JP2006510835A - High pressure pump for fuel injection device of internal combustion engine - Google Patents

Abstract

The present invention relates to a high-pressure pump for a fuel injection pump of an internal combustion engine, this high-pressure pump comprising a casing (10), in which at least one pump element (32) is arranged. The pump element (32) is connected via a transmission member (28) by a drive shaft (12) rotatably supported in the casing (10) via at least one support point (14, 16). In this case, the drive shaft (12) has an eccentric body section (26), and a transmission member (28) is provided to the eccentric body section (26). Is supported rotatably via a bearing point (30). Via a passage system (54, 55, 57) extending through the drive shaft (12) to the bearing point (30) of the transmission member (28) in the eccentric body section (26) of the drive shaft (12). Fuel is supplied for lubrication.

Description

  The present invention relates to a high-pressure pump for a fuel injection device for an internal combustion engine described in the superordinate conceptual part of claim 1.

  Such a high-pressure pump is known from German Offenlegungsschrift DE 1948035. This known high-pressure pump has a casing in which at least one pump element is arranged. The pump element has a plunger which is driven in a stroke motion via a drive shaft which is rotatably supported in the casing. The drive shaft has an eccentric body section, and a transmission member is rotatably supported by the eccentric body section via a bearing bush. The drive shaft is supported in the casing via two support locations each having a bearing bush. In the casing, the lubrication of the support portion of the transmission member in the eccentric body section of the drive shaft and the lubrication of the support portion of the drive shaft are performed by the fuel present in the casing. When fuel is pumped under very high pressure by a high-pressure pump, a correspondingly high load is generated, especially at the bearing point of the transmission member and the bearing point of the drive shaft, so that the lubrication by the fuel present in the casing is no longer sufficient. The bearing point will be exposed to high wear.

Advantages of the invention In contrast, the high-pressure pump according to the invention with the features as claimed in claim 1 is improved by an inexpensive structural cost for lubrication of at least the bearing part of the transmission member in the eccentric section of the drive shaft. The high-pressure pump has an advantage that the fuel can be pumped under a very high pressure, and the wear of the support portion is small.

  Advantageous configurations and embodiments of the high-pressure pump according to the invention are described in the dependent claims. The embodiment of claim 3 also improves the lubrication of at least one bearing point of the drive shaft. According to the embodiments as claimed in claims 4 and 5, the lubrication of the bearing points is further improved by improving the fuel splitting at the bearing points. The embodiment as claimed in claim 6 allows simple manufacture of the passage system in the drive shaft. According to the embodiments as claimed in claims 7 and 8, the supply of fuel into the driveshaft passage system is possible in a simple manner by means of the driveshaft support.

Drawings One embodiment of the invention is shown in the drawings and is described in detail below. 1 is a fuel injection device for an internal combustion engine equipped with a high-pressure pump, FIG. 2 is an enlarged cross-sectional view of the high-pressure pump, and FIG. 3 is an enlarged view of a portion indicated by reference numeral III in FIG. FIG. 4 and FIG. 4 are enlarged views of a portion indicated by reference numeral IV in FIG.

  FIG. 1 shows a fuel injection device for an internal combustion engine which is a self-ignition internal combustion engine. The fuel injection device has a high-pressure pump 100, which supplies fuel under high pressure up to 2000 bar (bar) to the accumulator 110. A pipe line 120 branches from the accumulator 110 to an injector 130 arranged in a cylinder of the internal combustion engine. These injectors 130 inject fuel into the combustion chamber of the cylinder. Fuel is supplied from the storage tank 150 to the suction side of the high-pressure pump 100 by the feed pump 140. A fuel metering device 160 is arranged between the feed pump 140 and the high-pressure pump 100, and the fuel metering device 160 can variably adjust the inflow of fuel from the feed pump 140 to the high-pressure pump 100. From the connection between the feed pump 140 and the high-pressure pump 100, a lubrication connection 170 leading to the drive region of the high-pressure pump 100 branches off. In this case, the high-pressure pump 100 and its drive region will be described in detail below. ing. A pressure valve 180 is disposed in the lubrication connection 170, and the pressure valve 180 first opens the lubrication connection 170 when a predetermined pressure is exceeded. The flow through the lubrication connection 170 is restricted in an advantageous manner by the restriction point 190.

