DE10322595B4 - Piston pump, and process for its preparation - Google Patents

Abstract

Piston pump (16), in particular high-pressure fuel pump, with a metallic housing (24) to which at least one tubular component, for example a cylinder liner (36), an inlet port (80), an outlet port (82), and so on, is attached in that the tubular component (36, 80, 82) is non-detachably connected (58; 76) to the housing (24), characterized in that the tubular component (36) has a face (54) facing the housing (24) circumferential, extending from the end face (54) axially extending collar (108) which abuts against the collar (108) at least approximately orthogonal surface on the housing (24) and is welded thereto (58).

Description

State of the art

The invention initially relates to a piston pump, in particular a high-pressure fuel pump, with a metallic housing, to which at least one tubular component, for example a cylinder liner, an inlet nozzle, an outlet nozzle, and so forth, is attached.

The invention also relates to a method for producing a piston pump, in particular a high-pressure fuel pump, in which a tubular component made of stainless steel, for example a cylinder liner, an inlet connection, an outlet connection, and so on, is fastened to a pump housing.

A piston pump and a method of the type mentioned are from the EP 1 162 365 A1 known. This shows a high-pressure fuel pump for an internal combustion engine with a piston which can be set in a reciprocating motion and thus compresses a fuel enclosed in a delivery chamber. The piston is slidably guided in a cylinder liner of a hardened stainless steel, which is clamped between a housing part and a locking screw.

A disadvantage of the known piston pump is the fact that the production of screw is expensive, and that the sealing of such screw over the life of the piston pump may deteriorate. Finally, a screw has a certain amount of space that increases the overall dimensions of the piston pump. However, the installation space necessary for such a pump is often difficult to obtain.

DE 199 28 913 A1 describes a piston pump with a piston sleeve which is caulked in the housing indirectly.

The present invention therefore has the object, a piston pump and a method of the type mentioned in such a way that the piston pump can be manufactured inexpensively, has a long life, and builds as small as possible.

This object is achieved by a piston pump or a method having the features of the independent claims.

Advantages of the invention

With such insoluble compounds, such as welded joints or caulking, the tightness of the connection over the entire life of the piston pump is guaranteed. This is especially important in view of future legal limits that are to be expected regarding the evaporative emission of fuel. The life of the piston pump according to the invention is high, since the problem of Losdrehens the clamping screw in operation by shaking loads can no longer occur due to the permanent connection. Furthermore, the piston pump according to the invention builds comparatively small, since O-rings for sealing, as well as support rings and threads, which are required in glands, are no longer needed. Furthermore, the manufacturing costs can be reduced in the piston pump according to the invention, since components and material can be saved, and since lower requirements can be placed on the tolerances of the components or components used.

A good welding connection, for example by means of resistance welding, is produced directly between the component and the housing, in that the tubular component has, on a face facing the housing, a circumferential collar extending axially from the end face, which collar is at least approximately orthogonal to the collar on the housing is present and welded to this.

Advantageous developments of the invention are specified in subclaims.

In one embodiment, it is provided that the tubular component has a larger inner diameter in that axial region in which it is fastened than outside this region. If the component is, for example, a cylinder bushing in which a piston is to be slidably received, this ensures that the actual guide surface of the piston can be deformed as required, for example, by the action of the retaining element, welding or caulking , etc., are not affected. The free and smooth movement of the piston is therefore also without subsequent processing of existing in the tubular component bore.

Very favorable is also an embodiment of the piston pump according to the invention, in which one of the two sections to be welded together is conical, and that the other section is formed by an annular edge of an opening which bears against the conical section. As a result, a self-centering is effected, which simplifies the assembly and increases the process reliability in the production of the welded joint. In addition, so can the requirements of the Tolerances of the individual parts are kept particularly low, which reduces the manufacturing costs.

