RU2397358C2 - Device to feed fuel from fuel tank into automotive ice - Google Patents

Abstract

FIELD: engines and pumps. ^ SUBSTANCE: proposed device comprises fuel feed pump arranged in fuel accumulator with bottom to feed fuel fro fuel tank therein. On and/or in fuel accumulator bottom facing fuel feed pump, several chambers open inside fuel accumulator are arranged to separate impurities or foreign particles from fuel, while fuel feed pump is arranged so that fuel fed thereby passes through aforesaid chambers. ^ EFFECT: ease of separating foreign particles from fuel sucked in from fuel tank. ^ 10 cl, 2 dwg

Description

State of the art

The present invention relates to a device according to the restrictive part of an independent claim. A similar fuel supply device, which is already known from US 5080077, has a fuel accumulator and a suction jet pump located therein, by which fuel from the fuel tank is supplied to the fuel accumulator through the suction port in its bottom. A fabric filter is located in front of the suction port, filtering out foreign particles (contaminant particles) from the fuel sucked from the fuel tank to prevent them from entering the valves located after the suction port and thereby deteriorate their performance. A disadvantage of such a known device is that the fabric filter, in the presence of a large amount of foreign particles in the fuel, gradually clogs them and as a result increases the hydraulic resistance created by it, due to which, at a constant power of the suction jet pump, the amount of fuel supplied to the fuel accumulator gradually decreases .

Advantages of the Invention

An advantage of the device proposed in the invention with the distinctive features presented in the independent claim over the devices known from the prior art is the use of a different solution that is simple to implement to separate the foreign particles present in it from the fuel sucked from the fuel tank, for which purpose and / or at the bottom of the fuel accumulator with its inner side facing the feed pump, there are several chambers open inside the fuel accumulator for separation I am from the fuel of foreign particles or particles of impurities present in it, and the feed pump is located in such a way that the fuel leaving it passes through these chambers.

Various preferred embodiments of the device claimed in the independent claim are given in the dependent claims.

Thus, in particular, it is most preferable for the chambers to be arranged sequentially one after another in the direction of the fuel flow exiting the feed pump, since this ensures a particularly efficient separation of foreign particles from the fuel in the chambers.

It is preferable to further further position the chambers next to each other, when viewed in the direction of the fuel flow exiting the feed pump, since this further improves the efficiency of separating foreign particles from the fuel.

In a particularly preferred embodiment, the chambers are formed by walls protruding from the bottom of the fuel accumulator, which can be made together with the fuel accumulator by a particularly simple and economical injection molding method.

In another preferred embodiment, the chambers are formed by at least two guide walls and several partitions connecting them to each other and arranged transversely to the direction of fuel flow, which guide walls and partitions can also be made together with the fuel accumulator by a particularly simple and economical injection molding method.

In the last of the above options, it is preferable that one of the guide walls was formed by the wall of the fuel accumulator, since this ensures that almost the entire amount of fuel absorbed from the fuel tank passes through the chambers and is cleaned of foreign particles.

In a further preferred embodiment, the guide walls and / or partitions are proposed to be performed with a height increasing in the direction of flow of the fuel leaving the feed pump, measured in the axial direction of the fuel accumulator, since this increases the efficiency of separating foreign particles from the fuel.

In another preferred embodiment, a suction jet pump is proposed as a feed pump.

In addition, it is preferable to position the feed pump so that the fuel jet exiting from its outlet pipe into the fuel accumulator is obliquely directed towards the side wall of the fuel accumulator, since in this case the fuel jet is not split into separate, smaller jets, but is adjacent to the side wall of the fuel The battery continues to move along it. As a result, almost all the amount of fuel sucked from the fuel tank passes through the chambers, which ensures its complete cleaning from foreign particles.

Brief Description of the Drawings

Below the invention is described in more detail on the example of one of the variants of its implementation with reference to the accompanying simplified drawings, which show:

figure 1 - schematic view proposed in the invention device and

figure 2 is a schematic view of a fuel battery with a feed pump.

Description of an embodiment of the invention

1 schematically shows a device for supplying fuel.

Such a device is intended, for example, for supplying fuel from a fuel tank 1 to a fuel accumulator 2 and from it by a feeding unit 3 to an internal combustion engine 4 of a vehicle.

In the fuel tank 1 is placed a fuel accumulator 2, in which, in turn, is the feeding unit 3. The feeding unit 3 is, for example, a dynamic or displacement pump.

A fuel accumulator 2, for example, in a glass-shaped form, is designed to accumulate or accumulate fuel in it in an amount sufficient to ensure its uninterrupted supply to ICE 4 by the feeding unit 3 even when, for example, when the vehicle is moving along a curve or in a curve and when due to this occurrence of swaying movements of fuel in the fuel tank 1, it does not enter the fuel accumulator 2.

The supply unit 3 draws fuel from the fuel accumulator 2, for example, through a coarse filter 5 through a suction fuel line 6 and pumps fuel through an outlet pipe 7 into a pressure fuel line 8 leading to the internal combustion engine 4. The coarse filter 5 protects the downstream fuel flow a device against the ingress of large foreign particles (particles of pollution) contained in the fuel.