  FIG. 2 shows the high-pressure pump 100 in an enlarged manner. The high-pressure pump has a casing 10, and the casing 10 is composed of a plurality of parts, and a drive shaft 12 is disposed in the casing 10. The drive shaft 12 is rotatably supported in the casing 10 via two support portions 14 and 16 that are spaced from each other in the direction of the rotation axis 13 of the drive shaft 12. These bearing points 14, 16 are arranged in different parts of the casing 10. Within the region of the support points 14, 16, the casing 10 has one hole 18, 20, respectively, in which the drive shaft 12 is supported via one bearing bush 22, 24. ing.

  In the region existing between the two bearing points 14, 16, the drive shaft 12 has an eccentric body section 26, on which a transmission member 28 in the form of a polygonal ring is mounted. It is supported rotatably through. The high-pressure pump 100 has at least one, preferably a plurality of pump elements 32, arranged in the casing 10, each of which has a plunger 34, which plunger 34 Is driven by the transmission member 28 with at least a substantially radial stroke movement with respect to the rotation axis 13 of the drive shaft 12. The plunger 34 is guided so as to be airtight and slidable in a cylinder hole 36 in the casing 10 or in an insert (insertion member) in the casing 10. A pump working chamber 38 is defined in the hole 36. The pump working chamber 38 is connected to the feed pump 140 via a fuel inflow passage 40 extending into the casing 10. An inlet valve 42 that opens into the pump working chamber 38 is disposed at the opening of the fuel inflow passage 40 into the pump working chamber 38, and this inlet valve 42 has a spring-loaded valve member 43. Yes. Further, the pump working chamber 38 is connected to the accumulator 110 via a fuel outflow passage 44 extending into the casing 10. An outlet valve 46 opened from the pump working chamber 38 is arranged at the opening of the fuel outflow passage into the pump working chamber 38. The outlet valve 46 has a spring-loaded valve member 47 as well. .

  The plunger 43 has a piston foot 50 held in contact with and held by the transmission member 28 by a preloaded spring 48. When the drive shaft 12 rotates, the transmission member 28 does not move together with the drive shaft 12, but performs a movement perpendicular to the rotation axis 13 of the drive shaft 12 based on the eccentric section 26. This vertical movement causes a stroke movement of the plunger 34. During the plunger 34 intake stroke, where the plunger 34 moves radially inward, the pump working chamber 38 is filled with fuel by the fuel inlet passage 40 at the open inlet valve 42, in which case the outlet valve 46 is closed. Has been. During the feed stroke of the plunger 34, where the plunger 34 moves radially outward, fuel is supplied by the plunger 34 under high pressure to the accumulator 110 through the fuel outlet passage 44 at the open outlet valve 46, in this case. The inlet valve 42 is closed.

  A lubrication connection 170 extending from the feed pump 140 extends through the passage 52 in the casing 10. The passage 52 is open on the outer peripheral surface of the drive shaft 12. A passage system is formed in the drive shaft 12, and a passage 52 is opened in the passage system so that the fuel is under pressure by the passage system and the transmission member 28 on the eccentric section 26 of the drive shaft 12. The bearing point 30 is supplied, where fuel exits the passage system and lubricates the bearing point 30. The passage system in the drive shaft 12 has a first passage section 54 which extends, for example, at least approximately radially with respect to the rotational axis 13 of the drive shaft 12. The hole extends from the outer peripheral surface of the drive shaft 12 into the drive shaft 12, and the hole reaches almost the center of the drive shaft 12. The first passage section 54 opens on a plane on the outer peripheral surface of the drive shaft 12 where the opening of the passage 52 is located in the casing 10. A second passage section 55 is connected to the first passage section 54, and this second passage section 55 extends in the direction of the rotation axis 13 of the drive shaft 12, for example coaxially with the rotation axis 13. Yes. The second passage section 55 is configured as a longitudinal (longitudinal) hole, particularly a blind hole, formed in the drive shaft 12 from the end face side of the drive shaft 12. The second passage section 55 is closed with respect to the end face side of the drive shaft 12 by a closing member 56 formed in the drive shaft 12. A third passage section 57 is connected to the second passage section 55, and this third passage section 57 extends at least substantially in the radial direction with respect to the rotational axis 13 of the drive shaft 12, for example. The hole is formed as a hole formed in the drive shaft 12 from the outer peripheral surface of the drive shaft 12. The hole reaches almost the center of the drive shaft 12 and opens in the second passage section 55. The third passage section 57 is open at the outer peripheral surface of the eccentric body section 26 of the drive shaft 12, preferably at least approximately in the center of the bearing point 30 of the transmission member 28. The fuel fed from the feed pump 140 passes through the lubrication connection 170, the passage 52, and the passage systems 54, 55, 57 in the drive shaft 12 to support the transmission member 28 in the eccentric body section 26 of the drive shaft 12. 30, where it now flows out to lubricate the drive shaft 12.

