JP6175567B2 - Pumps, especially fuel high-pressure pumps - Google Patents

Description

  The invention relates to a pump of the type of claim 1, in particular to a high-pressure fuel pump.

  Such a pump in the form of a fuel high-pressure pump is known from US Pat. The pump has a housing portion, and a pump piston is movably disposed in the cylinder bore within the housing portion, and the pump piston defines a pump working chamber in the cylinder bore. The pump has a suction valve, which is arranged in the housing part, by means of which the pump working chamber can be coupled with a supply for the transport medium. A metering device is provided in the supply unit, and the metering device can variably adjust the amount of the transport medium supplied to the pump working chamber. The supply part extends partly through a low-pressure module in which the metering device is arranged, which is connected to the housing part of the pump. In the low-pressure module, for example, a supply-portion connecting portion that can lead from the transport pump to the low-pressure module is arranged. The supply extends from a metering device in the low pressure module, through the base housing part of the pump, to a suction valve arranged in the housing part. The disadvantage of this pump is the complexity of the extension of the feed that passes through the base housing part of the pump, which makes its manufacture complex and expensive. If the pump does not have a base housing part but only a housing part with a cylinder bore, the low-pressure module is not usable.

German Patent Application Publication No. 102011087701A1

  On the other hand, in the pump according to the present invention having the constituent elements described in claim 1, the low pressure module can be directly coupled to the housing portion of the pump in a simple manner, and the housing portion can be directly coupled from the low pressure module. There is an advantage that a complicated hole or the like is not required for the supply portion that leads to the suction valve through the cylindrical protrusion. Thus, the pump is simple, cost-effective and can be manufactured in a compact size.

  The dependent claims describe advantageous and further embodiments of the pump according to the invention. With the configuration according to claim 2, a flexible orientation of the connecting part for the supply part is possible in the pump. The arrangement according to claim 3 and in particular the arrangement according to claim 4 enable a preferred flow guide from the metering device to the suction valve. With the configuration according to the fifth aspect, the low-pressure module and the accompanying pump can be reduced in weight and easily manufactured. The configuration according to claim 7 enables a preferred flow guidance in the low-pressure module from the supply connection to the metering device.

  Two embodiments of the invention are illustrated in the drawings and will be described in detail in the following description.

It is a schematic longitudinal cross-sectional view of the 1st Example of the pump which provided the low voltage | pressure module. It is the figure of the pump seen in the arrow II direction of FIG. It is a figure of the pump of 2nd Example provided with the low voltage | pressure module.

  FIG. 1 shows a pump, which is in particular a fuel high-pressure pump for a fuel injection device of an internal combustion engine. The pump has a housing part 10 which will be referred to below as a cylinder head. The cylinder head 10 has a cylinder bore 12, in which a pump piston 14 is closely guided so as to be displaceable. The pump piston 14 defines a pump working chamber 16 with its end projecting into the cylinder bore 12. The end of the pump piston 14 protruding from the cylinder bore 12 is coupled to a transmission in the form of a roller tappet 20, for example. The roller tappet 20 is supported by a cam 22 of the drive shaft 24, and the cam causes a stroke motion of the pump piston 14 in the cylinder bore 12 when the drive shaft 24 rotates. The drive shaft 24 may be part of a pump or may be part of an internal combustion engine, such as a cam shaft or other shaft of the internal combustion engine.

  The pump working chamber 16 can be coupled to a low-pressure supply unit 27 to the pump via a suction valve 26, and can be coupled to a high-pressure discharge unit communicating with, for example, a high-pressure accumulator 30 via a discharge valve 28. Fuel can be supplied to the low-pressure supply unit 27 by, for example, a transport pump that sucks fuel from the storage container. The suction valve 26 has a valve housing 32 and is formed as a check valve. The suction valve 26 has a piston-like valve member 34, which is guided in the valve housing 32 through its shaft portion 36, and is formed in a head 38 whose diameter is larger than that of the shaft portion 36. The valve member with a face cooperates with a valve seat formed in the valve housing 32. The valve member 34 is urged in the valve closing direction by the valve closing spring 40.

  The cylinder head 10 is inserted into the housing 44 of the base housing of the pump or the housing of the internal combustion engine, for example, the cylinder head or the engine block. In this case, the housing 44 is formed as a hole, for example. In this case, the cylinder head 10 has a flange-shaped region 46, which has a larger cross section than the housing portion 44 and abuts on the outer surface surrounding the housing portion 44. An extension 48 protruding through the accommodating portion 44 is connected to the flange-like region 46 of the cylinder head 10, and the cylinder bore 12 extends into the extension, from which the roller tappet 20 of the pump piston 14 and The joined end protrudes. On the side of the flange-shaped region 46 facing the extension 48, a hollow cylindrical protrusion 50 extending at least substantially coaxially with the cylinder bore 12 is connected to the cylinder head 10.

