WO2022218635A1 - High pressure pump for a fuel injection system - Google Patents

Abstract

The invention relates to a high pressure pump (1) for a fuel injection system, comprising at least one pump element (2) having a pump piston (3) which can be moved back and forth and which is received in a cylinder bore (4) at one end and supported on a camshaft (6), for example via a roller tappet (5), at the other end, wherein a piston sealing ring (8) is inserted in an end portion (7) of the cylinder bore (4) that faces the camshaft (6), which piston sealing ring is directly or indirectly axially supported on an annular projection (9) which delimits the end portion (7). According to the invention, the cylinder bore (4) has, in the region of the annular projection (9), a diameter (D1) which is equal to or greater than a diameter (D2) in the region of an opening (10) at the end of the cylinder bore (4).

Description

description

Title:

High-pressure pump for a fuel injection system

The invention relates to a high-pressure pump for a fuel injection system according to the preamble of claim 1. Fuel, for example diesel fuel, can be compressed with the aid of the high-pressure pump. The fuel injection system can therefore in particular be a common rail injection system.

State of the art

Injection systems for injecting diesel fuel, in particular common rail injection systems, are well known from the prior art. As a rule, these include a tank for storing the diesel fuel, a pre-supply pump for removing the diesel fuel from the tank and a high-pressure pump for applying high pressure to the diesel fuel. The high-pressure pump is usually designed as a piston pump, in particular as a radial piston pump, and comprises at least one pump element with a reciprocating pump piston, which is accommodated at one end in a cylinder bore and at the other end is supported on a camshaft via a roller tappet. The end of the pump piston facing away from the camshaft delimits a pump work chamber within the cylinder bore, which can be filled with fuel via an inlet valve. The fuel in the pump working chamber is subjected to high pressure with the help of the pump piston and fed to a high-pressure accumulator, the so-called "rail", via an outlet valve. A high-pressure pump 1 of the type mentioned above is shown by way of example in the attached FIG. 15 . It comprises pump elements 2, each of which has a reciprocating pump piston 3, which is supported at one end in a cylinder bore 4 and at the other end via a roller tappet 5 on a cam shaft 6. In an end section 7 the cylinder bores 4 each have a piston sealing ring 8 which surrounds the respective pump piston 3 . As can be seen from Fig. 16, which is also enclosed, which shows the installation situation of a piston sealing ring 8 in an enlarged view, the end section 7 receiving the piston sealing ring 8 has an enlarged diameter D1, so that an annular shoulder 9 is formed, on which the Piston sealing ring 8 is supported axially. At the other end, the position of the piston sealing ring 8 is secured by a retaining element 11 in the form of a snap ring which engages in an annular groove of the cylinder bore 4 and indirectly abuts the front side of the piston sealing ring 8 via a support disc 21 . To accommodate the Spren grings and the support disk 21, the end portion 7 of the cylinder bore 4 is stepped several times. In the area of an end opening 10, the remaining wall thickness of the end section 7 is therefore comparatively small, which leads to a weakening of the component.

The object of the present invention is to remedy this situation. To solve the problem, the high-pressure pump with the features of claim 1 is proposed. Advantageous developments of the invention can be found in the dependent claims.

Disclosure of Invention

The high-pressure pump proposed for a fuel injection system comprises at least one pump element with a reciprocating pump piston, which is accommodated in a cylinder bore at one end and supported on a camshaft at the other end, for example via a roller tappet. A piston sealing ring is inserted in an end section of the cylinder bore facing the camshaft and is supported directly or indirectly axially on an annular shoulder delimiting the end section. According to the invention, the cylinder bore in the area of the annular shoulder has a Diameter Dl, which is equal to or greater than a diameter D2 in the region of an end opening of the cylinder bore.

This means that—in contrast to the prior art—the end section of the cylinder bore that accommodates the piston sealing ring is not weakened in the area of the end opening, but may even be reinforced. In this way, increased robustness of the high-pressure pump is achieved.

Preferably, the end portion of the cylinder bore receiving the piston sealing ring has a constant diameter from the annular shoulder to the opening at the end. This means that the diameter is the same over the entire length of the end section. A weakening is thus avoided not only in the area of the end opening, but over the entire length of the end section.

