion 852 is connected to the thermistor case portion 851 by a hinge portion 853, and the thermistor cap portion 852 can close the upper end opening of the thermistor case portion 851 by bending the flexible hinge portion 853. . Claw portions 854, 855, and 857 that can be hooked on the upper end of the thermistor case portion 851 are formed on the outer peripheral portion of the thermistor cap portion 852, which is the portion indicated by the two-dot chain line in FIG. Also, a fuel delay orifice portion 856 that communicates the inside and outside of the case is formed at the bottom of the thermistor case portion 851. A thermistor 48 described later is accommodated in the thermistor case portion 851. The thermistor 48 detects the remaining amount of fuel in the tank, and generates, for example, an off electrical signal when the remaining amount falls below a predetermined amount.

  (Vi) The sender gauge mounting portion 86 includes positioning convex portions 861 and 862 for fitting and positioning the mounting metal plate 42 of the sender gauge as a liquid level gauge, and guide portions 863 for guiding both sides of the metal plate 42 in the insertion direction. 864. The positioning convex portions 861 and 862 are formed on the outer periphery in the extending direction of the cylindrical body 24, and L-shaped guide portions 863 and 864 protrude from both sides of the wider portion than the positioning convex portions 861 and 862. Abutting surfaces 863a and 864a serving as slide surfaces when the metal plate 42 is inserted are formed on the surfaces of the guide portions 863 and 864 facing the positioning convex portions 861 and 862, respectively. A snap fit portion 865 that can be fitted into a hole of a metal plate for attachment of the sender gauge is formed on the lower end side of the positioning convex portions 862 and 861, and further, a latch that becomes an assembly end point position of the metal plate 42 on the lower end side. Portions 866 and 867 are formed in a convex shape. The positioning convex portions 861 and 862 and the guide portions 863 and 865 are provided with a gradient so that they can be die-molded with resin.

  The sender gauge mounting portion 86 is provided so as to protrude radially outward from the mounting fixing portion 82, and the central portion thereof is supported by the mounting fixing portion 82 by the protruding portion 868. The outer peripheral portion 868a of the protruding portion 868 has an R shape so that it can be smoothly assembled and removed without being caught when the metal plate for attaching the sender gauge is slid.

(4) Flange 21
As shown in FIGS. 1 and 2, the flange 21 is made of resin and hangs down inside the disk portion 211, a reinforcing rib 212 formed in an annular shape on the lower surface of the disk portion 211, and the inside of the annular rib 212. It comprises a fuel supply unit 213 and a fuel return unit 214 provided in parallel to the fuel supply unit 213.

  The disc portion 211 has a rib 212 on the outer peripheral portion thereof fitted into the opening hole 3 a of the upper tank 3, and the disc portion 211 is fastened and fixed to the upper tank 3 by bolts 29 via the retainer 22 and the plate 23. Yes. A fuel supply pipe 217 that communicates with the communication hole 215 of the fuel supply unit 213 and a fuel return pipe 218 that communicates with the communication hole 216 of the fuel return unit 214 are formed above the disk portion 211. Further, an electric connector 219 for supplying a current for driving the motor part of the fuel pump 14 is formed on the disk part 211.

  The lower end of the fuel supply unit 213 is formed with a female connector that fits the discharge unit 73 of the fuel pump 14. Further, a male connector portion 221 that fits into the return fuel passage portion 84 is formed at the lower end portion of the fuel return portion 214, and a claw portion 55 for snap fit fitting is formed at the outer peripheral portion of the male connector portion 221.

(5) Sender gauge
The sender gauge 41 will be described with reference to FIGS. 20, 21, and 22.
The sender gauge 41 functions as a liquid level gauge that detects the liquid level of the fuel in the tank from the electric resistance value, and the thermistor 48 functions as a remaining amount warning light. The sender gauge 41 includes a metal plate 42 that functions as a mounting bracket to the pump-side flange, and positioning convex portions 43 and 44. Note that the portion that functions as the mounting bracket is the outer lower portion 42a (shaded portion in FIG. 21) of the metal plate 42, and the outer upper portion 42b may not be provided. When there is no outer upper part 42b, a space is formed between the flange 21 and the attachment / detachment work is facilitated. Further, the lower end of the metal plate 42 is formed with a detachment prevention hole 45 that fits into the snap fit portion of the mating housing. In this embodiment, the detachment prevention hole 45 has a quadrangular shape, but the shape is not limited and may be a round shape instead of a quadrangular shape. Further, one end of an arm 47 is attached to the metal plate 42 so as to be swingable, and a float 46 capable of floating on the liquid surface is attached to the other end of the arm 47 so as to be rotatable. A thermistor 48 functioning as a remaining amount warning lamp for displaying the remaining amount of fuel in the tank is provided on the side of the metal plate 42.

  The thermistor 48 is connected to the metal plate 42 by a connecting portion 50. The connecting portion 50 is formed with a gap 50a so as to hold the connecting portion 50 so that the side wall of the connecting portion 50 is fitted therebetween. A thermistor lead wire 49 of the thermistor 48 is drawn out.

(6) Electrical component 31
As shown in FIG. 23, the electrical component 31 includes a capacitor 32, a fuel pump side connector 33 that can be connected to the power supply unit on the fuel pump 14 side, and a flange side connector 34 that can be connected to the flange 21 side. The lead wires 35 and 36 drawn out from the flange-side connector 34 are electrically divided into two parts on the capacitor side and the fuel pump-side connector 33 side from the middle. The capacitor 32 constitutes an electric wire circuit and prevents noise. The capacitor 32 is connected to lead wires 35 and 36 by lead wires 37 and 38, and the lead wires 39 and 40 of the fuel pump side connector 33 are similarly connected to the lead wires 35 and 36. The capacitor 32 is snap-fit to the capacitor mounting portion 83. The pump-side connector 33 is fitted and electrically connected to the electrical connector portion.

(7) Pump cushion 51
The pump cushion 51 will be described with reference to FIGS. The pump cushion 51 is made of rubber and is inserted as a pump seat between the inner bottom portion of the pump case 16 and the fuel pump 14. The pump cushion 51 has a concave notch 52 for mounting, a space 53 that does not hinder the shaft rotation of the pump at the center, and a positioning projection 54 for positioning with the inner bottom of the pump case 16. 55 is formed. Further, a concave groove 56 is formed as a vapor discharge passage of the fuel pump 14. The filter 13 is fixed between the fuel pump 14 and the pump case 16 via the pump cushion 51 and the clip 56.

(8) Discharge component 61
As shown in FIG. 8, the discharge part 73 of the fuel pump 14 is connected to the female connector part of the fuel supply part 213 of the flange 21 through the spacer 65, the O-ring 64, and the cap 63.
Next, the characteristics of the first embodiment are summarized as follows.

(1) Since the pump case 16 of the fuel pump 14 is made of resin, it is possible to snap-fit the connection with the flange 21.
(2) The thermistor case portion 851 of the remaining amount warning device display portion 85 is formed integrally with the pump case 16.
(3) The thermistor cap 852 is integrally formed with the thermistor case 851. For this reason, after the thermistor 48 of the sender gauge 41 is assembled inside the thermistor case portion 851, the belt-like hinge portion 853 is folded back to cover the thermistor cap portion 852 at the upper end opening of the thermistor case portion 85. Moreover, since the gradient is provided in the assembly direction of the fitting part of the thermistor cap part 852, it is easy to assemble. Further, the claw portions 854, 855, and 857 are provided in the thermistor cap portion 852, so that the thermistor case portion 851 is sandwiched to prevent the cap from coming off.

(4) The capacitor case portion 831 is formed integrally with the pump case 16. The capacitor 32 serves to prevent noise of the fuel pump 14. In this embodiment, there is an advantage that the capacitor 32 can be easily attached by a one-touch operation of inserting the capacitor 32 into the capacitor case portion 831.
(5) Since the capacitor lead wire fixing portion 832 of the capacitor 32 is formed integrally with the pump case 16, it helps to prevent the lead wire from being cut.