It is also proposed that the tubular component has a sealing device, which is received in an installed position in an opening of the housing, and that the weld seam, with which the component is at least indirectly fixed to the housing, viewed from the opening to the component behind the sealing device is. This prevents spatter occurring during the welding process from entering the housing interior of the piston pump. By means of a corresponding design of the sealing device, it is also possible to keep very small splashes and possibly also smoke away from the interior of the pump housing. If a corresponding shielding device is also provided on the outside, no splashes can adhere to the external components.

drawing

Embodiments will be explained in more detail with reference to the accompanying drawings. In the drawing show:

1 a schematic representation of an internal combustion engine with a high-pressure fuel pump;

2 a partial section through a first embodiment of the high pressure piston pump of 1 ;

3 a section through a portion of a second embodiment of the high pressure piston pump of 1 ;

4 a representation similar 3 a third embodiment of the high-pressure piston pump of 1 ;

5 a representation similar 3 a fourth embodiment of the high pressure piston pump of 1 ;

6 a representation similar 3 a fifth embodiment of the high pressure piston pump of 1 ;

7 a representation similar 3 a sixth embodiment of the high-pressure piston pump of 1 ;

8th a representation similar 3 a seventh embodiment of the high-pressure piston pump of 1 ;

9 a section through an eighth embodiment of the high pressure piston pump of 1 ;

10 a sectional view from above through a ninth embodiment of the high pressure piston pump of 1 ;

11 a sectional view taken along the line XI-XI of 10 ;

12 a representation similar 9 A tenth embodiment of the high-pressure piston pump of 1 ;

13 a representation similar 9 an eleventh embodiment of the high pressure piston pump of 1 ;

14 a representation similar 9 a twelfth embodiment of the high-pressure piston pump of 1 ;

15 a section through a portion of a thirteenth embodiment of the high-pressure piston pump of 1 ;

16 a plan view along the direction XVI of 15 ;

17 a representation similar 2 a fourteenth embodiment of the high-pressure piston pump of 1 ;

18 a representation similar 2 a fifteenth embodiment of the high-pressure piston pump of 1 ;

19 a representation similar 2 a sixteenth embodiment of the high-pressure piston pump of 1 ;

20 an enlarged view of a portion of a seventeenth embodiment of the high-pressure piston pump of 1 ;

21 a representation similar 20 an eighteenth embodiment of the high-pressure piston pump of 1 ; and

22 a representation similar 20 a nineteenth embodiment of the high pressure piston pump of 1 ,

Description of the embodiments

In 1 an internal combustion engine carries the reference numeral 10 , It includes a fuel tank 12 from which a prefeed pump 14 Fuel to a high-pressure piston pump 16 and on to a fuel rail 18 ( "Rail") promotes. There are several fuel injectors on them 20 connected, the fuel directly into them associated combustion chambers 22 inject.

A first possible embodiment of the in 1 shown high-pressure piston pump 16 is in partial section in 2 shown. The high pressure piston pump 16 includes a pump housing 24 , which is made of a machinable and weldable stainless steel, and in the outer circumferential surface of various holes 26 and 28 are present for receiving an inlet nozzle or outlet nozzle, not shown in this figure. In 2 above the pump housing 24 is on this a pressure damper 30 attached. In a stepped blind hole 32 coaxial with a longitudinal axis 34 of the pump housing 24 runs, is a tubular component, namely a cylinder liner 36 , which is made of hardened stainless steel. In a pilot hole 37 the cylinder liner 36 is a piston 38 guided smoothly. The inner diameter of the guide bore 37 the cylinder liner 36 is constant over its length. An intermediate element 40 made of plastic, which also in an area of the blind hole 32 of the pump housing 24 is arranged, carries a piston seal 42 ,

The cylinder liner 36 has an in 2 upper section 44 with larger outer diameter and an in 2 lower section 46 with a smaller outer diameter, passing through a heel 48 are separated from each other. An area 50 the blind hole 32 has a slightly smaller inner diameter than the outer diameter of the area 44 the cylinder liner 36 , During assembly, the cylinder liner 36 with her area 44 in the area 50 the blind hole 32 pressed. It is fluid-tight in the pump housing in this way 24 fixed. The high contact forces required for mounting are via the heel 48 introduced in the axial direction. As a result, deformations in the area of the guide bore 37 prevents without the cylinder liner 36 must have a large wall thickness. A thin-walled cylinder liner 36 but has the advantage that less space is required.

