JP3552270B2 - Jet pump and fuel supply device - Google Patents

Abstract

PURPOSE:To provide a constitution in which vapor generated in a jet pump is not sucked by a fuel pump and also is not collected in a jet pump. CONSTITUTION:A shield plate 7 which bends a flow of fuel which is jetted from an outlet pipe of a jet pump 6 in a desired direction which is different from a direction of a filter 5 of a fuel pump 4 is provided in the jet pump 6. The shield plate 7 forms an opening which is opened immediately after the outlet pipe of the jet pump 6. Consequently, vapor which comes out of the outlet pipe is quickly released to the outside to suppress obstruction of the flow of fuel from the outlet pipe.

Description

[0001]
[Industrial applications]
The present invention provides a fuel supply device that supplies fuel to an internal combustion engine or the like, and prevents a fuel pump from sucking air bubbles generated by a jet pump that transfers fuel from one fuel tank to the other fuel tank, as well as a jet pump. The present invention relates to a device that can also prevent vapor lock in the inside.
[0002]
[Prior art]
Conventionally, in a four-wheel drive vehicle or the like, a saddle-type fuel tank in which the inside of the fuel tank is inflated is used to pass a propeller shaft. In a fuel tank having such two fuel tank spaces, a jet pump is provided in one of the fuel tanks, and fuel is transferred from the other fuel tank by the jet pump.
[0003]
However, when the fuel is transferred by the jet pump, bubbles may be generated in the fuel tank by the jet pump, and the bubbles may be sent to the internal combustion engine through the fuel pump.
Therefore, as a solution to such a problem, as shown in FIG. 5, a configuration is adopted in which a guide pipe for guiding fuel in a predetermined direction at the tip of the outlet pipe so that the fuel pump does not suck the fuel is fixed with a mounting clip. , Has been used.
[0004]
[Problems to be solved by the invention]
However, in such a configuration, the low boiling point component of the fuel at high temperature is vaporized by the negative pressure in the jet pump, and the vapor accumulates in the jet pump, so that the jet pump cannot absorb fuel. The vapor lock phenomenon had occurred.
[0005]
SUMMARY OF THE INVENTION In view of the above problems, the present invention is applied to a fuel supply device including a jet pump, in which a vapor generated by the jet pump causes no vapor lock phenomenon in the jet pump or the fuel pump, and is used for the device. The purpose of the present invention is to provide a jet pump that can be used.
[0006]
[Means for Solving the Problems]
In order to achieve the above object, a first invention provides
An inlet pipe,
An outlet pipe,
A nozzle provided between the inlet pipe and the outlet pipe,
A negative pressure chamber provided downstream of the nozzle;
A suction pipe opening adjacent to the nozzle,
A diffuser tube formed divergently toward the downstream side provided between the negative pressure chamber and the outlet pipe,
A fuel discharged from the outlet pipe , a shielding member that flows sideways in a desired direction ,
A jet pump comprising: the shielding member is provided along a side surface of the outlet pipe, extends downstream in the axial direction of the outlet pipe, and further has its tip bent laterally in the desired direction. A jet pump having an opening formed between the bent portion and the downstream end opening of the outlet pipe .
[0007]
Further, the second invention is :
In claim 1,
The shielding member includes a cylindrical portion fitted with the outlet pipe, a first flat portion extending from the cylindrical portion in a direction parallel to the axis of the outlet pipe, and a second flat portion extending laterally in the desired direction. It has a flat part and a curved part formed between the first flat part and the second flat part.
Also, the third invention is
A fuel pump having a fuel inlet, a pump body, and a fuel outlet;
A jet pump according to claim 1,
A fuel supply device provided with the fuel supply device, wherein the desired direction is different from the direction of the fuel inlet .
[0008]
[Action]
According to the first and second aspects of the present invention, the vapor is quickly discharged from the diffuser pipe by the opening provided immediately after the outlet of the diffuser pipe of the jet pump, and the fuel is sucked by the vapor being accumulated in the negative pressure chamber of the jet pump. The function can be prevented from deteriorating, and the fuel discharged from the jet pump or the fuel containing vapor can be caused to flow in a desired direction by the shielding member.
[0009]