(6) The return fuel passage portion 84 is formed integrally with the pump case 16. For this reason, when the claw portion 55 on the flange 21 side is fitted into the snap-fit mounting hole 844 formed at the upper end portion of the return fuel passage portion 84, the fixed portion between the flange 21 and the return fuel passage portion 84 becomes the fuel. It also serves as a return passage.
(7) The lower end portion 843 of the return passage may have a shape that allows the return tubes 94, 95, and 96 shown in FIG.

  (8) The attachment part of the sender gauge 41 is formed integrally with the pump case 16. An uneven groove portion having a slope portion is provided, and a snap fit portion is provided at the lower end. While the metal plate 42 is slid into the concavo-convex groove portion, the metal plate 42 is gradually sandwiched by the gradient, and the inner side surface of the groove portion and the side surface of the press projection of the metal plate 42 are tightened while coming into contact with each other. The attachment direction is regulated. Further, when the metal plate 42 passes over the snap-fit portion and comes into contact with the lower end wall of the housing, the assembly end position is reached. Thereby, the assembly is easy and there is a function of preventing the removal.

(9) A positioning port for the pump cushion 51 and a filter escape portion are provided.
(10) Since the vapor discharge hole 25 from the fuel pump 14 is provided, the vapor discharge effect is improved. When the pump case 16 is made cylindrical as in this embodiment, collision noise and vibration noise are likely to occur when the vapor discharge portion hits the inner surface of the pump case. Such a problem is caused by the provision of the vapor discharge hole 25. It will be resolved.

(Second embodiment)
A second embodiment of the present invention is shown in FIG.
In the second embodiment, the discharge part of the fuel pump 14 and the fuel supply part on the flange 21 side are connected by a rubber hose 91, and the fuel return part on the flange 21 side and the return fuel passage part on the pump case 16 side are connected to a rubber hose 92. This is an example of connection. As for the other components, as in the first embodiment, an electrical component mounting portion, a sender gauge mounting portion, and the like are formed outside the pump case in the pump case 16 that houses the fuel pump 14.

  Also in the second embodiment, similarly, the number of pump parts is reduced, the weight is reduced, and each pump internal part can be easily attached. The rubber hose can be replaced with a nylon tube or the like.

(Third embodiment)
A third embodiment of the present invention is shown in FIG.
The third embodiment shown in FIG. 33 is an example in which the shape of the capacitor lead fixing portion attached to the outside of the pump case 16 is changed. As described above, the capacitor lead wire fixing portion 837 can be provided on the outer side portion of the cylinder 24 of the pump case 16.
An enlarged view of the capacitor lead fixing portion 837 is shown in FIG. The capacitor lead fixing portion 837 protrudes from the end portion 240 of the cylindrical body 24 in the outer diameter direction, and the corner portions 240a and 240b of the end portion 240 are rounded. As a result, disconnection of the lead wires 37 and 38 extending from the capacitor mounting portion 83 into the pump case 16 can be prevented.

(Fourth embodiment)
A fourth embodiment of the present invention is shown in FIG.
FIG. 34 shows a modification of the shape of the return tube. When the return tube includes fuel vapor, the return tube is an example in which various measures are taken so that bubbles in the returned fuel are not sucked into the pump unit. A return tube 94 shown in FIG. 34A is bent in an L shape, a return tube 95 shown in FIG. 34B is extended to the bottom and bent in an L shape, and a return tube 96 shown in FIG. It has become.

(5th Example)
FIG. 35 shows a fifth embodiment of the present invention.
The fifth embodiment shown in FIG. 35 is another modification example replacing the return tube lower end portion 843 shown in FIG. The return tube lower end portion 847 having the shape shown in FIG. 35 is formed with a large-diameter portion 848 for locking when the return tube is fitted.

(Sixth embodiment)
A sixth embodiment of the present invention is shown in FIG.
The sixth embodiment shown in FIG. 36 is an example in which the shape of the capacitor mounting portion is changed so that it can be more easily formed. The capacitor lead wire fixing portion 838 is provided in series with the capacitor case portion 831 and has a more compact shape.

(Seventh embodiment)
FIG. 38 shows a seventh embodiment of the present invention.
In the seventh embodiment shown in FIG. 38, a slit 161 a is provided on the side surface of the pump case 161 so that the fuel filter can pass therethrough. Thereby, it becomes possible to insert the fuel pump 14 and the fuel filter 13 together with the pump cushion 51 into the pump case 161. In addition, when the fuel pump 14 and the fuel filter are inspected or replaced, they can be integrally attached and detached, which is advantageous in reducing the man-hours.

(Eighth embodiment)
An eighth embodiment of the present invention is shown in FIGS.
39 and 40 show a mounting portion of the quick connector, and FIG. 41 shows a state of the fuel tank to which the quick connector is mounted. The main tube 101 protruding to the outside of the flange 21 is integrally formed with the flange 21 and resin, and a fuel passage 102 for receiving fuel discharged from the discharge portion 18 of the fuel pump 14 is formed inside the main tube 101. The fuel passage 103 has a fuel passage 103 that is bent in an L shape in a substantially right-angle direction.

  A convex portion 104 for attaching and locking a quick connector (not shown) to the portion of the main tube 101 extending parallel to the upper surface of the flange 21 of the main tube 101 is formed in an annular shape on the outer periphery. The extending direction of the main tube 101 is slightly inclined from the direction opposite to the extending direction of the fuel filter 13 as shown in FIG. A main tube protection plate 106 is vertically resin-molded integrally with the flange 21 below the main tube 101. The main tube protection plate 106 is formed with a predetermined gap from the convex portion 104 of the main tube 101.

  According to the eighth embodiment, when an external force is applied to the main tube 101 in the direction of the arrow shown in FIG. 40, the main tube protection plate 106 supports and prevents the main tube 101 from directly hitting the flange 21. The main tube protection plate 106 is formed with an arcuate receiving surface 107.

(Ninth embodiment)
A ninth embodiment of the present invention is shown in FIGS.
The ninth embodiment shown in FIG. 42 is an embodiment in which a protective plate 109 is mounted on the upper portion of the main tube 101 of the eighth embodiment shown in FIGS. 43 and 44 show a state before the protective plate 109 is mounted on the upper portion of the main tube 101. FIG. In the ninth embodiment, the protective plate 109 includes (1) a cover portion 110 and (2) a protective plate portion 111.

(1) The cover portion 110 is placed on the upper side of the main tube 101 so as to cover it.
(2) The protective plate portion 111 is formed integrally with the cover portion 110 and resin, and the leg portions 112 and 113 abut against the flange 24 through the gap with the main tube 101. A space 114 for inserting the main tube protection plate 106 as a regulating member is formed inside the legs 112 and 113, and claw portions 115 and 116 are formed on the space 114 side of the legs 112 and 113. As shown in FIG. 42, the claw portions 115 and 116 inside the protection plate portion 111 are fitted into the holes 117 and 118 of the main tube protection plate 106.

  According to the ninth embodiment, as shown in FIG. 42, since the protective plate 109 is mounted on the upper portion of the main tube 101, even if external force is applied to the quick connector mounting portion fitted to the main tube 101 from the outside, Since the receiving surface 107 of the main tube protection plate 106 supports the main tube 101, the base of the main tube 101 or the quick connector 120 is not damaged.

  In the ninth embodiment, the protective plate 109 can be mounted with a simple structure by the claw portions 115 and 116 fitted into the holes 117 and 118 of the main tube protective plate 106, and in addition to the downward external force described above, There is an effect of protecting the main tube 101 and the quick connector 120 from the external force in the direction by the protective plate portion 111. Furthermore, there is an effect that intrusion of water, dust, snow and the like can be prevented as much as possible.

  In the ninth embodiment, the protection plate 109 can be easily attached to the main tube 101 without using a special working part by spreading the claws 115 and 116 of the protection plate 109. At the time of mounting, the protective plate 109 can be easily assembled simply by manually pushing the claw portions 115 and 116 into the holes 117 and 118 of the main tube protective plate 106.