  The transmission member 28 may be supported directly on the eccentric body section 26. Alternatively, the transmission member 28 may be supported on the eccentric body section 26 via a bearing bush 58. In this case, the bearing bush 58 may be constructed in one piece, as shown in FIG. 3, or in two parts, as shown in FIG. In this case, the bearing bush 58 is divided into two parts arranged side by side in the direction of the rotation axis 13 of the drive shaft 12, and a gap 59 is provided between these two parts. The gap 59 is advantageously located in the plane in which the third passage section 57 opens on the outer peripheral surface of the eccentric body section 26. The lubrication of the bearing location 30 is further improved by the divided bearing bushes 58. This is because the fuel flowing out from the third passage section 57 is well divided at the bearing point 30.

  In addition to the bearing point 30 of the transmission member 28 in the eccentric body section 26, one or two bearing points 14, 16 of the drive shaft 30 in the casing 10 are also lubricated by the passage system in the drive shaft 12. . In this case, the second passage section 55 extends to the support location 16 in the direction of the rotational axis 3 of the drive shaft 12, and the fourth passage segment 60 is connected to the second passage section 55 at the support location 16. Has been. The fourth passage section 60 extends, for example, at least substantially in the radial direction with respect to the rotational axis 13 of the drive shaft 2, and is configured as a hole formed in the drive shaft 12 from the outer peripheral surface of the drive shaft 12. The hole reaches almost the center of the drive shaft 12 and opens into the second passage section 55. The fourth passage section 60 opens on the outer peripheral surface of the drive shaft 12 at at least approximately the center of the support location 16 of the drive shaft 12. The bearing bush 24 of the bearing point 16 is constructed in one piece or in two parts as described above in relation to the bearing bush 58 with a gap 25 between the two parts. Also good.

  In addition, the bearing point 14 of the drive shaft 12 in the casing 10 can also be lubricated by the fuel sent by the feed pump 140 via the lubrication connection 170 and the passage 52. In this case, the first passage section 54 is preferably open at least approximately in the middle of the support location 14 in the region of the support location 14 on the outer peripheral surface of the drive shaft 12. In this case, the fuel can reach the first passage section 54 from the passage 52 through the bearing bush 22 at the bearing point 14. For this purpose, the bearing bushing 22 may be composed of two parts, as shown in FIG. 2 and as described in connection with the bearing bushing 58, in this case between the parts of the bearing bushing 22. The gap 23 is located in the plane of the opening of the first passage section 54 on the outer peripheral surface of the drive shaft 12.

  FIG. 4 shows an embodiment of the bearing bush 22 that is integrally formed. In this case, the bearing bush 22 has an annular groove 62 on its inner peripheral surface, and the annular groove 62 is formed by undercut (Einstich). The annular groove 62 is disposed in the same plane as the opening of the passage 52 on the outer peripheral surface of the bearing bush 22 and the opening of the first passage section 54 on the inner peripheral surface of the bearing bush 22. Further, the bearing bush 22 has at least one hole 64, and the hole 64 connects the annular groove 62 to the outer peripheral surface of the bearing bush 22. Fuel from the passage 52 passes through the hole 64 and the annular groove 62 to reach the first passage section 54 of the drive shaft 12.

  Outflow passages 66 are respectively provided in the casing 10 in the region of the support points 14 and 16, and the fuel flows out from the support points again through the outflow passages 66.

