DE7925377U1 - FUEL INJECTION PUMP FOR COMBUSTION MACHINES - Google Patents

Description

R. 5676

9.8.1979 Ks / Ht

ROBERT BOSCH GMBH ₃ 7OOO Stuttgart 1

Fuel injection pump for internal combustion engines State of the art

The innovation is based on a fuel injection pump according to the preamble of the main claim. With acquaintances, with Equal pressure relief valves equipped fuel injection pumps of this type (DE-AS 1 297 935) lead the relief valve parallel to this valve because of the relief valve arranged centrally in the equal pressure relief valve running pressure line sections to an enlarged outer diameter which makes the installation in existing pumps more difficult of the cylindrical fuel flowed around it Part of the valve body. There must therefore be a reinforced, the valve with enlarged diameter can be used to accommodate the pump housing, or the wall thicknesses between the pressure line sections and the outer surface of the cylindrical part of the valve housing are not permitted thin, so that there is a risk of breakage or cracks.

Advantages of the innovation

The fuel injection pump according to the innovation with the

fit • t

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characterizing features of the main claim has the advantage that an extremely slim structure of the Equal pressure relief valve is achieved, which allows subsequent installation in existing fuel injection pumps allowed or leads to only a small increase in the diameter of the pump.

The measures listed in the subclaims are advantageous developments and improvements of the In the main claim shown training of the Gleichdruckent relief valve possible. Thus, through the characteristics of the Claim 2 facilitates production and achieves a clean separation between pressure and relief lines. The extremely thin partition is through the bores of the pressure line section, which are always subjected to the same pressure and the pedestrian room possible.

By the features of claim 3 an extremely compact design is made possible, and by the features of Claim 4 are intersections of the bores that require additional effort when deburring and also endangered thin walls avoided. A cheap and easy to manufacture, as well as a particularly slim design enabling and at the same time functional equal pressure relief valve is characterized by the characteristic features of claim 5 achieved.

drawing

Three exemplary embodiments are shown in the drawing and are explained in more detail below. It shows Figure 1 a longitudinal section through the "rush" essential to the invention

56

of the first embodiment, Figure 2 the second and Figure 3 the third embodiment based on the opposite Figure 1 differently designed equal pressure relief valves.

Description of the exemplary embodiments

In a bore 10 of a pump housing 11 of an injection pump only partially shown in FIG. 1, a pump cylinder 12 is inserted, in the cylinder bore 13 of which a pump piston 15 provided with an inclined control edge Ik slides. The known parts of the cam drive and the rotating device for the quantity change are not shown. The cylinder bore 13 contains a pump working space 16 which is delimited on the one hand by an end face 17 of the pump piston 15 and on the other hand by a constant pressure relief valve 18.

The constant pressure relief valve 18 contains in a valve housing 19, arranged one behind the other in the flow direction of the fuel, a relief valve 21 and a pressure valve 22. The valve housing 19 is with an underlying flange 23 with the interposition of a sealing ring 2H of a pipe connector 25 screwed into the pump housing 11 against the The cylinder liner 12 is stretched and holds the latter firmly in the pump housing 11, and the valve housing 23 and the pump cylinder 12 are metallically sealed at their contacting end faces.

Both the relief valve 21 and the pressure valve 22 are designed as spring-loaded ball valves, and a valve spring 26 of the relief valve 21 is supported

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at a pump work room-extended abutment 27. A valve spring 28 of the pressure valve 22 is supported on one Abutment 29 which, like the abutment 27, is held in the valve housing 19 by means of a snap ring 31.

The pump working space 16 is connected via the constant pressure relief valve 18 and a pressure line section 32 located in the pipe connection piece 25 to a pressure line 33 which is only indicated and which leads to the injection nozzle.