  FIG. 45 to FIG. 54 show a protection plate as a modification example instead of the protection plate 109 shown in FIG. 45 has a claw portion 115 and 116 formed on the same surface at the same height, and a protection plate 311 shown in FIG. 46 has a claw portion 115 and 116 formed on a different surface at the same height. 47 has a claw portion 115, 116 formed on the same surface at the same height and a window portion 320 formed on the opposite surface of the claw, and the protection plate 313 shown in FIG. 48 has the same height on a different surface. Now, claw portions 115 and 116 are formed, and a window 320 is formed on the opposing surface of the claw portion, and a protective plate 314 shown in FIG. 49 is formed with claw portions 115 and 116 having the same height on both surfaces. The protective plate 315 shown in FIG. 50 has claw portions 115 and 116 formed on different surfaces at different heights, and the protective plate 316 shown in FIG. 51 has claw portions 115 and 116 formed on both surfaces at the same height. 115 52 is provided with a window 320 on the orthogonal plane, the protective plate 317 shown in FIG. 52 is the same as the protective plate shown in FIG. 45 with the second leg support 121, and the protective plate 318 shown in FIG. 54. The claw portions 115 and 116 are formed at the same height on the surface and the cover portion 122 is formed. The protective plate 319 shown in FIG. 54 forms the claw portions 115 and 116 at the same height on the same surface, and the cover portion 123. Is formed.

(Tenth embodiment)
Next, FIGS. 55 to 63 show an embodiment provided with a ground circuit for preventing charging of the fuel tank. For example, when fuel is supplied from the outside into the fuel tank 1, the fuel tank 1 is charged by friction with the fuel filler port 6 when the fuel flows through the fuel filler port 6, and the charge of the static fuel tank 1 is charged. It is provided with a ground circuit that leads to the outside of the fuel tank. The tenth embodiment shown here is an example in which a ground terminal is formed by exposing the negative terminal on the flange-side electrical connector 31 to the sealing gasket 191 side.

  When the bracket for fixing the fuel pump 14 to the fuel tank 1 is formed of resin parts, since this resin is non-conductive, it is devised so that static electricity is generated due to friction of fuel or the like, and damage to each part is not caused. Is. As countermeasures against static electricity, each component may be made of a conductive material or a dedicated earth circuit may be provided. However, in either case, the number of components increases and the cost increases, which is not preferable. The tenth embodiment described below has an object to reduce the number of parts, to facilitate assembly, and to form a fuel tank grounding circuit at a low cost.

  In the tenth embodiment shown in FIGS. 55 to 58, a flange side electrical connector 131 as a fuel pump driving electrical connector is provided on the flange 21 forming the lid portion of the fuel tank 1, and the negative side of the flange side electrical connector 131 is provided. The terminal 132 is exposed to the outside on the conductive gasket 134 side, and this exposed portion is brought into electrical contact with the gasket 134.

  As shown in FIG. 55, a minus side terminal 132 is fixed by insert molding inside the flange side electrical connector 131 formed integrally with the flange 21. The negative terminal 132 has a U-shaped portion 133 bent into a U-shape exposed to the outside of the resin, and the exposed portion is in contact with the gasket 134. Further, the outer peripheral edge portion 137 of the flange 21 is fixed to the upper tank 3 by the fixing member 135 and the flange holding plate 136.

  As shown in FIGS. 57 and 58, the flange-side electrical connector 131 and the pump-side electrical connector 33 are connected to the minus side and the plus side by lead wires 139 and 140, respectively. When the minus side terminal 132 of the flange side electrical connector 131 is integrally formed of synthetic resin, the minus side terminal 132 is connected to the inner periphery of the gasket 134 in a state where the flange 21 is attached to the opening of the fuel tank 1. It is exposed to the outside of the rib 143 so as to come into contact.

  Accordingly, the static electricity generated in the metal upper tank 3 is electrically short-circuited via the conductive gasket 134, the negative terminal 132, and the grounding lead wires 139 and 140. Trouble is prevented. According to the tenth embodiment, without providing a dedicated tank ground circuit, the number of parts can be reduced and a countermeasure against static electricity can be taken in a small space.

  Further, according to the tenth embodiment, the U-shaped portion 133 of the negative terminal 132 of the flange-side electrical connector 131 is a curved portion by press molding, so that the gasket 134 is prevented from being damaged or broken when the gasket 134 is mounted. To do. Furthermore, since the exposed portion of the U-shaped portion 133 of the negative terminal 132 has a diameter that is the same as or slightly larger than the outer diameter of the flange rib 143, it is possible to ensure electrical contact with the inner peripheral portion of the gasket 134. There is.

  FIG. 59 shows a side view and a cross-sectional view of the gasket 134 used in the tenth embodiment. The gasket 134 according to the tenth embodiment is an annular shape having an elliptical cross section, and the sealing surface 35a is sandwiched between the flange 21 and the fuel tank 1 to seal the fuel. Moreover, the 1st-4th modification which deform | transformed the shape of the gasket of this 10th Example is shown in FIGS. 60-6363.

  60 to 63, seal surfaces 351a, 352a, 3530a, and 354a of gaskets 351, 352, 353, and 354 are sandwiched between the flange and the fuel tank and have a function of receiving pressure and sealing the fuel in the tank. The gasket 351 of the first modification shown in FIG. 60 is an annular shape having a rectangular cross section, and upper and lower sealing surfaces 351a and 351a are sandwiched between a flange and a fuel tank to seal fuel.

  The gasket 352 of the second modification shown in FIG. 61 has a shape in which concentric double rings are arranged inside and outside and connected between them. The diameter da of the inner ring 3520 is substantially the same as the diameter db of the outer ring 3521, and the surface sealed between the flange and the fuel tank is mainly 352a. The effect of improving the function of the seal is obtained by these two rings.

  The gasket 353 of the third modified example shown in FIG. 62 has a shape in which the center part of the inner annular part 3530 and the outer annular part 3531 is connected, and in addition to this, there is a projection 3532 projecting radially outward. The upper surface 3532a or the side surface 3532b or 3532c of the terminal contacts the terminal. In this gasket 353, even if the protrusion is deformed by strong contact with the terminal, the deformation is absorbed by the outer annular portion 3531. Therefore, the seal surface 3530a is not deformed, and a good sealing effect can be obtained.

  The gasket 354 of the third modification shown in FIG. 63 has three protrusions at the top and bottom, and is sealed by the two upper and lower protrusion tip surfaces 354a on the inside, and contacts the terminal at the side surface 354b. This gasket 354 has the same effect as the gasket 353 of FIG. Next, modified examples of the minus side terminal fixed to the electrical connector 131 by insert molding are shown in FIGS.

(Eleventh embodiment)
The eleventh embodiment shown in FIG. 64A is the same as the tenth embodiment shown in FIG. 55, and the specific shape of the minus side terminal 132 is shown in FIGS. 64B and 64C. Since the operation and effects of the negative terminal of the eleventh embodiment are as described above, the description thereof is omitted.

(Twelfth embodiment)
A twelfth embodiment of the present invention is shown in FIG.
In the twelfth embodiment shown in FIG. 65, a terminal 142 separate from the terminal 141 is fixed to a linear negative terminal 141 by welding or soldering. The opposite side 142 a of the terminal 142 is exposed to the outside of the rib 143, and the exposed portion 144 is in electrical contact with the gasket 134.

(Thirteenth embodiment)
A thirteenth embodiment of the present invention is shown in FIG.
The thirteenth embodiment shown in FIG. 66 is an example in which a wide exposed portion 145 having a wide area is provided in a T shape on the exposed portion of the terminal 142. The T-shaped wide exposed portion is provided with a curvature radius smaller than that of the arc on the outer periphery of the rib 143. This is to make good electrical contact with the gasket 134.

(14th embodiment)
A fourteenth embodiment of the present invention is shown in FIG.
In the fourteenth embodiment shown in FIG. 67, a bent portion 147 is provided on the minus side terminal 146, and a separate terminal 148 is fixed to the bent portion 147 by welding or soldering. A T-shaped portion 149 that makes the electrical contact area good is formed in a T shape on the opposite side of the terminal 148.