  The valve housing 32 of the suction valve 26 is inserted into the hollow cylindrical protrusion 50 from the side opposite to the cylinder bore 12. In this case, the valve housing 32 is connected to the protrusion 50 from the cylinder bore 12 of the cylinder head 10. It contacts the annular shoulder 52 formed at the transition part. A set screw 56 is inserted into the protruding portion 50 from the outer surface, and the set screw has a male screw that cooperates with the female screw of the protruding portion 50. The valve housing 32 is pressed against the annular shoulder 52 by the set screw 56 to seal the pump working chamber 16 toward the protrusion 50. In some cases, a packing ring may be disposed between the valve housing 32 and the annular shoulder 52. The set screw 56 has a central withdrawal portion 58 on the inner surface of the valve housing 32, and an end portion of the shaft portion 36 of the valve member 34 protruding from the valve housing 32 and a valve closing spring in the central withdrawal portion. 40 are arranged.

  Around the valve housing 32, at least one or preferably a plurality of supply holes 60 arranged in the circumferential direction are provided, and the fuel enters the suction valve 26 through the supply holes. The valve housing 32 is surrounded by an annular groove 62 with a protrusion 50 having a supply hole 60 open therein. The annular groove 62 is coupled to the outer periphery of the protrusion 50 through at least one hole 64 extending through the protrusion 50.

  At the side of the cylinder head 10, a connecting member 66 having a discharge valve 28 is formed at least substantially perpendicular to the longitudinal axis 13 of the cylinder bore 12. A hydraulic pipe leading to the accumulator 30 can be connected to the connection member 66.

  1 and 2 show a pump according to a first embodiment. A low pressure module 70 is provided for the cylinder head 10, and the supply unit 27 extends to the suction valve 26 through the low pressure module. The low-pressure module 70 has a module housing 72, which is coupled to the cylinder head 10 and placed on the hollow cylindrical protrusion 50 of the cylinder head 10. The module housing 72 is made from a lightweight material, for example a light metal such as aluminum or an aluminum alloy, or plastic. The module housing 72 has a substantially cylindrical shape. In this case, the module housing is placed on the protrusion 50 of the cylinder head 10 and has a drawing-out portion 74 that accommodates the protrusion 50. The module housing 72 abuts on the flange-like region 46 of the cylinder head 10, and a sealing element 76 is fastened and fixed between the module housing 72 and the region 46 in the form of a packing ring, for example. The module housing 72 may be crimped onto the cylinder head 10, for example, or may be secured to the cylinder head 10 using a lock coupling or via at least one or more screws.

  An opening 78 is connected to the drawing-out portion 74 in the module housing 72, and a metering device 80 used to variably adjust the amount of fuel supplied to the suction valve 26 is inserted into the opening. Has been. The metering device 80 is formed as a proportional valve, for example, by means of which a plurality of through-flow cross sections of different sizes can be adjusted. The metering device 80 has a housing, in which a piston 82 is arranged, by means of the piston, a through-flow cross section between a supply opening open to the metering device 80 and a discharge part branched off from the metering device. Is adjusted. The piston 82 can be displaced against the spring 85 by an electric actuator 84, for example, by an electromagnet. Depending on the position of the piston 82, the through-flow cross section of different sizes is adjusted by the piston. Supply into the metering device 80 takes place at least approximately in the radial direction with respect to the longitudinal axis 83 of the piston 82, and the discharge part branches off from the metering device 80 at least approximately coaxially with respect to the longitudinal axis 83 of the piston 82, 72 is opened in the drawing-out portion 74. An annular space is formed between the outer periphery of the projection 50 of the cylinder head 10 and the withdrawal portion 74, and as a result, the fuel reaches the suction valve 26 from the withdrawal portion 74 through the hole 64 in the projection 50. be able to. The weighing device 80 is provided with an electrical connection portion 81 for coupling with an electronic control device for controlling the actuator 84. When coupling the low pressure module 70 with the cylinder head 10, the metering device 80 is arranged such that the longitudinal axis 83 of its piston 82 extends at least approximately coaxially with the cylinder bore 12.

  The module housing 72 has a protruding portion 86 with a hole 87 that protrudes at least substantially radially outward with respect to the drawing-out portion 74. A connecting pipe 88 is inserted into the hole 87, for example, press-fitted. For example, a hydraulic pipe leading from the transport pump to the low pressure module 70 can be connected to the connection pipe 88. The hole 87 in the module housing 72 is coupled to the metering device 80 via another hole 89, where the other hole 89 surrounds the piston 82 of the metering device 80 and is an annular space 90 in the module housing 72. Open in. In this case, the annular space 90 and the hole 87 may be offset from each other in the direction of the longitudinal axis 83 of the piston 82, so that the other hole 89 extends correspondingly obliquely in the module housing 72. Yes.