Then a retaining ring 52 made of a machinable and weldable steel, on the cylinder liner 36 deferred, in such a way that the latter with their the pump housing 24 facing end face 54 against a paragraph 56 the blind hole 32 is charged. Then the retaining ring 52 on the pump housing 24 welded (reference numeral 58 ). By using a retaining ring, the cylinder liner 36 unsolvable with the housing 24 connects, connections can be realized from different material combinations. So it is possible to combine hardened stainless steel with non-hardened stainless steel.

An alternative to this is in 3 shown. For these and all subsequent figures, elements and regions which are functionally equivalent to elements and regions mentioned in previously described figures bear the same reference numerals and will not be explained again in detail.

At the in 3 the embodiment shown has the retaining ring 52 not like in 2 , an approximately rectangular cross-section, but it comprises two areas 60 and 62 with different inner diameters. Between the two areas is a paragraph 64 available. The retaining ring 52 is now first on the cylinder liner 36 Pressed fluid-tight. Due to the increased stiffness of the cylinder liner in their area 44 and due to the fact that the retaining ring 52 Made of a comparatively soft stainless steel, this is without deformation of the guide bore 37 the cylinder liner 36 possible. Is still a deformation of the guide hole 37 not exclude, this can also only after pressing the retaining ring 52 on the cylinder liner 36 be finished (for example by honing). Deformations caused by the press-fitting of the retaining ring 52 are caused, are thus removed again.

Now the cylinder liner 36 together with the retaining ring 52 in the stepped blind hole 32 in the pump housing 24 introduced. It stands the pump housing 24 facing end face (without reference numeral) of the retaining ring 52 then, if his paragraph 64 at the heel 48 the cylinder liner 36 rests, something over the face 54 the cylinder liner 36 above. If the cylinder liner 36 So in the blind hole 32 is introduced, comes only the end face of the retaining ring 52 , but not the face 54 the cylinder liner 36 at the heel 56 the blind hole 32 in Appendix. Resistance welding now turns the weld 58 between the end face of the retaining ring 52 and the paragraph 56 the blind hole 32 generated.

Another variant of the connection of the cylinder liner 36 with the pump housing 24 is in 4 shown: In this are the retaining ring 52 and the cylinder liner 36 positively connected with each other. For this purpose, first the retaining ring 52 on the cylinder liner 36 pressed to size. Then the retaining ring 52 in a circumferential groove 66 in the outer circumferential surface of the cylinder liner 36 rolled. Thereafter, if necessary, the fine machining and finally in 58 the welding with the pump housing 24 instead of.

Another variant is in 5 shown. This is similar to the variant of 3 , The retaining ring 52 is with a small clearance in the blind hole 32 in the pump housing 24 inserted, in such a way that the cylinder liner 36 with the face 54 at the heel 56 of the pump housing 24 is applied. The weld 58 is then between retaining ring 52 and pump housing 24 produced by laser welding. It should be noted that the inner diameter of the range 62 of the retaining ring 52 greater than the outer diameter of the area 46 the cylinder liner 36 , resulting in a gap s (a similar gap is also found in the embodiment of FIG 3 ), and that the axial length of the area 62 is greater than the depth of the weld 58 , This will ensure that the guide bore 37 does not warp during welding.

Another difference from the previous embodiments relates to the overall axial length of the retaining ring 52 : While in the embodiments of the 3 and 4 the retaining ring 52 with his the pump housing 24 facing edge over the face 54 the cylinder liner 36 The situation is exactly the opposite: the axial length of the area 60 of the retaining ring 52 is slightly shorter than the axial length of the heel 48 the cylinder liner 36 to the frontal area 54 , Therefore lies in installation position, the end face 54 the cylinder liner 36 at the heel 56 at.