It is the schematic of the fuel-injection apparatus of the internal combustion engine provided with the high pressure pump. It is an expanded sectional view of a high pressure pump. It is an enlarged view of the part shown by the code | symbol III of FIG. FIG. 4 is an enlarged view of a portion indicated by reference numeral IV in FIG.

Claims (9)

A high-pressure pump for a fuel injection device of an internal combustion engine, comprising a casing (10), in which at least one pump element (32) is arranged, the pump element (32 Is driven in a stroke motion via a transmission member (28) by a drive shaft (12) rotatably supported in the casing (10) via at least one bearing point (14, 16) (34). In this case, the drive shaft (12) has an eccentric body section (26), and the transmission member (28) has a support point (30) in the eccentric body section (26). In the form of being supported rotatably through
Via a passage system (54, 55, 57) extending through the drive shaft (12) to the bearing point (30) of the transmission member (28) in the eccentric body section (26) of the drive shaft (12). A high-pressure pump for a fuel injection device of an internal combustion engine, characterized in that fuel is supplied for lubrication.   2. The high-pressure pump according to claim 1, wherein the transmission member (28) is supported on the eccentric body section (26) via a bearing bush (58).   Fuel is also supplied for lubrication to the at least one bearing point (16) of the drive shaft (12) in the casing (10) via the passage system (54, 55, 60) in the drive shaft (12). In this case, the drive shaft (12) is supported in the casing (10) via the bearing bushes (24) in an advantageous manner in at least one bearing point (16). The high pressure pump according to claim 1 or 2.   The bearing bush (22, 24, 58) of the transmission member (28) and / or the drive shaft (12) is divided into two parts arranged side by side in the direction of the rotational axis (13) of the drive shaft (12). 4. The high-pressure pump according to claim 2, wherein a gap (23, 25, 59) is provided between the two parts.   The drive shaft (12) has gaps (23, 25, 59) between the parts of the bearing bushes (22, 24, 58), the passage system (54, 55, 57) is open on the outer peripheral surface of the drive shaft (12). 5. The high-pressure pump according to claim 4, wherein the high-pressure pump is arranged in a plane extending at least approximately radially with respect to the axis of rotation (13).   The passage system has a first passage section (54) that opens to the outer peripheral surface of the drive shaft (12), and extends into the casing (10) in the first passage section (54). At least approximately the axis of rotation (13) of the drive shaft (12), wherein the passage system is further connected to the first passage section (54). ) And a second passage section (55) extending in the direction of), and connected to the second passage section (55) and on the outer peripheral surface of the drive shaft (12) at the support point (30) of the transmission member (28). 6. The high-pressure pump according to claim 1, comprising an open third passage section (57). 7.   The passage (52) extending into the casing (10) is open to a support location (14) where the drive shaft (12) is supported in the casing (10) via a bearing bush (22), A first passage section (54) in the bearing bush (22) opens into the outer peripheral surface of the drive shaft (12) and extends into the first passage section (54) and the casing (10). 7. The high-pressure pump according to claim 6, wherein the connection with the passage (52) is made through the bearing bush (22).   An annular groove (62) is formed in the inner peripheral surface of the bearing bush (22), and the annular groove (62) is in a radial plane in relation to the rotational axis (13) of the drive shaft (12). Arranged in the radial plane, the passage system (54) opens to the outer peripheral surface of the drive shaft (12), the annular groove (62) in an advantageous manner in the bearing bush (22). The high-pressure pump according to claim 7, wherein the high-pressure pump is connected to the outer peripheral surface of the bearing bush (22) via at least one hole (64). A fuel injection device for an internal combustion engine comprising the high-pressure pump according to any one of claims 1 to 8,
Fuel is supplied to the high pressure pump (100) by the feed pump (140), and a part of the fuel sent by the feed pump (140) is passed through the lubrication connection (170) to the passage system (54, 55, 57, 60) and a pressure valve (180) and / or a throttle point (190) opening in the lubrication connection (170) in an advantageous manner towards the passage system (54, 55, 57, 60). A fuel injection device for an internal combustion engine equipped with a high-pressure pump.

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