(15th embodiment)
A fifteenth embodiment of the present invention is shown in FIG.
In the fifteenth embodiment shown in FIG. 68, a separate terminal 148 is fixed to the minus terminal 150 by welding, soldering, or the like, and a T-shaped portion 151 is provided on the non-fixed side.

(Sixteenth embodiment)
A sixteenth embodiment of the present invention is shown in FIG.
The sixteenth embodiment shown in FIG. 69 is an example in which a branch terminal 153 branched from the minus terminal 152 is provided, and a T-shaped portion 154 is formed on the opposite side of the branch terminal 153. According to the sixteenth embodiment, since the branch terminal 153 is formed integrally with the minus side terminal 152, there is an effect that the number of parts at the time of resin molding is reduced.

  As described above, the electrical connection with the fuel tank 1 through the minus side terminal of the flange side electrical connector 131 has been attempted. In either case, static electricity charged on the tank from the fuel tank 1 through the gasket 134 and the electrical connector minus terminal is exposed to the outside of the fuel tank. Grounded. Next, examples relating to improvement of the cushion portion of the fuel pump 14 accommodated in the fuel tank 1 are shown as FIGS. 70 to 92 as 17th to 21st examples.

(Seventeenth embodiment)
A seventeenth embodiment of the present invention is shown in FIGS.
The seventeenth embodiment shown in FIGS. 70 to 77 is an example in which the fuel pump 14 is suspended and fixed from the fuel tank 1 by a metal bracket 155. 72 shows the mounting state of the metal bracket to the fuel tank, FIGS. 7373 and 74 show the fuel pump and flange, FIGS. 75, 76 and 77 show the pump cushion, and FIGS. 70 and 7171 show the seventeenth embodiment. The attachment state of the fuel pump using the pump cushion which is the characteristic part of is shown.

  As shown in FIGS. 70 and 71, a positioning hole 163 is formed in the fuel pump seating surface 162 of the bracket 161. The protrusion 165 of the pump cushion 164 is fitted in the positioning hole 163. The fuel pump 14 sits on the upper surface of the pump cushion 164. As shown in FIGS. 73 and 74, the fuel pump 14 has a discharge portion 18 connected to a metal main tube 67, and the upper end of the main tube 67 extends from the pipe 173 outside the metal flange 172 to the injector side. Supplied. The flange 172 is provided with a return tube 174 for returning fuel from the engine side to the fuel tank side. Lead wires 175 and 176 are taken out from the pump-side electrical connector 33 of the fuel pump 14 and terminals 177 and 178 are provided outside the flange 172. The flange 172 is fixed by a retainer 171 provided on the upper side of the upper tank 3, a bolt 169, and a nut 170. 75, 76, and 77 show specific shapes of the pump cushion 164 interposed between the fuel pump 14 and the bracket 161 in order to make the fuel pump 14 sit on the bracket 161.

  The pump cushion 164 is made of rubber, and a positioning projection 165 is formed on the bracket 161 side. The positioning protrusion 165 is fitted into the positioning hole 163 (see FIG. 71) of the bracket 161. According to the seventeenth embodiment, since the protrusion 165 of the pump cushion 164 is inserted into the positioning hole 163 of the bracket 161, the pump cushion 161 is unlikely to come off when the fuel pump 14 is assembled to the bracket 161.

  Further, the pump cushion 161 is made of rubber, and it is not necessary to cut and remove the remaining molding gate by forming the remaining molding gate portion as the projection 165 when molding. Conventionally, the process of cutting and removing the molded gate portion of the pump cushion to avoid interference with the counterpart part has been required, which increases the cost. In this embodiment, the cutting process is omitted by leaving the molded gate remaining. This can reduce the cost. The diameter, size, position, shape and the like of the protrusion 165 can be set at the time of molding according to the counterpart component.

  Further, in this embodiment, there is an effect that the pump cushion 161 is not easily detached even if the product is inclined during the assembly. Furthermore, if the end of the gate portion after assembly of the pump cushion is in contact with the bottom surface of the fuel pump 14, the vibration reduction effect of the pump with bracket can be obtained.

(Eighteenth embodiment)
An eighteenth embodiment of the present invention is shown in FIGS.
The pump cushion 181 is made of rubber, and a positioning protrusion 182 for preventing the release is formed on the bottom surface side.

(Nineteenth embodiment)
A nineteenth embodiment of the present invention is shown in FIGS. The nineteenth embodiment shown in FIGS. 81, 82 and 83 is a pump cushion 184 having a different shape from the seventeenth and eighteenth embodiments. This pump cushion 184 is similarly provided with a positioning projection 185. Since the protrusion 185 fits into the positioning hole of the bracket, there is an effect that the pump cushion 184 is hardly detached from the bracket 161. Therefore, even if the pump posture or the like is inclined, the pump cushion is not easily detached, so that the assembly can be easily performed.
FIG. 84 shows the appearance of the fuel pump 14 seated on the pump cushion 184.

(20th embodiment)
A 20th embodiment of the present invention is shown in FIGS. 85, 86, 87, and 88, the in-tank type fuel pump 402 is obtained by changing the shape of the bracket that holds the fuel pump 14 to another shape. That is, the bracket 405 that supports the fuel pump 14 in order to suspend and fix the fuel pump 14 from the fuel tank 1 is made of metal.

  Also in this embodiment, the fuel pump 14 is seated on the bracket 405 via the pump cushion 403 on the lower surface of the fuel pump 14. The pump cushion 403 has the protrusion 404 as described above, and the protrusion 404 is fitted into the positioning hole of the bracket 405 to prevent the pump cushion 403 from coming off from the bracket 405.

(21st Example)
A twenty-first embodiment of the present invention is shown in FIGS.
The twenty-first embodiment shown in FIG. 89 is an example using a resin bracket (fuel pump housing case). The bracket is a pump case 16 that accommodates the fuel pump 14.

  In the twenty-first embodiment shown in FIG. 89, the fuel pump 14 is accommodated in a pump case 16 that is a resin bracket, and the upper end of the pump case 16 is snap-fitted to the resin flange 21 so that the fuel is supplied from the fuel tank 1. This is an example in which the pump 14 is suspended and fixed. In the twenty-first embodiment as well, the pump cushion 164 is seated under the fuel pump 14 so that the pump cushion 164 is mounted without slipping out of the pump case 16 that accommodates the fuel pump 14. A fuel pump 14 may be provided on the top. 90, 91, and 92 are views showing that a protrusion is provided on the bottom of the pump case 16. FIG.

(Twenty-second embodiment)
A twenty-second embodiment of the present invention is shown in FIG.
A twenty-second embodiment shown in FIG. 93 is an example in which a protrusion 102 a protrudes in the fuel passage 102 of the main tube 101 integrated with the flange 21 in the direction opposite to the flange 21. By receiving any load acting on the protrusion 102a from the side opposite to the flange 21, the protrusion 102a can prevent the load from being applied to the fuel passage 103 portion of the main tube 101. Furthermore, by increasing the protrusion dimension of the protrusion 102a, it is possible to prevent a load from being applied to the quick connector even when the quick connector is attached to the main tube 101.

(23rd embodiment)
A twenty-third embodiment of the present invention is shown in FIGS.
In the twenty-third embodiment shown in FIGS. 94 to 101, the case portion suspended from the flange 21 is composed of a pump case 331 and a bracket 341, and the flange 21, pump case 331 and bracket 341 are divided into three parts. Yes. The upper claw 332 of the pump case 331 is snapped into the fitting hole 322 of the flange 21. Further, the lower claw 333 on the lower side of the pump case 331 is snap-fitted into the fitting hole 342 of the bracket 341. A plurality of fitting holes 322 in the flange 21 are provided on the lower end side of the flange 21 in the circumferential direction at positions where the fitting holes 322 can be coupled to the pump case 331. Further, the positions of the fitting holes 322 and the upper claws 332 are provided at 120 degree intervals in the circumferential direction, so that the weight balance can be made substantially uniform and the upper claws 332 can be prevented from being damaged or broken. Similarly, the fitting holes 342 of the bracket 341 that is fitted to the lower claws 333 of the lower part of the pump case 331 are also provided at approximately 120 degrees equally in the circumferential direction. As a result, the weight balance becomes uniform, and breakage and destruction of the specific lower claws 333 can be prevented.