A variant of the embodiment of 5 shows 6 : This is the retaining ring 52 in the blind hole 32 in the pump housing 24 pressed. In the outer surface of the retaining ring 52 are three spaced slightly spaced grooves 72 brought in. Through these grooves 72 become dome-shaped bulges 74 formed, which also extend in the circumferential direction. Through these bulges of material 74 may be the soft material of the retaining ring 52 partially deform, without in the guide hole 37 the cylinder liner 36 To cause deformations. That area of the retaining ring 52 in which at a later date the weld 58 is attached, has no such bulges 74 , so there due to the higher pressing force of the section 62 of the retaining ring 52 when pressing in the retaining ring 52 in the blind hole 32 in the pump housing 24 is deformed radially inward. But this also has no consequences for the pilot hole 37 the cylinder liner 36 because in this area 62 of the retaining ring 52 between the retaining ring 52 and the cylinder liner 36 the gap s is present.

The 7 and 8th show further variants of the permanent connection of the retaining ring 52 with the pump housing 24 , They essentially correspond to those in 5 and 6 shown embodiments, wherein the compound instead of a weld by means of caulking 76 the outer edge 70 the blind hole 32 of the pump housing 24 will be produced.

Another variant is in 9 represented: It resembles that of 2 but between the retaining ring 52 and the outer surface of the cylinder liner 36 a gap s is present. This can, as in the right half of 9 is shown, also the shape of an undercut 78 assume, which in the outer circumferential surface of the cylinder liner 36 is introduced. As a result, the support surface in the axial direction between the paragraph 48 the cylinder liner 36 and the retaining ring 52 maximizes without the outside diameter of the area 44 the cylinder liner 36 to enlarge. This saves costs and installation space. The weld between retaining ring 52 and housing 24 bears the reference number 58a ,

As further on the right side of 9 is shown, the inner bore of the cylinder liner 36 an area 37a with larger inside diameter and an area 37b having a small inner diameter. The latter represents the actual guide bore. A deformation of the area 37a , which possibly when pressing the cylinder liner 36 in the blind hole 32 of the pump housing 24 caused, remains so for the guide hole 37a without consequences. Their subsequent fine machining can thus be omitted.

In 9 are also the connections of other tubular components with the pump housing 24 shown. In particular, this relates to the connection of an inlet nozzle 80 made of brass, which enters the inlet hole 26 is used, and an outlet 82 made of a non-hardened stainless steel, which is in the outlet hole 28 is inserted, each with the pump housing 24 , The inlet nozzle 80 is initially on the front side to measure in the inlet bore 26 pressed in and with a fillet weld 58b tightly welded. The outlet nozzle 82 has a circumferential paragraph 84 on. He is so in the outlet hole 28 pressed that paragraph 84 flush with the outer wall of the pump housing 24 concludes. Then he gets over an I-seam 58c with the pump housing 24 welded.

Another variant is in the 10 and 11 shown. Out 10 shows that the pump housing 24 has an overall hexagonal shape. It can be designed, for example, as an extruded or turned or milled polygonal profile. This facilitates the assembly process of the inlet nozzle 80 and the outlet 82 , as in particular in resistance welding, a high contact pressure is required (arrows 88 ), thanks to the design of the in 10 shown pump housing 24 can be safely supported (arrow 90 ).

How out 11 indicates the inlet port 80 and the outlet nozzle 82 one each the pump housing 24 facing and conically tapering to this connection surface 92 on. At this lies the outer edge (without reference numeral) of the straight inlet bore 26 or outlet hole 28 at. This will cause the nozzles 80 and 82 self-centering when inserting, which simplifies assembly. The corresponding weld 58 is manufactured by resistance welding, for example inverter or capacitor and discharge welding.

At both ports 80 and 82 is outside of the pump housing 24 one each radially outwardly extending circumferential collar 96 available. This can attack during the welding process, a tool, with the one to the corresponding nozzle 80 respectively 82 against the pump housing 24 is applied to the one and the other for the production of the weld 58 or 58 required electrical contact with the nozzle 80 respectively 82 will be produced.