Furthermore, the piston sealing ring is preferably inserted directly or indirectly into the end section of the cylinder bore, preferably pressed in, via a sleeve-shaped holding element which at least partially surrounds the piston sealing ring. In this case, there is no need to additionally secure the position of the piston sealing ring with the aid of a snap ring and a support washer, so that the number of components is reduced. At the same time, the assembly of the sealing ring is simplified ver, since only a single pressing process is to be carried out. The production of the press connection using a sleeve-shaped holding element has the advantage that the press fit can be optimized, for example by using a metallic sleeve as the holding element. The sleeve-shaped retaining element surrounding the piston sealing ring at least in sections can be arranged and designed in such a way that it engages around the front side of the piston sealing ring at its free end. In this way, additional protection of the piston sealing ring is achieved via the holding element. For this purpose, the holding element can be designed as a collar sleeve.

According to a further preferred embodiment of the invention, the piston sealing ring is held in the end section of the cylinder bore via an annular retaining element. The annular retaining element takes the place of the Snap ring and the support washer, so that in this case the number of components is reduced and the assembly of the piston sealing ring is simplified. For assembly, the piston sealing ring is preferably first used in the end section of the cylinder bore, then the retaining element. The retaining element is preferably pressed into the end section of the cylinder bore in the region of the end opening and is supported axially on the piston sealing ring. The retaining element therefore has an oversize that allows it to be pressed into the end section. Otherwise, the holding element can be designed as a simple ring.

According to a further preferred embodiment of the invention, an annular or sleeve-shaped retaining element surrounding the piston sealing ring at least in sections matures into a recess widening the end section of the cylinder bore and/or into a recess of the piston sealing ring. In this way, with the aid of the holding element, a form fit is achieved which prevents relative movements of the piston sealing ring and/or the holding element in the axial direction. If the piston sealing ring and the retaining element are not connected in a form-fitting manner, a non-positive connection is preferably established between the piston sealing ring and the retaining element. For this purpose, the retaining element can be pressed onto the piston sealing ring, for example. A snap ring and ei ne support washer are not required, as further fixing the position of the piston sealing ring is not required. The piston sealing ring can therefore reach up to the end opening of the cylinder bore or just before it. This has the advantage that a maximum length of the guide of the pump piston in the cylinder bore is guaranteed. The piston sealing ring can, for example, be flush with the cylinder.

The holding element producing the form-fitting connection can in principle have any desired cross-section, for example the holding element can have a circular cross-section analogously to a snap ring. However, the holding element can also have a rectangular cross-section, for example it can be designed analogously to a clamping bush. The recess that widens the end section of the cylinder bore and/or the recess of the piston sealing ring, in which the holding element engages, is/are preferably designed as an annular groove. As a result, the wall delimiting the end section is weakened, but at an axial distance from the opening at the endsei. This only impairs the robustness of the high-pressure pump to an insignificant extent.

According to a further preferred embodiment of the invention, a holding element is arranged outside of the cylinder bore, which surrounds a cylinder that forms the cylinder bore. Due to the external arrangement of the holding element, the piston sealing ring can be brought up to the end opening of the cylinder bore, so that it is flush with the cylinder bore or the cylinder. A maximum length of the guide for the pump piston is thus also achieved in this embodiment. At the same time, the piston sealing ring is protected on the front side by the external retaining element. To secure the position, the retaining element surrounding the cylinder can be connected to the cylinder via a plug-in, clamp, press, snap-in and/or screw connection. A welded or glued connection is also conceivable.

In a further preferred embodiment of the invention, the piston sealing ring has at least one geometry on the outer circumference, which engages in a geometry of opposite design that widens the end section of the cylinder bore. In this way, a positive fit between the piston sealing ring and the cylinder that forms the cylinder bore is achieved. Further means for securing the position are unnecessary, so that not only can a snap ring and a support washer be omitted, but also a holding element. The position of the piston sealing ring can be secured simply by the form fit of the intermeshing geometries. The geometry formed on the piston sealing ring can be, for example, a peripheral bead that engages in an annular groove of the cylinder that is formed in the same manner. Although the annular groove leads to a certain weakening of the wall delimiting the end section, the weakening takes place at a certain distance from the opening at the end of the cylinder bore, so that it is negligible. Alternatively, the geometry of the piston sealing ring can also extend only over a partial circumferential area. corners, so that no circumferential annular groove has to be provided in the wall, but only a recess extending over a part of the circumference. If there are several geometries or recesses, these are preferably arranged in a uniformly distributed manner in the circumferential direction. If further means for securing the position are dispensed with, the piston sealing ring can also be brought up to the end opening of the cylinder bore in this embodiment. The guide length of the pump piston is therefore at its maximum.