  As shown in FIGS. 94 and 95, the flange portion 21 has a plurality of slit portions 323 at the head portion. Thereby, the snap fit effect when the upper claw 332 is elastically fitted to the fitting hole 322 is enhanced. The slit portion 323 can also be used as a lead for a fuel pump supply power source. The main tube 101 is connected to a return tube 381, and a passage in the return tube 381 is further connected to a fuel filter 383 from a pressure regulator 382.

  The lower end portion of the slit portion 323 of the flange 21 is chamfered or curved. This prevents cutting of the lead wire when the slit portion 323 is used for handling the lead wire or the like. Further, the inner surface of the lower end of the flange rib portion 325 on the case side is chamfered or curved. Thereby, there is an effect that the pump case 331 can be easily inserted and assembled into the cylindrical portion of the flange 21. As shown in FIG. 96, the main tube 101 is provided with a main tube rib portion 324 for reinforcement.

  As shown in FIGS. 99, 100, and 101, a concave portion 326 is provided on the inner wall side at the lower portion of the fitting hole 322 at the lower end portion of the cylindrical flange rib portion 325. The concave portion 326 is formed by a hatched portion in FIGS. 100 and 101. Accordingly, when the upper claw 332 of the pump case 331 is inserted into the fitting hole 322 from the lower end side of the flange rib portion 325, the recess 326 allows the portion to be slid and easily snap-fit fitted. .

  According to the twenty-third embodiment, since the flange rib portion 325, the pump case 331, and the flange 341 are divided into three parts, there is an effect that the fuel pump can be easily replaced. In the 23rd embodiment, since a plurality of fitting holes 322 are provided in the circumferential direction on the lower end side of the flange rib portion 325, the upper claw 332 of the pump case 331 is snap-fit fitted to the flange rib portion 325 for easy assembly and removal. There is an effect that can be done. Further, when the upper claw 332 and the fitting hole 322 are inserted, the recess 326 is made to slide so that the snap fit can be easily performed, so that the concave portion 326 is a lower portion of the fitting hole 322 on the lower end side of the inner peripheral wall of the flange rib portion 325. Therefore, there is an effect that snap-fit fitting can be easily performed. This means that by inserting a tool such as a flat-blade screwdriver into the concave portion 326, the snap-fit fitting can be easily released at the time of removal.

(24th embodiment)
A twenty-fourth embodiment of the present invention is shown in FIGS.
In the twenty-fourth embodiment, instead of the structure shown in FIGS. 100 and 101 of the twenty-third embodiment, a convex portion 327 is formed by projecting a radially outer portion of the concave portion 326 of the flange rib portion 325. is there. Since the portion where the thickness of the concave portion 326 is thin at the convex portion 327 is thickened on the opposite side surface, there is a reinforcing effect by making the thickness of the flange rib portion 325 the same.

(25th embodiment)
A twenty-fifth embodiment of the present invention is shown in FIGS.
The twenty-fifth embodiment shown in FIGS. 104 to 106 is an example in which windows 327 and 328 are additionally added in the circumferential direction in the axial direction of the flange rib portion 325. According to the twenty-fifth embodiment, the weight of the flange 21 can be reduced and the material cost can be reduced. Since the windows are formed by sliding in the same direction in the axial direction and aligned in the axial direction, the height of the pump is assembled. Can be changed by position. As a result, in-tank fuel pump brackets corresponding to fuel tanks of various depths can be assembled, thereby reducing costs. Furthermore, when the fuel in the fuel tank moves due to the impact, the impact effect is alleviated and the fuel flows through the window portions 327 and 328 so that the impact is reduced and the baffle effect is increased. Therefore, the lateral load of the flange rib portion 325 is reduced, and the rib strength is increased.

(Twenty-sixth embodiment)
A twenty-sixth embodiment of the present invention is shown in FIGS.
By using the pump case 331 of the twenty-sixth embodiment, the pump case 331 and the flange 21 can be easily attached and detached, and the bracket 341 and the pump case 331 can be easily attached or detached.

(Twenty-seventh embodiment)
A twenty-seventh embodiment of the present invention is shown in FIG.
The twenty-seventh embodiment shown in FIG. 110 is an example in which a mounting / removal recess 334 is provided below the upper claw 332 of the pump case 331. Further, an attachment / removal recess 335 is formed on the upper side of the lower claw 333. By forming the recesses 334 and 335, when releasing the snap fit, a tool such as a flathead screwdriver is pushed into the recess 334 or 335 to widen the rib portion, thereby releasing the upper claw 332 and the fitting hole 322 and lower claw 333. And the fitting hole 342 can be easily released.

(Twenty-eighth embodiment)
A twenty-eighth embodiment of the present invention is shown in FIG.
The twenty-eighth embodiment shown in FIG. 111 is an example in which a window portion 336 that communicates the inside and outside of the pump case in the axial direction of the pump case 331 is formed. The window 336 extends in the axial direction when focusing on one window, and a plurality of the windows 336 are formed in the circumferential direction of the outer periphery of the pump case.

  According to the twenty-eighth embodiment, since the fuel in the fuel tank flows through the window 336, the fuel in the vehicle mounted with the fuel tank is not turned down and the fuel is turned when suddenly starting and stopping. The impact force that the liquid wave generated in the tank gives to the pump case 331 and the flange 21 can be reduced. Therefore, the pump case 331 and the flange 21 can be effectively prevented from being damaged.

(Twenty-ninth embodiment)
A twenty-ninth embodiment of the present invention is shown in FIGS.
The twenty-ninth embodiment shown in FIGS. 112 and 113 shows the appearance of the bracket 341. A plurality of fitting holes 342 are formed in the bracket 341 in the circumferential direction to fit into the lower claws 333 of the pump case 331. In this embodiment, there is no removal recess.

  When the bracket 341 of the 29th embodiment is used, three side wall portions 341b, 341c, 341d protrude from the bottom portion 341a, and fitting holes are formed in the side wall portions, so that the lower claws 333 of the pump case 331 are formed. Can be easily attached and detached by releasing the snap fit.

(30th embodiment)
A thirtieth embodiment of the present invention is shown in FIGS.
In the 30th embodiment shown in FIGS. 114 and 115, the lengths of the window portions 343 and 344 in which the claw portion on the pump case 331 side engages with the bracket 341 are extended in the axial direction of the bracket 341. Since the window portion 343 extends in the axial direction, the remaining space portion where the claws are fitted serves as a passage through which fuel in the tank flows, and has a baffle effect. In addition to the function of fitting the lower claws 333 of the pump case 331, the window 344 has a role of functioning as a hole for discharging the vapor of the fuel pump.
In this embodiment, since the window portion can be formed by the vertical slide core without using the circumferential slide core, the cost is reduced.

(Thirty-first embodiment)
A thirty-first embodiment of the present invention is shown in FIGS.
116 and 117 is an example in which a concave portion 345 is formed in the bracket inner peripheral wall on the lower side from the fitting hole 342 of the bracket 341. The recess 345 is formed on the pump case 331 side of the fitting hole 342. Thereby, there exists an effect that snap fit cancellation | release can be easily performed using this recessed part 345. FIG.

(Thirty-second embodiment)
A thirty-second embodiment of the present invention is shown in FIGS. 118 and 119.
The thirty-second embodiment shown in FIGS. 118 and 119 is an example in which a window portion 346 is formed in the bracket 341. The window portion 346 is a circular hole that communicates the inside and outside of the bracket. As a result, the weight of the bracket 341 can be reduced.

(Thirty-third embodiment)
A thirty-third embodiment of the present invention is shown in FIG.
120, the main tube 351, the return tube 352, the breather tube 353, and the electrical connectors are formed from the top of the flange 21 to the outside. On the outer periphery of each of the tubes 351, 352, and 353, annular convex portions 354, 355, and 356 are provided for preventing the quick connector from coming off. The convex portions 354, 355, and 356 are all provided on the radially outer side as viewed from above the maximum outer diameter of the flange 21. By carrying out like this, when carrying out resin mold shaping, mold cutting can be easily carried out by performing die cutting by the convex parts 354, 355, and 356.