A variant of in 11 shown embodiment is in 12 shown: In this point, the nozzle 80 and 82 at one in installation position of the weld 58 into the inlet or outlet bore 26 respectively. 28 extending section 98 a radially outward to the wall of the inlet or outlet hole 26 respectively. 28 extending circumferential sealing edge 100 on which the inner wall of the corresponding hole 26 respectively. 28 touched linearly. By this it is prevented that when making the weld 58 Splashes or smoke in the interior of the pump housing 24 reach.

How out 13 can be seen, alternatively, in a circumferential groove 102 in the section 98 a sealing ring 100 be used. Again, as an alternative, as out 14 it can be seen, even simply a corresponding sealing ring between the nozzle 80 respectively. 82 and a paragraph 104 the bore 26 respectively. 28 be placed. In this case, the circumferential groove in the nozzle can 80 respectively. 82 be waived.

Like from the 15 and 16 can also be an angled neck 82 with the pump housing 24 be welded. This is done for the production of the weld 58 a in 16 dashed shown half-shell-like tool 106 used, which on both sides of the coaxial with the inlet hole 28 extending portion (without reference numeral) of the nozzle 82 is arranged.

A variant of the attachment of the cylinder liner 36 on the pump housing 24 shows 17 : The cylinder liner 36 is similar to in 2 formed, with a retaining ring 52 is waived. Instead, it is between the area 44 the cylinder liner 36 , which has a comparatively large outer diameter, and the radially opposite region of the blind bore 32 a small gap (without reference numeral) available. The cylinder liner 36 So it is in the blind hole 32 not pressed in. The welding 58 takes place directly between the face 54 the cylinder liner 36 and the paragraph 56 the blind hole 32 , The corresponding weld 58 is, since not accessible from the outside, for example, introduced by a resistance welding process.

A modified form of a cylinder liner 36 is in 18 shown. There has the end face 54 the cylinder liner 36 a radially outer and axially extending in the form of a collar raised edge region 108 on. In this way, the position at which the weld is 58 is generated, precisely defined. Furthermore, in the cylinder liner 36 in the outer lateral surface of a circumferential constriction 110 present, which for the simple attack of a tool, such as a welding gun, serves, with the one hand, the axial contact force can be applied, with the cylinder liner 36 during the welding process against the heel 56 the blind hole 32 on the other hand, the electrical contact between the welding machine and the cylinder liner 36 will be produced.

Similar constrictions are also on the neck 80 and 82 available. They also carry the reference numeral for the sake of simplicity 110 , A corresponding welding tool 106 is in 18 at the outlet 82 indicated by dash-dotted lines. While in 18 surfaces 112 where the welding tool 106 on the cylinder liner 36 or at the two nozzles 80 and 82 engages, approximately at an angle of 60 ° relative to the longitudinal axis of these components is in 19 a variant shown at this attack surface 112 is at a right angle to the longitudinal axis of the corresponding component.

Another variant of the direct connection of the cylinder liner made of hardened stainless steel 36 with the pump housing made of a soft stainless steel 24 is in 20 shown. It is at the radially outer edge of the end face 54 the cylinder liner 36 an axially extending and tapered collar 108 formed, with which the cylinder liner 36 directly on the flat shoulder 56 the blind hole 32 is applied. The outside diameter of the area 44 the cylinder liner 36 is slightly smaller than the lying in this area section of the blind hole 32 , so that between the lateral surface of the area 44 the cylinder liner 36 and the blind hole 32 a gap s is present. The cylinder liner 36 touches the pump housing 24 so only with the tapered edge of the collar 108 ,

Because of the collar 108 at the radially outer edge of the end face 54 the cylinder liner 36 is formed, during assembly of the cylinder liner 36 in which these with high force against the paragraph 56 the blind hole 32 is pressed, the guide hole 37 the cylinder liner 36 not deformed. The contact pressure is applied by a suitable tool, which on the heel 48 the cylinder liner 36 attacks. The weld 58 between the cylinder liner 36 and the pump housing 24 is manufactured by resistance welding. For this weld to be made at the intended location, the gap s should be at least about 0.5 mm. The radially outer layer of the collar 108 also ensures that during operation of the high-pressure piston pump 16 the weld 58 is slightly loaded, since the lateral force of the piston 38 is low.