According to a further preferred embodiment, the opening at the end of the cylinder bore is delimited by an annular collar, so that the diameter D2 is smaller than the diameter D1. The annular collar reduces the opening at the end or reinforces the wall in this area. At the same time, another annular shoulder is formed for axial support of the piston sealing ring. Since the piston sealing ring is supported axially at both ends on an annular set from the cylinder bore, further means for position hedging of the piston sealing ring are unnecessary. When installing the piston sealing ring, it must be guided behind the ring collar, so that a certain elasticity of the piston sealing ring is required. In order to facilitate the insertion of the piston sealing ring into the end section of the cylinder bore, the annular collar can be provided with an insertion cone.

In a further preferred embodiment of the invention, the piston sealing ring is held with the aid of a pin which is arranged transversely to a longitudinal axis of the cylinder bore and engages in a groove formed on the outer peripheral side of the piston sealing ring. The pin can be installed after the piston seal has been installed, so that the piston seal can be inserted into the end section of the cylinder bore without any problems. In order to be able to use the piston sealing ring in any angular position, the groove formed on the outer circumference can be formed as an annular groove. The cylinder forming the cylinder bore has a transverse bore for receiving the pin.

Preferred embodiments of the invention are explained in more detail below with reference to the accompanying drawings. These show: 1 shows a longitudinal section through a pump element of a first high-pressure pump according to the invention in the area of a piston sealing ring,

2 shows a longitudinal section through a pump element of a second high-pressure pump according to the invention in the area of a piston sealing ring,

3 shows a longitudinal section through a pump element of a third high-pressure pump according to the invention in the area of a piston sealing ring, FIG. 4 shows a longitudinal section through a pump element of a fourth high-pressure pump according to the invention in the area of a piston sealing ring,

5 shows a longitudinal section through a pump element of a fifth high-pressure pump according to the invention in the area of a piston sealing ring,

6 shows a longitudinal section through a pump element of a sixth invention to the invention high-pressure pump in the area of a piston sealing ring,

7 shows a longitudinal section through a pump element of a seventh high-pressure pump according to the invention in the area of a piston sealing ring,

8 shows a longitudinal section through a pump element of an eighth high-pressure pump according to the invention in the area of a piston sealing ring, FIG. 9 shows a longitudinal section through a pump element of a ninth high-pressure pump according to the invention in the area of a piston sealing ring,

10 shows a longitudinal section through a pump element of a tenth high-pressure pump according to the invention in the area of a piston sealing ring,

11 shows a longitudinal section through a pump element of an eleventh high-pressure pump according to the invention in the area of a piston sealing ring, 12 shows a longitudinal section through a pump element of a twelfth high-pressure pump according to the invention in the area of a piston sealing ring,

13 shows a longitudinal section through a pump element of a thirteenth high-pressure pump according to the invention in the area of a piston sealing ring,

14 shows a cross section through the pump element of FIG. 13 in the area of a retaining element for securing the position of the piston sealing ring,

15 shows a longitudinal section through a high-pressure pump according to the prior art and

FIG. 16 shows an enlarged detail of the high-pressure pump of FIG. 15 in the area of a piston sealing ring.

Detailed description of the drawings

1 to 14, various embodiments of a high-pressure pump 1 according to the invention are shown. The illustration is limited to the area of a piston sealing ring 8 accommodated in a cylinder bore 4. Otherwise, the high-pressure pumps 1 can be designed analogously to the high-pressure pump 1 illustrated in FIG. 15, which was already described at the outset. The following description of FIGS. 1 to 14 is therefore also limited to the area of the cylinder bore 4 and the piston sealing ring 8 used therein.