Within an enlarged longitudinal bore 3 ^ of the pipe connection piece 25 extends a neck-like, the relief valve 21 and the pressure valve 22, cylindrical and fuel-flowed part 35 of the valve housing 19 adjoining the flange 23 The relief valve 21 is eccentric by such a dimension a Arranged to the longitudinal axis of the pressure valve 18, that the thinnest wall thickness S ₁ and S ₂ between the lateral surface of the cylindrical part 35 designated by 36 and a bore 37 forming the pedal space of the relief valve 21 as well as between the lateral surface 36 and a parallel to the relief valve 21 and arranged the pump working space l6 with the pressure valve 22 connecting pressure line section 38 is at least approximately the same. As a result, the cylindrical part 35 of the valve housing 19 can be made extremely slim, so that the entire constant pressure relief valve 18 can be installed in commercially available fuel injection pumps in exchange for normal pressure valves. There is only a few tenths of a millimeter between the pressure line section 38 and the bore 37 forming the pedal space of the relief valve

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thick partition 39 available. This extremely thin wall thickness is possible because it is always in the pressure line section 38 and the same pressure prevails in the spring chamber 37, so that this wall is practically unloaded and influences it the size only imperceptibly.

The pressure valve 22 designed as a ball valve is central arranged in the valve housing 19, and its spring chamber, denoted by 4l, is connected via transverse bores 42 to one of the cylindrical Part 35 of the valve housing 19 surrounding, located within the longitudinal bore 34 of the pipe connector 25 Gap 43 and from this to the pressure line section 32 and the pressure line 33 in connection.

To relieve the pressure line 33, the intermediate space 43 is connected to the relief valve 21 via a transverse bore 44 connected, the pump working chamber l6 relieved at the end of injection and the pressure line 33 via the pressure line section 32 and the space 43 with the spring space 37 of the relief valve 21 and from there with the Pump working space l6 connects.

For the second exemplary embodiment, only the equal pressure relief valve designated ^{here by 18 1 is shown in FIG.} The relief valve 21 and the pressure valve 22 are the same as the two valves built in Figure 1 and disposed, the only difference of this valve l8 is composed to that shown in Figure 1 valve 18 is that the designated ^f here with 38, the pressure line section forming Bore cuts the spring space 37, so that in the area of the spring space 37 both bores 37 and 38 'merge into one another and a mutual

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create space. Such an arrangement is somewhat more difficult to deburr than the one shown in FIG and a simplified channel routing allowed. As in the first exemplary embodiment, the wall thicknesses S _{1 UBd S 2} are at least approximately the same due to the off-center arrangement of the relief valve 21.

In the third exemplary embodiment shown in FIG. 3, only the equal pressure relief valve designated here by 18 "is shown. The pressure valve 22 has the same structure as in the two examples described above, but the relief valve 21 has a differently designed spring chamber 37". The spring chamber 37 ″ is formed above the abutment 27 of the valve spring 26 by an undercut 46 worked centrally in the valve housing 19 ″ despite the eccentrically arranged relief valve 21 or encompassed by this. The pressure line section 38 'which connects the pump working area to the pressure valve 22 and which is shorter than the bore section 38' shown in FIG same as this is designated. The wall thickness, denoted by S ₁ ^, between the undercut 46 or spring chamber 37 "and the jacket surface 36" of the cylindrical part 35 "of the valve housing 19" is the same over the entire circumference, and the wall thickness S £ between the pressure line section 38 'and the jacket surface 36 "is same as that in Figure 2 and min-

at least approximately equal to the wall thickness S ₁ J. A bore section 47 accommodating the spring abutment 27 of the valve spring 26 of the relief valve 21 is, however, still, as with the valves in FIGS 27 also the snap ring 31 holding this abutment.