Alternatively, as can 21 it can be seen, the collar 108 also in the region of the radially inner edge of the end face 54 the cylinder liner 36 to be available. In this case, the leadership of the piston in the cylinder liner 36 not to interfere, an in 21 upper area 37a the inner bore with a slightly larger diameter than the actual guide bore 37b executed. Is it during the assembly of the cylinder liner 36 due to the axial pressure of the cylinder liner 36 against the paragraph 56 the blind hole 32 to a deformation in the upper region of the cylinder liner 36 , this does not affect the quality of the pilot hole 37b the cylinder liner 36 ,

To reduce the manufacturing costs, the outer diameter of the cylinder liner 36 analogous to those in the 18 and 19 shown variants in the area 46 the cylinder liner 36 near the paragraph 48 be provided with a constriction. This is in 21 not shown. The corresponding constriction had in the 18 and 19 the reference number 110 , The same applies with regard to measures to prevent the ingress of splashes and smoke, which arise during welding, in the pump housing 24 , Such measures are in the 12 to 14 in connection with the local nozzles 80 and 82 shown.

A corresponding concrete realization in connection with the cylinder liner 36 is in 22 shown: There is in the face of the cylinder liner 36 a circumferential groove 114 present in which a sealing ring 100 is inserted, with its projecting edge on a corresponding paragraph (without reference numeral) of the blind hole 32 in the pump housing 24 is applied.

Claims (5)

Piston pump ( 16 ), in particular high-pressure fuel pump, with a metallic housing ( 24 ), at which at least one tubular component, for example a cylinder liner ( 36 ), an inlet nozzle ( 80 ), an outlet ( 82 ), and so on, with the tubular component ( 36 . 80 . 82 ) with the housing ( 24 ) is inextricably linked ( 58 ; 76 ), characterized in that the tubular component ( 36 ) on a housing ( 24 ) facing end face ( 54 ) a circumferential, from the end face ( 54 ) axially extending collar ( 108 ), which at one to the collar ( 108 ) at least approximately orthogonal surface on the housing ( 24 ) and is welded thereto ( 58 ). Piston pump ( 16 ) according to claim 1, characterized in that the tubular component ( 36 ) in the axial region in which it is attached, a larger inner diameter ( 37a ) than outside this area ( 37b ). Piston pump ( 16 ) according to one of the preceding claims, characterized in that one of the two sections to be welded together ( 92 ) is conical, and that the other portion is formed by an annular edge of an opening ( 26 . 28 ) formed on the conical section ( 92 ) is present. Piston pump ( 16 ) according to one of the preceding claims, characterized in that the tubular component ( 80 . 82 ) a sealing device ( 100 ), which in an installed position in an opening ( 26 . 28 ) of the housing ( 24 ) and that a weld ( 58 ), with which the tubular component ( 80 . 82 ) at least indirectly on the housing ( 24 ), from the opening ( 26 . 28 ) to the component ( 80 . 82 ) behind the sealing device ( 100 ) is arranged. Method for producing a piston pump ( 16 ), in particular high-pressure fuel pump, in which a tubular component made of a hardened stainless steel, for example a cylinder liner ( 36 ), an inlet nozzle ( 80 ), an outlet ( 82 ), and so on, on a pump housing ( 24 ) and in which the tubular component ( 36 . 80 . 82 ) with the housing ( 24 ) is inextricably linked ( 58 ; 76 ), characterized in that the tubular component ( 36 ) on a housing ( 24 ) facing end face ( 54 ) a circumferential, from the end face ( 54 ) axially extending collar ( 108 ), which at one to the collar ( 108 ) at least approximately orthogonal surface on the housing ( 24 ) and is welded thereto ( 58 ).

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