The section of FIG. 1 shows a cylinder 14 in which the cylinder bore 4 is formed. In the cylinder bore 4, a pump piston 3 is accommodated in a reciprocating manner. The piston sealing ring 8 is pressed into an end section 7 of the cylinder bore 4 so that it is axially supported on an annular shoulder 9 which delimits the end section 7 . In the area of annular paragraph 9, the end section 7 has a diameter D1 which remains the same over the entire length of the end section 7, so that the diameter D2 in the area of an end opening 10 of the cylinder bore 4 is equal to that diameter is Dl. In the area of the opening 10 an annular retaining element 11 is pressed into the cylinder bore 4 so that the retaining element 11 bears against an end face of the piston sealing ring 8 . Since the holding element 11 has no sealing function to fulfill, it can be made of a material that ensures an optimal press fit, so that the position of the piston sealing ring 8 within the cylinder bore 4 is secured.

Fig. 2 shows the same detail as Fig. 1, but another high-pressure pump 1. The end portion 7 of the cylinder bore 4 has a diameter D1 in the area of the ring-shaped shoulder 9 and a diameter D2 in the area of the end opening 10, which is the same the diameter is Dl.

Here, too, the position of the piston sealing ring 8 within the cylinder bore 4 is secured by a holding element 11 . However, the retaining element 11 is in this case designed as a collar sleeve which encloses the piston sealing ring 8 at the periphery and at the front. The collar sleeve has an oversize in relation to the cylinder bore 4 in the area of the end section 7, so that the piston sealing ring 8 is pressed into the cylinder bore 4 via the collar sleeve. Since the material of the collar sleeve can be freely selected, an optimal press fit can be achieved. At the same time, the piston sealing ring 8 is protected on the front side by the collar sleeve.

The embodiment shown in FIG. 3 represents a modification of the embodiment from FIG. The collar sleeve has on the outer circumference axially spaced apart from each other before jumps 22 which engage in recesses 12 of the cylinder 14. In this way, a form fit is achieved, which secures the position of the piston sealing ring 8 within the cylinder bore 4 . The projections 22 can be formed circumferentially, for example as circumferential beads, or only extend over a partial circumferential area. The same applies to the recesses 12 of the cylinder 14 Zy. However, this requires the installation of the retaining element 11 in a certain angular position be. In order to be able to install the holding element 11 in any angular position, the recesses 12 are preferably designed as annular grooves. A further preferred embodiment can be seen in FIG. To secure the position of the piston sealing ring 8, a holding element 11 is also provided here. This is ring-shaped in the present case and engages in a recess of the piston sealing ring 8 which is designed as an annular groove. The holding element 11 and the piston sealing ring 8 are thus connected in a form-fitting manner. The retaining element 11 also engages in the recesses 12 that widen the cylinder bore 4, so that a form fit between the retaining element 11 and the cylinder 14 is also achieved. Since the retaining element 11 surrounds the piston sealing ring 8 , the piston sealing ring 8 can be brought up to the opening 10 so that it is flush with the cylinder 14 at the end face. This allows the pump piston 3 to be guided to its maximum length within the cylinder bore 4.

A modification of the embodiment of FIG. 4 is shown in FIG. The modification is that the holding element 11 is not rectangular, but has a circular cross-section. Other cross-sectional shapes are also possible.

A further preferred embodiment is shown in FIG. 6. The position of the piston sealing ring 8 is again secured by a retaining element 11, but this is arranged outside of the cylinder bore 4. The piston sealing ring 8 can thus in turn be brought up to the opening 10 . Since the retaining element 11 is designed as a collar bushing, it encompasses the cylinder 14. At the same time, the end face of the piston sealing ring 8 is protected by the collar bushing. The collar bushing is pressed onto the cylinder 4 in FIG. 6, so that the position of the collar bushing in relation to the cylinder 14 and thus the position of the piston sealing ring 8 within the cylinder bore 4 is secured.

The embodiment of FIG. 7 is similar to that of FIG. 6, but here the Hal teelement 11 or the collar bushing is screwed onto the cylinder 14. As a result, the position is secured not by a force fit but by a form fit.

Alternatively - as shown by way of example in Fig. 8 - the retaining element 11, which is designed as a collar bushing, can also have a snap-in connection with the cylinder 14 to be connected. For this purpose, the collar bushing has latching means 23 at its end, which engage in a circumferential groove 24 of the cylinder 14 .

A further preferred embodiment is shown in FIG. 9. The holding element 11 is designed here as a holding plate which is mounted over the cylinder 14. FIG. The holding plate can in turn be pressed or screwed to the cylinder 14 . Furthermore, the connection can be established via an adhesive connection. In addition, an element spring 25 can be used to fix the retaining plate, which is already present.