  In this embodiment, the main tube 351, the return tube 352, and the breather tube 353 are taken out in the same direction or in the opposite direction, which simplifies the structure of dividing the mold and leads to cost reduction.

(Thirty-fourth embodiment)
A thirty-fourth embodiment of the present invention is shown in FIG.
The thirty-fourth embodiment shown in FIG. 121 is an example in which the length of the sender gauge 361 for detecting the fuel level is made variable according to the tank depth. One end of the stay 364 is fixed to the boss portion 362 of the flange 21 with a screw 363, and the other end is fixed to the sender gauge body 366 with a screw 365. The other end of the float arm 367 that fixes the float 368 to one end is fixed to the sender gauge body 366. The position of the float 368 can be adjusted to the tank depth by loosening the screw 365 and changing the relative position of the stay 364 to the sender gauge body 366.

(Thirty-fifth embodiment)
A thirty-fifth embodiment of the present invention is shown in FIGS.
The 35th embodiment shown in FIGS. 122 and 123 is an example in which one end of a separate nylon tube 372 is fixed to a lower end of a return tube portion 371 formed on the flange 21 by a clip 373. The nylon tube 372 is fixed by a clamp portion 374 protruding from the pump case 331, or has a gap as shown in FIG. 123 with a guide function, and may be displaced by the gap. However, since the tip of the clamp portion 374 is smaller than the outer diameter of the nylon tube 372, it does not come off. Although the nylon tube 372 is used, a rubber hose or the like may be used in the present invention.

(Thirty-sixth embodiment)
A thirty-sixth embodiment of the present invention is shown in FIG.
The thirty-sixth embodiment is an example different from the first embodiment in the shape of a metal plate that functions as a sender gauge mounting portion and a mounting bracket for a sender cage.
As shown in FIG. 124, the metal plate 742 has push claws 743a and 743b projecting in the width direction of the metal plate 742 from the upper position in FIG. 124 by a predetermined distance with respect to the outer lower portion 42a. A wider press-fit portion 743 is formed. In addition, the metal plate 742 is provided with two press punching portions 744 for positioning in a convex shape in the radially inward direction of the pump case 16.

  The guide portions 763 and 764 of the sender gauge mounting portion 760 to which the metal plate 742 is assembled are formed following the flat plate-like tightening portions 763a and 764a provided at the metal plate insertion start end, and the tightening portions 763a and 764a. Groove portions 763b and 764b having an L-shaped cross section. The guide portions 763 and 764 are provided with a gradient so that the interval between the inner walls facing each other gradually becomes narrower downward in FIG. In FIG. 124 of the groove portions 763b and 764b, the gap is wider than the width of the outer lower portion 42a of the metal plate 742 at the upper end and substantially equal to the width of the outer lower portion 42a at the lower end, and the press-fit portion of the metal plate 742 at the tightening portions 763a and 764a. It is narrower than the width of 743 and wider than the width of the outer lower portion 42a. In addition, the positioning projections 861 and 862 of the sender gauge mounting portion 760 are provided with a gradient so that the width gradually increases downward in FIG. 124, and thereby the positioning projection corresponding to the outside in the width direction of the sender gauge 760. The distance between the side surfaces of the portions 861 and 862 gradually increases toward the lower side in FIG. In FIG. 124 of the positioning convex portions 861 and 862, the interval is wider than the distance between the side surfaces of the two press punching portions 744 at the upper end and narrower than the distance between the press punching portions 744 at the lower end. The structure of the other parts is substantially the same as that of the first embodiment.

  When the metal plate 742 is assembled to the sender gauge mounting portion 760 and the metal plate 742 is inserted into the grooves 763b and 764b from above in FIG. 42a is sandwiched. At the same time, the side surfaces of the two press punching portions 744 are gradually tightened while the side surfaces of the positioning convex portions 861 and 862 are in contact with each other, whereby the assembly direction of the metal plate 742 is restricted. Then, the lower end of the metal plate 742 gets over the snap fit portion 865 so that the detachment prevention hole 45 of the metal plate 742 is fitted into the snap fit portion 865, and the press-fit portion 743 is press-fitted between the tightening portions 763a and 764a. Assembly is completed at the stage. At this time, the lower end of the metal plate 742 abuts on the locking portions 866 and 867 of the sender gauge mounting portion 760 or has a slight gap between the locking portions 866 and 867. As shown in FIG. 124, the contact positions 763c and 764c between the press claws 743a and 743b of the press-fit portion 743 and the tightening portions 763a and 764a are upward in FIG. 124 from the metal plate insertion start ends of the grooves 763b and 764b. A certain distance away.

  In order to assemble the sender gauge to the pump case, an assembly space is required at the upper end of the sender gauge. If the length of the metal plate is shortened for the purpose of reducing the space for assembling the sender gauge, the backlash of the sender gauge increases and the liquid level detection accuracy decreases. In addition, since the order of assembling the sender gauge cannot be set arbitrarily, the process design is restricted.

  According to the thirty-sixth embodiment, the press-fitting portion 743 is press-fitted between the tightening portions 763a and 764a at the end of the assembly, whereby the metal plate 742 is moved in the width direction and the rotation direction at the upper and lower ends of the guide portions 743 and 744. Since the movement is restricted, rattling after the metal plate 742 is assembled can be effectively suppressed even when the lengths of the guide portions 743 and 744 are relatively short. Thereby, since the positional accuracy of the sender gauge assembled through the metal plate 742 is improved, there is an effect that the liquid level detection accuracy is increased. The contact positions 763c and 764c of the flat plate-like tightening portions 763a and 764b and the push claws 743a and 743b are separated from the metal plate insertion start ends of the groove portions 763b and 764b by a predetermined distance, and therefore the tightening portions are pushed by the push claws 743a and 743b. 763a and 764b are easy to expand. For this reason, it is easy to press-fit the press-fit portion 743 into the tightening portions 763a and 764a. Further, tightening portions 763a and 764b are provided at the metal plate insertion start ends of the guide portions 763 and 764 in place of the L-shaped grooves 763b and 764b. Since the tightening portions 763a and 764b are flat and open to the outer peripheral side of the pump case 16, the slide length when the metal plate 742 is attached / detached is only the length of the groove portions 763b and 764b. Therefore, the sender gauge mounting space required above the guide portions 763 and 764 can be reduced.

(Thirty-seventh embodiment)
A thirty-seventh embodiment of the present invention is shown in FIGS.
The thirty-seventh embodiment relates to the structure of the fuel supply portion, the fuel return portion of the fuel return portion, and the molding die that are made into a returnless system. As shown in FIG. 125, a fuel supply pipe 713 connected to the fuel pump discharge part and a fuel return pipe 714 connected to the pressure regulator penetrate the disc part 211 and are integrally formed with the flange 21 in the flange 21. Has been. From the upper end of the fuel supply pipe 713, a main tube 711 for supplying fuel to the engine side and a return tube 712 connected to the fuel return pipe 714 extend perpendicularly to the fuel supply pipe 713 in opposite directions. A fuel supply unit 701 is configured by the fuel supply pipe 713 and the main tube 711, and a fuel return unit 702 is configured by the return tube 712 and the fuel return pipe 714. Fuel passages 721, 722, 723, and 724 are formed inside the main tube 711, the return tube 712, the fuel supply pipe 713, and the fuel return pipe 714, respectively.

  The fuel delivered from the discharge part of the fuel pump into the fuel supply pipe 713 is branched at the upper end of the fuel supply pipe 713 into a main side from the main tube 711 to the engine and a return side from the return tube 712 to the pressure regulator. The The fuel to the return side is adjusted to a predetermined pressure by the pressure regulator, the fuel corresponding to the consumption of the engine is pumped to the main side, and the remaining surplus fuel is a fuel filter disposed downstream of the pressure regulator. And return to the tank.