Further, according to the third aspect , the fuel discharged from the jet pump or the vapor-containing fuel is caused to flow in a direction different from the direction of the fuel inlet of the fuel pump by the shielding member, so that the fuel pump sucks the vapor-containing fuel, The occurrence of vapor lock is suppressed.
[0010]
【The invention's effect】
According to the present invention described above, vapor lock of the jet pump itself by bubbles generated by the jet pump Ru is suppressed. Further, it is also possible to prevent the fuel pump from sucking the vapor discharged from the jet pump and causing the vapor lock.
[0011]
【Example】
Hereinafter, embodiments to which the present invention is applied will be described.
In this embodiment, a fuel supply device including both a fuel pump and a jet pump is provided on one of saddle type fuel tanks in which the inside of the fuel tank is inflated, and when fuel is transferred from the other fuel tank by the jet pump, jet fuel is supplied. A fuel supply device and a jet pump used for the fuel supply device in which vapor from a pump is not sucked by a filter serving as a fuel suction port of the fuel pump.
[0012]
FIG. 1 shows a piping diagram of a fuel tank using the jet pump of the embodiment.
The saddle-type fuel tank has a substantially raised portion formed in the center, and a tank chamber for storing fuel is divided into a first tank portion 2 and a second tank portion 3. The first tank 2 is provided with a fuel pump 4 together with a filter 5 serving as a fuel inlet, and further provided with a jet pump 6.
[0013]
A delivery pipe 9 for delivering fuel to an internal combustion engine (not shown) is connected to a fuel outlet (not shown) of the fuel pump 4. A return pipe 10 for returning fuel from the internal combustion engine to the jet pump 6 is connected to the jet pump 6, and a suction pipe 11 for the jet pump 6 to suck fuel from the second tank unit 3 is connected to the jet pump 6.
The jet pump 6 is configured as shown in FIGS. FIG. 3 is a sectional view of the jet pump, and FIG. 4 is an external view of the jet pump.
[0014]
A nozzle 18 having an orifice portion 18b is formed integrally with the inlet pipe 17 further downstream of the narrow portion 18a toward the downstream side.
The negative pressure chamber 20 is formed by both the cylindrical negative pressure chamber 20a around the nozzle and the truncated conical negative pressure chamber 20b on the downstream side, and the negative pressure chamber 20, the suction pipe 22 and the outlet pipe 23 are integrally formed to form a casing. 21 are formed. The casing 21 is provided with a throat portion 26 on the downstream side of the negative pressure chamber 20, and further on the downstream side thereof, a diffuser tube 24 formed so as to expand toward the outlet pipe 23.
[0015]
The main dimensions of each jet pump are as follows. The unit is mm. Outer pipe inner diameter dc = φ5.5, orifice inner diameter dd = φ1.9, throat inner diameter df = φ4, length L12 = 10 from orifice tip end face 18ba to throat upstream end face, throat part length L14 = 4, Diffuser pipe length L15 = 11.5, outlet pipe length L16 = 17.2.
[0016]
The diffuser tube length L15 is desirably between 2 mm and 20 mm, and in this embodiment is 11.5 mm.
The nozzle 18 of the jet pump 6, the negative pressure chamber 20, the diffuser pipe 24, and the outlet pipe 23 are provided so as to be substantially vertical in the direction of gravity in the fuel tank. It is set up to generate a stronger negative pressure in chamber 20.
[0017]
As shown in FIG. 2, the shielding plate 7, which is a shielding member, includes a cylindrical portion 12, a connection rib 13, a first flat portion 14 parallel to the axis of the discharge pipe 23, a curved surface portion 15, The shielding member 7 is attached to the outlet pipe 23 so that the tip projection 2b formed by the two flat portions 16 and having the second flat portion 16 faces in the opposite direction to the filter.
[0018]
The shielding plate 7 of this embodiment is made of rubber, and the cylindrical portion 12 is fitted to the outlet pipe 23. The outlet pipe 23 is provided with a retaining projection 23b, and the retaining projection 23b and the inner diameter 12a of the cylindrical portion are set to dimensions such that they do not fall off even if the shielding plate 7 swells. Further, an inner wall surface 13a which is a part of a wall surface forming the connection rib 13 is in contact with an outer peripheral contact surface 23c which is a part of an outer peripheral surface of the discharge pipe 23, and the outlet pipe 23 is other than the outer peripheral contact surface. Is in direct communication with the outside through an opening 25 formed with the connection rib 13, the first flat portion 14, the curved surface portion 15, and the second flat portion 16.
[0019]
It is desirable that the distance L5 between the second flat portion 16 and the outlet pipe tip 23a be provided at a distance of 8 mm or more, and in this embodiment, it is 15 mm.