In the pressure fuel line 8, a check valve 9 is provided and a main filter 10 located behind it in the direction of the fuel flow. The check valve 9 prevents the flow of fuel from the fuel flow line 8 located downstream of the check valve 9 and is located downstream of the fuel supply valve 3. flow in front of the check valve 9 part and then through the supply unit 3, the suction pipe 6 and the coarse filter 5 back to the fuel accumulator 2. The main filter 10 filters the contained in small foreign particles (particles of pollution) in the fuel and in this way protects against clogging, for example, ICE valve nozzles.

From the pressure fuel line 8 at a point located along the fuel flow behind the main filter 10, a bypass fuel line 13 branches with a pressure relief valve 14 provided therein. When the pressure in the pressure fuel line 8 increases above a predetermined value, the pressure reduction valve 14 opens, allowing fuel to flow from the pressure head fuel line 8 through the fuel bypass line 13 back to the fuel accumulator 2. As a result, the pressure in the pressure fuel line 8 again becomes lower than the specified maximum timogo level and pressure reducing valve 14 closed.

In addition, from the fuel pressure pipe 8 at a point located along the fuel flow behind the supply unit 3 and in front of the check valve 9, a fuel discharge pipe 15 branches, for example, for supplying fuel as a working medium from a pressure fuel pipe 8 to a feed pump, for example, called a suction jet pump (injector) 16, and its actuation. In principle, fuel can be supplied to the suction jet pump 16 also from the fuel bypass 13 or from a return fuel pipe not shown in the drawing, which leads from the internal combustion engine 4 back to the fuel tank 1. In order to prevent the fuel accumulator 2 from completely emptying by the supply unit 3 into the fuel accumulator 2 through the suction the hole 17 by the suction jet pump 16 continuously delivers fuel from the fuel tank 1. The suction fuel along with the so-called driving (working) jet leaving the injection fuel line 15, is supplied to the fuel accumulator 2. In the injection fuel line 15, for example, a throttling element 21 is provided for establishing and limiting the volumetric flow rate of the fuel passing through it. In order to avoid clogging of the throttling element 21, the discharge fuel line 15 is provided upstream of the throttling element 21 one coarse filter 22.

A suction jet pump is known, for example, from DE 19856298 C1, which is hereby incorporated by reference in its entirety.

The fuel accumulator 2 is made, for example, in a glass-like shape with an axis 20 (FIG. 2) and has a bottom 23. A suction jet pump 16 is located, for example, at the bottom 23 of the fuel accumulator.

According to the prior art, fuel that is sucked in through the suction port 17 passes through filters that trap foreign particles present in the fuel. During operation, such filters are gradually clogged by particles detained by them, due to which the hydraulic resistance created by the filters increases (i.e., the pressure loss on the filters increases), and with the constant power of the suction jet pump, the amount of fuel absorbed into the fuel accumulator 2 gradually decreases. In accordance with the present invention, the use of these filters can be dispensed with using a different approach for separating foreign particles from the fuel. Due to this, the hydraulic resistance in the area of the suction hole 17 remains constant, and the fuel accumulator 2 as a result, at a constant power of the suction jet pump 16 always receives the same amount of fuel.

According to the invention, several chambers 24 are provided on and / or in the bottom 23 of the fuel accumulator 2 with its inner side 19 facing the suction jet pump 16, for separating foreign particles from the fuel sucked from the fuel tank 1. Such chambers 24, with their upper side facing away from the bottom 23 of the fuel accumulator, are made open inside the fuel accumulator 2. The chambers 24 can be of any shape. According to the invention, the suction jet pump 16 is arranged so that the fuel coming from it into the fuel accumulator 2 passes through the chambers 24.

The chambers 24 are arranged sequentially one after the other in the direction 26 of the fuel flow coming from the suction jet pump 16 to the fuel accumulator 2. In addition, several more chambers 24 located next to each other can also be provided when viewed in the indicated direction 26 of the fuel flow. The cameras 24 are arranged sequentially one after another, for example, along an arcuate line, however, in principle, they can also be sequentially arranged along a straight line or along a line of any other shape.

The chambers 24 are formed, for example, by walls 25 protruding from the bottom 23 of the fuel accumulator 2. In another embodiment, the chambers 24 can also be formed by recesses in the bottom 23 of the fuel accumulator.

After exiting the suction jet pump 16 into the fuel accumulator 2 and when it moves through the chambers 24, the fuel slows down by them. Each chamber 24 forms a stagnant zone for the fuel flow, in each of which a turbulence of the fuel flow occurs. Foreign particles present in the fuel moving through the chambers 24 are separated from it due to their inertia due to the slowing of the fuel flow and its swirl in the chambers 24 and settle to the bottom of each individual chamber 24. A sufficiently large capacity is made for the volume of the chamber 24 to accumulate in particles of pollutants, excluding their full filling by pollution particles during the average service life of the vehicle. The chambers 24 are capable of accommodating a much larger amount of contaminant particles compared to the amount of contaminant particles that the filters used according to the prior art are capable of holding.