FIG. 10 shows an embodiment that manages without holding element 11 . Instead, a geometry 15 is provided on the outer circumference of the piston sealing ring 8 , which engages in a geometry 16 of the cylinder 14 that is constructed in the opposite manner. The geometry 15 can be, for example, a circumferential bead which engages in a geometry 16 designed as a circumferential annular groove. The shape of the geometry 15 or the oppositely designed geometry 16 can be chosen arbitrarily. In Fig. 11, therefore, an embodiment example is shown with a rectangular cross-sectional shape.

The embodiment shown in FIG. 12 also comes without Hal teelement 11, since the piston sealing ring 8 is supported axially on the one hand on the annular set 9 and on the other hand on an annular collar 17, which is formed by the cylinder 14. The annular collar 17 narrows the end opening 10 of the cylinder bore 4 so that the diameter D2 is smaller than the diameter D1 in the area of the annular shoulder 9 . The cylinder 14 is accordingly reinforced in the area of the opening 10 by the annular collar 17 . In order to facilitate the insertion of the piston sealing ring 8 into the end section 7 of the cylinder bore 4, the annular collar 17 has an insertion cone 18 in the present case.

A further preferred embodiment can be seen in FIG. Here the piston sealing ring 8 is held by a pin 19 which is accommodated in a bore 26 of the cylinder 14 transversely to a longitudinal axis A of the cylinder bore 4 and thereby engages in a circumferential groove 20 of the piston sealing ring 8 (see also Fig. 14).

Claims

Expectations

1. High-pressure pump (1) for a fuel injection system, comprising at least one pump element (2) with a reciprocating pump piston (3), which is accommodated at one end in a cylinder bore (4) and at the other end, for example via a roller tappet (5), is supported on a camshaft (6), with a piston sealing ring (8) being inserted in an end section (7) of the cylinder bore (4) facing the camshaft (6), which is attached to an annular shoulder (9 ) is directly or indirectly axially supported, characterized in that the cylinder bore (4) in the area of the annular shoulder (9) has a diameter (Dl) which is equal to or larger than a diameter (D2) in the area of an end opening (10) of the cylinder bore (4).

2. High-pressure pump (1) according to claim 1, characterized in that the end section (7) of the cylinder bore (4) receiving the piston sealing ring (8) has a constant diameter (Dl, D2) has.

3. High-pressure pump (1) according to claim 1 or 2, characterized in that the piston sealing ring (8) directly or indirectly via a sleeve-shaped holding element (11) which surrounds the piston sealing ring (8) at least in sections, in the end section (7) the cylinder bore (4) is used, preferably pressed.

4. High-pressure pump (1) according to Claim 1 or 2, characterized in that the piston sealing ring (8) is held in the end section (7) of the cylinder bore (4) via an annular holding element (11), the holding element (11) preferably being in Area of the opening (10) is pressed into the end section (7) and supported axially on the piston sealing ring (8).

5. High-pressure pump (1) according to Claim 1 or 2, characterized in that an annular or sleeve-shaped holding element (11) surrounding the piston sealing ring (8) at least in sections extends into a recess (12 ) and/or engages in a recess (13) of the piston sealing ring (8), the recess (12) and/or the recess (13) preferably being designed as an annular groove or being.

6. High-pressure pump (1) according to claim 1 or 2, characterized in that outside of the cylinder bore (4) a retaining element (11) is arranged, which encompasses a cylinder bore (4) forming the cylinder (14), the retaining element ( 11) is connected to the cylin (14) via a plug, clamp, press, snap-in and/or screw connection.

7. The high-pressure pump (1) according to claim 1, characterized in that the piston sealing ring (8) has at least one geometry (15) on the outer circumference, which fits into a geometry (16) of opposite design that widens the end section (7) of the cylinder bore (4). grabs.

8. High-pressure pump (1) according to claim 1, characterized in that the end opening (10) of the cylinder bore (4) is delimited by an annular collar (17), so that the diameter (D2) is smaller than the diameter (D1). , wherein preferably the annular collar (17) is provided with an insertion cone (18).

9. High-pressure pump (1) according to Claim 1, characterized in that the piston sealing ring (8) is held with the aid of a pin (19) which is arranged transversely to a longitudinal axis (A) of the cylinder bore (4) and is formed in a Groove (20) of the piston sealing ring (8) engages.