Further, the length L1 in the axial direction of the outlet pipe from the outlet pipe tip 23a to the tangent line between the first flat portion 14 and the curved surface portion 15 is desirably 2 mm or more, and is 5 mm in this embodiment.
[0020]
It is desirable that the ratio of the outer peripheral contact surface 23c to the entire peripheral surface is less than half, that is, the central angle of the outer peripheral contact surface is 180 ° or less, and in this embodiment, it is approximately 60 °.
The operation of the configuration of the above embodiment will be described.
An unused portion of the fuel sent from the fuel pump 4 to the internal combustion engine is returned to the jet pump 6 through the return pipe 10. When the fuel passes through the nozzle 18 from the inlet pipe 17, a negative pressure is created in the negative pressure chamber 20, and the fuel from the second tank unit 3 is sent to the jet pump 6 by this negative pressure.
[0021]
The sent fuel enters the jet pump 6 from the suction pipe 22, passes through the diffuser pipe 24 together with the fuel from the inlet pipe 17, collides with the shielding plate 7 from the outlet pipe 23, and then proceeds along the second plane portion 16. Are discharged to the first tank portion 2 in a direction different from a certain direction of the filter 5.
Even when the fuel returned from the internal combustion engine to the jet pump 6 evaporates when the temperature is high, the vapor passes through the diffuser tube 24 and is discharged to the outside through the opening of the shielding plate. Does not happen.
[0022]
Further, the vapor discharged to the outside hits the shielding plate 7 and is guided in a direction opposite to the direction in which the filter 5 of the fuel pump 4 is provided, which is a predetermined direction, so that the fuel pump 4 sucks the vapor. Therefore, the vapor lock phenomenon does not occur even in the fuel pump 4.
In the above-described embodiment, an example was described in which the shielding plate as the shielding means was made of an elastic body such as rubber, but may be a resin instead of rubber, and specifically, a resin having gasoline resistance. May be manufactured. In this case, even if the vapor collides with the shield plate or is exposed to gasoline, the shape and volume of the shield plate rarely change with time.
[0023]
Furthermore, since the jet pump main body is often formed of resin, the shield plate and the jet pump main body can be formed integrally, which facilitates manufacturing. Therefore, it is more desirable to manufacture with resin.
[Brief description of the drawings]
FIG. 1 is a piping diagram of a fuel tank using a jet pump according to an embodiment of the present invention.
FIG. 2 is an external view showing a shielding plate used in the embodiment.
FIG. 3 is a sectional view of a jet pump to which the present invention is applied.
FIG. 4 is an external view of a jet pump to which the present invention is applied.
FIG. 5 is an external view showing a conventional jet pump.
[Explanation of symbols]
6 Jet pump 7 Shielding plate 8 as shielding member 8 Shielding portion 13 Connecting rib 13a Inner wall surface 14 First flat portion 15 Curved portion 16 Second flat portion 23 Outlet pipe 23a Outlet hype tip 25 Opening

Claims (3)

An inlet pipe,
An outlet pipe,
A nozzle provided between the inlet pipe and the outlet pipe,
A negative pressure chamber provided downstream of the nozzle;
A suction pipe opening adjacent to the nozzle,
A diffuser tube formed divergently toward the downstream side provided between the negative pressure chamber and the outlet pipe,
A fuel discharged from the outlet pipe , a shielding member that flows sideways in a desired direction ,
A jet pump comprising: the shielding member is provided along a side surface of the outlet pipe, extends downstream in the axial direction of the outlet pipe, and further has its tip bent laterally in the desired direction. A jet pump , wherein an opening is formed between the bent portion and a downstream end opening of the outlet pipe . The shielding member includes a cylindrical portion fitted with the outlet pipe, a first flat portion extending from the cylindrical portion in a direction parallel to the axis of the outlet pipe, and a second flat portion extending laterally in the desired direction. The jet pump according to claim 1, further comprising a flat portion and a curved portion formed between the first flat portion and the second flat portion. A fuel pump having a fuel inlet, a pump body, and a fuel outlet;
A jet pump according to claim 1 or 2,
A fuel supply device comprising:
The fuel supply device according to claim 1, wherein the desired direction is different from a direction of the fuel inlet.

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