  The fuel passages 721, 722, 723, 724 are formed inside the fuel supply unit 701 and the fuel return unit 702 as follows. A supply passage pin 732 that forms a fuel passage 713 from the discharge part of the fuel pump to the main tube 712 and a return passage pin 733 that forms a fuel passage 714 from the return tube 712 to the pressure regulator are in the vertical direction in FIG. Set in the vertical direction. And the main tube pin 731 which penetrates the upper part of the supply channel | path pin 732 and the return channel | path pin 733 and forms the fuel channel | paths 721 and 722 is set to the horizontal direction which is the left-right direction in FIG.

  Here, the diameter of the supply passage pin 732 is larger than the diameter of the main tube pin 731 at the interphase portion between the supply passage pin 732 and the main tube pin 731. As a result, the volume of the passage from the fuel passage 713 to the fuel passage 721 decreases, so that a damper portion is formed, and pump vibration and the like can be reduced by this damper portion. Furthermore, it is possible to reduce the weight by thinning the outer portion of the interpenetrating portion and to simplify the mold splitting structure of the mold. In addition, the diameter of the return passage pin 733 is larger than the diameter of the main tube pin 731 at the joint portion between the return passage pin 733 and the main tube pin 731. As a result, the volume of the passage from the fuel passage 714 to the fuel passage 721 decreases, so that a damper portion is formed, and pump vibration and the like can be reduced by this damper portion. Furthermore, it is possible to reduce the weight by thinning the outer portion of the interpenetrating portion and to simplify the mold splitting structure of the mold.

  Further, since the main tube pin 731 is set through the upper part of the supply passage pin 732 and the return passage pin 733, the following effects can be obtained. When a main tube, an electrical connector, or the like is integrally formed on the flange, it is necessary to increase the length of the main tube pin depending on the dividing structure of the forming die. However, since the main tube pin is thinned toward the tip end of the die for easy removal of the die, the main tube pin 631 is provided with the supply passage pin 632 and the return passage pin as in the comparative example shown in FIG. In the configuration in contact with the upper portion of 633, the longer the main tube pin 631, the smaller the diameter of the main tube pin 631 at this contact position, and the position of the main tube pin 631 tends to become unstable due to resin molding pressure or the like. For example, when resin is injected from the outer peripheral side of the flange, the main tube pin 631 is lifted from the upper part of the supply passage pin 632 and the return passage pin 633 by the resin pressure as shown in FIG. The resin flows into the gap 630 with the return passage pin 633 and hardens, so that a resin thin film is formed in the fuel passage portion and the fuel passage becomes insufficient. Although this thin film can be removed by processing after molding, there is a problem that the cost is increased, and if the cutting powder remains, there is a problem of entering the pressure regulator, so it is necessary to remove the cutting powder.

  According to the thirty-seventh embodiment, since the main tube pin 731 passes through the upper part of the supply passage pin 732 and the return passage pin 733, the formation of a thin film in the fuel passage portion can be prevented. As shown in FIG. 125, since the resin injection gate is provided above the main tube pin 731, the resin injection pressure is applied in the direction in which the main tube pin 731 presses the supply passage pin 732 and the return passage pin 733. The structure in which the tube pin 731 is in contact with the upper portions of the supply passage pin 732 and the return passage pin 733 is also effective in preventing the generation of a thin film.

1 is a side perspective view showing an in-tank fuel pump apparatus according to a first embodiment of the present invention. FIG. 2 is a plan perspective view of FIG. 1. It is a bottom view of FIG. It is the side perspective view seen from another angle of FIG. It is the VV sectional view taken on the line shown in FIG. It is the VI-VI sectional view taken on the line shown in FIG. It is sectional drawing which shows the state which attached the in-tank type fuel pump apparatus of 1st Example of this invention in the fuel tank. It is a figure which shows the components structure of 1st Example. The pump case of 1st Example of this invention is shown, (A) is an A direction arrow view shown in FIG. 10, (B) is a B direction arrow view shown in FIG. 10, (C) is FIG. It is a C direction arrow line view shown. FIG. 10 is a plan view of FIG. 9. FIG. 10 is a bottom view of FIG. 9. It is the XII-XII sectional view taken on the line shown in FIG. It is the XIII-XIII sectional view taken on the line shown in FIG. It is an enlarged view of the XIV part shown in FIG. It is a top view of the pump case of 1st Example. It is an enlarged view of the XVI part shown in FIG. It is arrow XVII direction arrow directional view shown in FIG. It is a XVIII direction arrow line view shown in FIG. It is the XIX-XIX sectional view taken on the line shown in FIG. It is a top view of a sender gauge. FIG. 21 is a view in the direction of arrow XXI in FIG. 20. It is arrow XXII direction arrow line view of FIG. It is a top view which shows an electrical component. It is a XXIV direction arrow directional view shown in FIG. It is a XXV direction arrow line view shown in FIG. It is a front view of a fuel pump. It is a XXVII direction arrow line view shown in FIG. It is a XXVIII direction arrow line view shown in FIG. It is a front view of a pump cushion. It is a XXX direction arrow line view shown in FIG. It is a XXXI direction arrow directional view shown in FIG. It is sectional drawing which shows the fuel tank attachment state of 2nd Example which is a modification of a return fuel channel | path part. It is a top view which shows the fuel pump case of 3rd Example which is a modification of a fuel pump case. It is a figure which shows the 4th Example which is a modification of a return tube. It is a figure which shows 5th Example which is a modification of a return tube lower end part. (A) is a figure which shows 6th Example which is a modification of a capacitor | condenser attachment part, (B) is the B direction arrow directional view. FIG. 34A is an enlarged view of the capacitor lead fixing portion of FIG. 33, and FIG. (A) is a figure which shows the 7th Example which is a modification of a pump case, (B) is the figure seen from the different angle. The in-tank type fuel pump apparatus by 8th Example of this invention is shown, (A) is a top view, (B) is the B direction arrow view. It is a side view of the in-tank type fuel pump apparatus of 8th Example. It is sectional drawing which shows the fuel tank attachment state of 8th Example. The protection plate mounting | wearing state of 9th Example is shown, (A) is a top view, (B) is a B direction arrow view of (A), (C) is a C direction arrow view of (B). . The in-tank type fuel pump apparatus which can mount | wear with the protective cover of 9th Example is shown, (A) is the top view, (B) is a B direction arrow directional view. It is a side view of the in-tank type fuel pump apparatus of 9th Example. The modification of a protection plate is shown, A is a top view, B is the B direction arrow view of A, C is the C direction arrow view of B. The modification of a protection plate is shown, A is a top view, B is the B direction arrow view of A, C is the C direction arrow view of B. The modification of a protection plate is shown, A is a top view, B is the B direction arrow view of A, C is the C direction arrow view of B. The modification of a protection plate is shown, A is a top view, B is the B direction arrow view of A, C is the C direction arrow view of B. The modification of a protection plate is shown, A is a top view, B is the B direction arrow view of A, C is the C direction arrow view of B. The modification of a protection plate is shown, A is a top view, B is the B direction arrow view of A, C is the C direction arrow view of B. The modification of a protection plate is shown, A is a top view, B is the B direction arrow view of A, C is the C direction arrow view of B. The modification of a protection plate is shown, A is a top view, B is the B direction arrow view of A, C is the C direction arrow view of B. The modification of a protection plate is shown, A is a top view, B is the B direction arrow view of A, C is the C direction arrow view of B. The modification of a protection plate is shown, A is a top view, B is the B direction arrow view of A, C is the C direction arrow view of B. It shows the principal part of 10th Example, and is the sectional view on the AA line of FIG. It is sectional drawing which shows the fuel tank attachment state of 10th Example. It is a top view of the in-tank type fuel pump apparatus of 10th Example. It is a side view of the in-tank type fuel pump apparatus of 10th Example. The modification of the gasket of 10th Example is shown, (A) is a top view, (B) is the cross-sectional view. The modification of a gasket is shown, (A) is a top view, (B) is the cross-sectional view. The modification of a gasket is shown, (A) is a top view, (B) is the cross-sectional view. The modification of a gasket is shown, (A) is a top view, (B) is the cross-sectional view. The modification of a gasket is shown, (A) is a top view, (B) is the cross-sectional view. It is sectional drawing of the flange side electrical connector part of 11th Example. It is sectional drawing of the flange side electrical connector part of 12th Example. It is sectional drawing of the flange side electrical connector part of 13th Example. It is sectional drawing of the flange side electrical connector part of 14th Example. It is sectional drawing of the flange side electrical connector part of 15th Example. It is sectional drawing of the flange side electrical connector part of 16th Example. It is a principal part partial notch figure of 17th Example of this invention. It is an A direction arrow directional view shown in FIG. It is sectional drawing which shows the fuel tank attachment state of 17th Example of this invention. It is a top view of the in-tank type fuel pump of 17th Example of this invention. It is a side view of the in-tank type fuel pump of 17th Example of this invention. It is a top view of the pump cushion of 17th Example of this invention. It is a B direction arrow line view of FIG. It is a C direction arrow directional view of FIG. It is a top view of the pump cushion of 18th Example. It is a side view of the pump cushion of 18th Example. It is a bottom view of the pump cushion of 18th Example. It is a top view of the pump cushion of 19th Example. It is a side view of the pump cushion of 19th Example. It is a bottom view of the pump cushion of 19th Example. The fuel pump of 19th Example is shown, (A) is a top view, (B) is a side view, (C) is a bottom view. It is a top view of the in-tank type fuel pump of 20th Example. It is a side view of the in-tank type fuel pump of 20th Example. It is the side view seen from the angle different from FIG. It is a bottom view of the in-tank type pump of 20th Example. It is sectional drawing which shows the fuel tank attachment state of 21st Example. It is a top view of the in-tank type pump apparatus of 21st Example. It is a side view of the in-tank type fuel pump of 21st Example. It is a bottom view of the in-tank type pump of 21st Example. It is a side view which shows the protrusion part of the in-tank type fuel pump of 22nd Example. It is a side view of the in-tank type fuel pump apparatus of 23rd Example of this invention. It is the side view seen from another angle of 23rd Example. It is a top view of the flange of 23rd Example. It is a side view of the flange of 23rd Example. It is the side view of the flange seen from another angle of 23rd Example. It is a bottom view of the flange of 23rd Example. FIG. 99 is an enlarged view of part A of FIG. 99. It is the BB sectional view taken on the line shown in FIG. It is a figure which shows the fitting hole for snap fits of 24th Example. It is a BB sectional view taken on the line shown in FIG. It is a top view of the flange of 25th Example. It is a side view of the flange of 25th Example. It is the side view seen from another angle of the flange of 25th Example. It is a top view of the pump case of 26th Example. It is a side view of the pump case of 26th Example. It is a bottom view of the pump case of 26th Example. It is a side view of the pump case of 27th Example. It is a side view of the pump case of 28th Example. It is an expanded view of the bracket of 29th Example. It is a side view of the bracket of 29th Example. It is an expanded view which shows the bracket of 30th Example. It is a side view of the bracket of 30th Example. It is an expanded view of the bracket of 31st Example. It is a side view of the bracket of 31st Example. It is an expanded view of the bracket of 32nd Example. It is a side view of the bracket of 32nd Example. It is a top view which shows the in-tank type pump apparatus of 33rd Example. It is a side view of the in-tank type pump apparatus of 34th Example. It is a side view of the in-tank type pump apparatus of 35th Example. It is AA sectional view taken on the line shown in FIG. It is a side view of the in-tank type fuel pump apparatus of 36th Example. It is a fragmentary sectional view at the time of shaping | molding of the in-tank type fuel pump apparatus of 37th Example. The pin state used for molding of an in-tank type fuel pump device as a comparative example is shown before the resin is injected, (A) is a side view, and (B) is a cross-sectional view taken along line CXXVI-CXXVI. The state at the time of resin injection | pouring of the pin used for the shaping | molding of the in-tank type fuel pump apparatus as a comparative example is shown, (A) is a side view, (B) is the CXXVII-CXXVII sectional view taken on the line.