Figure 2 shows a fragment of the device shown in figure 1, of all the components and elements of which, however, only the fuel accumulator, the suction jet pump and chambers are shown in this drawing.

Elements of the device shown in FIG. 2, which are identical in design or function to similar elements of the device shown in FIG. 1, are denoted by the same positions.

In the embodiment shown in FIG. 2, the chambers 24 are formed, for example, by two spacing guide walls 28 and several spaced apart from each other by the fuel flow direction 26, partitions 30 connecting the guiding walls 28. The guiding walls 28 are made for example, arcuate in curved shape and at least roughly extend in the same direction. In principle, however, the guide walls can be of any shape. In the direction of the axis 20 of the fuel accumulator 2, the partitions 30 reach, for example, its bottom 23, forming chambers 24 that are separated from each other.

The sides of the chamber 24, for example, are adjacent radially outwardly from the axis of the fuel accumulator 20 to the side wall 29 of the fuel accumulator 2. In this case, the chambers 24 are radially outwardly delimited by the side wall 29 of the fuel accumulator 2, thereby forming one of the guide walls 28. Another the guide wall 28 is indented from the side radially inner relative to the side wall 29 of the fuel accumulator.

The height of the guide walls 28 measured in the direction of the axis 20 of the fuel accumulator 2, for example, is greater than the height of the partitions 30 measured in the same direction, but in principle it can also be equal to it. That part of the guide walls 28, which is located above the partitions 30, serves to direct the fuel flow out of the suction jet pump 16 through the chambers 24.

In the embodiment shown in FIG. 2, the height of the sequentially arranged partitions 30 increases in the direction 26 of the fuel flow from one partition 30 to the next. In addition, the height of the radially inner guide wall 28 increases, for example, continuously, in the direction 26 of the fuel flow. However, in principle, the height of the partitions 30 and at least one guide wall 28 may also remain constant or even decrease in the direction of the fuel flow 26.

The suction jet pump 16 has an inlet 33 for fuel entering through the fuel injection pipe 15, and also called a mixing channel, an exhaust pipe 34 for outputting fuel into the fuel accumulator 2. Through the suction port 17 in the bottom 23 of the fuel accumulator, fuel is sucked from the fuel tank 1 into the suction the jet pump 16, then, together with the fuel leaving the discharge fuel line 15, enters through the exhaust pipe 34 into the fuel accumulator 2 and then moves between the guide walls 2 8 through cameras 24.

The suction jet pump 16 is located in such a way that the fuel jet exiting from its outlet pipe 34, the outlet of which should be located as close as possible to the chambers 24, is directed at them. This ensures the passage of almost the entire amount of fuel absorbed from the fuel tank 1 through the chambers 24 and its cleaning from foreign particles. In addition, the suction jet pump 16 is located so that the fuel jet emerging from its outlet pipe 34 is directed obliquely to the side wall 29 of the fuel accumulator 2, adjoins to it and then moves along it between the guide walls 28 over the partitions 30 and through the chambers 24 limited by them .

Claims (10)

1. A device for supplying fuel from a fuel tank to an internal combustion engine of a vehicle having a feed pump, which is located in a bottom of a fuel accumulator and serves to supply fuel from a fuel tank to it, characterized in that on and / or in the bottom (23 ) of the fuel accumulator (2) with its inner side (19) facing the feed pump (16), several chambers (24) open to the inside of the fuel accumulator (2) are provided for separating foreign particles or contaminants from the fuel, and the hearth conductive pump (16) is positioned so that fuel exiting therefrom passes through the chamber (24). 2. The device according to claim 1, characterized in that the chambers (24) are arranged sequentially one after another in the direction (26) of the fuel flow leaving the feed pump (16). 3. The device according to claim 2, characterized in that the chambers (24) are additionally located next to each other when viewed in the direction (26) of the fuel flow. 4. The device according to claim 1, characterized in that the chambers (24) are formed by the walls (25) protruding from the bottom (23) of the fuel accumulator (2). 5. The device according to claim 1, characterized in that the chambers (24) are formed by recesses in the bottom (23) of the fuel accumulator (2). 6. The device according to claim 1, characterized in that the chambers (24) are formed by at least two guide walls (28) and several partitions (30) that connect them to each other and are located transverse to the direction (26) of the fuel flow. 7. The device according to claim 6, characterized in that one of the guide walls (28) is formed by the wall of the fuel accumulator (2). 8. The device according to claim 6, characterized in that the height of the guide walls (28) and / or partitions (30) measured in the axial direction of the fuel accumulator (2) increases in the direction of fuel flow (26). 9. The device according to claim 1, characterized in that the feed pump (16) is a suction jet pump. 10. The device according to claim 1, characterized in that the feed pump (16) is located in such a way that the fuel jet (2) emerging from its outlet pipe (34) into the fuel accumulator (2) is inclined toward the side wall (29) of the fuel accumulator (2) )

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