-λ The mode of operation of the inventive to FIGS ί)

to 3 described equal pressure relief valves differs only imperceptibly from the known valves
and is described below with reference to Figure 1:

During the pump delivery, the pump piston 15
the fuel to be injected is conveyed from the pump working chamber 16 through the pressure line section 38, via the pressure valve 21, the transverse bores 42, the intermediate space 43 and the pressure line section 32 into the pressure line 33 leading to the injection nozzle. At the end of the injection, when the inclined control edge 14 on the pump piston 15 opens a control bore 48 in the wall of the pump cylinder 12, the pressure in the pump working chamber 16 drops suddenly, the pressure valve 22 closes the passage in front of the pressure line section 38 to the pressure line 33, and the in
the pressure line 33> the pressure line section 32 and
The residual pressure remaining in the space 43 also acts on the relief valve 21 via the transverse bore 44 connecting the space 3 with the relief valve The spring preload of the valve spring 26 of the relief valve 31 and possibly also the one designed as a throttle bore
Transverse bore 44 determine the pressure level and the speed at which or at which the relief takes place.

".5676

9.8.1979 Ks / Ht

ROBERT BOSCH GMBH, 7OOO Stuttgart α Fuel injection pump for internal combustion engines summary

A fuel injection pump (FIG. 1) for internal combustion engines is proposed, the constant pressure relief valve (18) of which has a structure that takes up little space. A relief valve (21) arranged between a pressure valve (22) and a pump working chamber (16) is parallel to a pressure line section (38) and by such a dimension (a) off-center to the longitudinal axis of the valve housing (19) in a cylindrical part (35) around which fuel flows. of the valve housing (19) arranged so that the thinnest wall thickness (S ₁ and S-) between the lateral surface (36) of the valve housing (19) and the pressure line section (38) and the spring chamber (37) is at least approximately the same.

Claims (1)

R.5676 9.8.1979 Ks / Ht ROBERT BOSCH GMBH, 7OOO Stuttgart 1 Protection claims 1. Fuel injection pump for internal combustion engines with a reciprocating pump piston delimiting a pump working space and one in the pressure line equal pressure relief valve used for injection valve, one behind the other in a valve housing in the direction of flight of the fuel arranged relief and pressure valve, of which the one between the pressure valve and the pump working chamber Lying relief valve parallel to a pressure line section connecting the pump working space with the pressure valve is arranged and via a .querbohrung bypassing the pressure valve in a cylindrical The part of the valve housing around which the fuel flows is the connection from the pressure line to the pump working chamber for controlling a constant pressure relief of the pressure line, characterized in that at least the relief valve (21) is designed as a spring-loaded ball valve that the relief valve (21) off-center by such an amount (a) - 2 - R. is arranged that the thinnest wall thickness (s. ^ and S ₂ , Sjj) between the lateral surface (36, 36 ") of the cylindrical part (35, 35") of the valve housing (19, 19 ', 19 ") and one of the Peder space of the relief valve (21) forming the bore (37, 37 ") and between the lateral surface (36, 36") and the pressure line section (38, 38 ') is at least approximately the same. 2. Fuel injection pump according to claim 1, characterized in ₃ that forming between the pressure line section (38) and the spring chamber of the relief valve (21) bore (37) a few Zentelmillimeter thick intermediate wall (39) is present (Figure 1). 3 · Fuel injection pump according to claim 1, characterized in, that the bore (38 ') forming the pressure line section the spring chamber (37) of the relief valve (21) and a hole (45) of the pressure valve (21) cuts (Figure 2). ¹ J. Fuel injection pump according to Claim 1, characterized in that the pressure line section (38 *) opens into a central recess (46) encompassing the spring chamber (37 ") of the relief valve (21), the wall thickness of which 5676 (S ₁₁ ) to the jacket surface (36 ") of the cylindrical part (35") of the valve housing (19 ") is the same over the entire circumference and that, however, a spring abutment (27) for the valve spring (26) of the relief valve (? I) accommodating Bore section (^ 7) is arranged eccentrically to the longitudinal axis of the valve housing (19 ") and centrically to the axis center of the relief valve (21) (Figure 3) 5. Fuel injection pump according to one of claims i to ² J, characterized in that both valves (21, 22) are designed as ball valves. ,