Explanation of symbols

  1: fuel tank, 2: in-tank fuel pump device, 3: upper tank, 4: lower tank, 10: fuel filler port, 13: fuel filter, 14: fuel pump, 16: pump case, 18: discharge part, 21 : Flange, 24: Cylinder, 25: Vapor discharge port, 27, 28: Claw part, 31: Electrical part, 32: Capacitor, 33: Fuel pump side connector, 34: Flange side connector, 41: Sender gauge, 51: Pump Cushion 61: Discharge part 71: Pump part 72: Motor part 73: Discharge part 74: Power supply part 81: Pump attachment part 82: Suspension fixing part 83: Capacitor attachment part 84: Return Fuel passage portion, 85: Remaining amount warning display attaching portion, 86: Sender gauge attaching portion, 101: Main tube, 102, 103: Fuel passage, 104: Convex portion, 106: Main tube Protective plate, 109: protective plate, 110: cover portion, 111: protective plate portion, 115, 116: claw portion, 117, 118: hole, 120: quick connector, 131: flange side electrical connector, 132: negative side terminal 133: U-shaped part, 143: rib, 211: disk part, 212: rib, 213: fuel supply part, 214: fuel return part, 831: capacitor case part, 832: capacitor lead wire fixing part, 841: communication Hole, 842: Return tube, 844: Snap fit mounting hole, 851: Thermistor case part, 852: Thermistor cap part

Claims (12)

An in-tank type fuel pump device in which a fuel pump for pumping fuel in a fuel tank is provided in the fuel tank,
A resin pump case that houses the fuel pump so as to cover the outer peripheral surface of the fuel pump,
The pump case has a vapor discharge hole,
Wherein and sender gauge mounting portion is formed in the pump casing, the sender gauge attachment portion have a fitting structure of the snap-fit,
The counterpart sender gauge also has a snap-fit fitting structure,
The in-tank type fuel pump device , wherein the sender gauge mounting part has a concave groove part that forms a space part with a narrowed tip part .   2. The in-tank fuel pump device according to claim 1, further comprising a lower end wall surface at a tip portion of the concave groove portion.   2. The in-tank fuel pump device according to claim 1, wherein the sender gauge mounting portion has a convex protrusion that becomes wider toward the tip.   4. The in-tank type fuel pump device according to claim 2, wherein the pump case has a return fuel passage portion having a fuel return passage formed outside thereof.   The in-tank fuel pump device according to claim 4, wherein the return fuel passage portion has a snap-fit fitting structure with a flange side member.   The in-tank fuel pump device according to claim 4, wherein the return fuel passage portion has a pipe detachable shape portion at a lower end portion. The outer periphery of the pump case, Intan click type fuel pump apparatus according to any one of claims 1 to 6, further comprising a tank component case being formed integrally with the pump case.   8. The tank part case is a thermistor case for accommodating a thermistor, wherein the thermistor case has a lid on the top, and the lid is attached to the thermistor case by a hinge portion. In-tank fuel pump device.   9. The in-tank fuel pump device according to claim 8, wherein a claw portion is provided on an outer peripheral portion of the lid.   An in-tank type fuel pump device in which a fuel pump for pumping fuel in a fuel tank is provided in the fuel tank,
  A resin-made pump case for housing the fuel pump so as to cover the outer peripheral surface of the fuel pump; and a tank internal part case for storing the tank internal parts mounted on the fuel tank,
  The tank part case is formed by integral molding on the outer periphery of the pump case,
  The pump case has a vapor discharge hole,
  The in-tank fuel is characterized in that the tank case is a thermistor housing a thermistor, and the thermistor case has a lid on the top, and the lid is attached to the thermistor case by a hinge portion. Pump device.   The in-tank type fuel pump device according to claim 10, wherein a claw portion is provided on an outer peripheral portion of the lid.   The pump case includes a pump receiving surface that receives gravity acting on the fuel pump, and a pump side surface that regulates movement perpendicular to the direction of gravity acting on the fuel pump, and the pump case includes the fuel pump. The in-tank type fuel pump device according to any one of claims 1 to 11, wherein a pump insertion opening is provided at an opposite portion of the pump receiving surface so that the gas can be inserted from above.

Images