  During operation of the pump, the fuel is transported by, for example, a transport pump and reaches the hole 87 in the module housing 72 from the storage container through the connection pipe 88 and then into the annular space 90 through the other hole 89. To do. From the annular space 90, fuel reaches the withdrawal section 74 through the through-flow cross section regulated by the piston 82 of the metering device 80 and through the piston 82, from which the supply in the hole 64 and the valve housing 32. The suction valve 26 is reached through the hole 60. The piston 82 of the metering device 80 is likewise arranged coaxially with respect to the suction valve 26 which is arranged coaxially with the cylinder bore 12, so that a favorable inflow of fuel is achieved. During the suction stroke of the pump piston 14, the suction valve 26 is opened, so that fuel flows into the pump working chamber 16. The amount of fuel that flows into the pump working chamber 16 via the suction valve 26 during the suction stroke of the pump piston 14 depends on the cross-flow cross section adjusted by the piston 82 of the metering device 80. If no fuel is to be transported by the pump, the metering device 80 is closed, so that the metering device interrupts the flow-through cross section. Nevertheless, if the fuel reaches the pump and is transported by the pump due to a leak in the metering device, the fuel that has been transported in excess can be released by appropriate measures in the fuel injector. . In some cases, a fuel pump that transports fuel from the storage container to the low-pressure module 70 and the low-pressure module 70 is allowed to escape the fuel that is transported in excess by the transport pump and that is not supplied by the pump metering device 80 A valve may be arranged. In this case, the relief valve is not disposed in the low-pressure module 70 but is disposed, for example, in the transport pump.

  The low-pressure module 70 is provided with a connecting pipe 88 as a single hydraulic connection and an electrical connection 81 for the weighing device 80. For example, no other hydraulic connection for the return path is provided. The low-pressure module 70 can be placed on the cylinder head 10 at an arbitrary rotational position due to the cylindrical configuration of the protrusion 50 of the cylinder head 10, and in this case, a withdrawal portion 74, the withdrawal portion and the cylinder head There is always a coupling state between the discharge part of the metering device 80 and the suction valve 26 via the annular space between the ten protrusions 50.

  FIG. 3 shows a pump with a low pressure module 170 according to a second embodiment. The cylinder head 10 of the pump is configured the same as in the first embodiment, but the low pressure module 170 is configured differently and the metering device 180 is positioned differently. The module housing 172 according to the second embodiment is formed to be flatter than the case of the first embodiment and has a flange 173 provided with an opening 174. In this case, the opening 174 of the module housing 172 is a cylinder. It is placed on the cylinder head 10 so as to surround the protrusion 50 of the head 10. The module housing 172 has a protrusion 186 connected to the side of the flange 173, and a connecting pipe 88 is inserted into the hole 187 at the end of the protrusion. In the module housing 172, another opening 178 is provided between the connecting pipe 88 and the flange 173, and the measuring device 80 is inserted into the other opening. The opening 178 is oriented with its longitudinal axis at least substantially parallel to the longitudinal axis of the opening 174. Another hole 189 is connected to the hole 187 in the module housing 172, and the other hole opens into an annular space 190 that radially surrounds the piston 82 of the metering device 80. A space 191 is formed between the weighing device 80 and the module housing 172, a discharge portion of the weighing device 80 is opened in the space, and the space is coupled to a hole 192 opened in the opening 174. ing. An annular space is formed between the protrusion 50 and the opening 174 in the flange 173 of the module housing 172.

  A sealing element 76 is arranged between the flange 173 of the module housing 172 and the flange-like region 46 of the cylinder head 10. Further, a sealing element 193 in the form of a packing ring, for example, is disposed between the protrusion 50 and the opening 174 of the flange 173 above the hole 64 in the protrusion 50 of the cylinder head 10. Furthermore, a sealing element, for example in the form of a packing ring, is arranged between the set screw 56 and the inner surface of the projection 50. Therefore, the transition between the cylinder head 10 and the low pressure module and the suction valve 26 is sealed to the outside.

  Since the protrusion 50 of the cylinder head 10 is formed in a cylindrical shape, the low-pressure module 170 can be coupled to the cylinder head 10 at an arbitrary rotational position. Through an annular space between the protrusion 50 and the opening 174 of the flange 173, the hole 192 of the module housing 172 having the hole 64 of the protrusion 50 and the suction valve are independent of the rotational position of the low-pressure module 70. There is therefore always a bond between.

10 Cylinder head (housing part)
12 Cylinder bore 13 Cylinder bore longitudinal axis 14 Pump piston 16 Pump working chamber 26 Suction valve 27 Low pressure supply section (supply section)
50 Projection 70, 170 Low pressure module 72 Module housing 74 Pull-out part 80 Weighing device 82 Piston 83 Longitudinal axis of piston 88 Connection pipe (external hydraulic pressure connection)

Claims (8)

A housing part (10) in which a pump piston (14) defining a pump working chamber (16) in the cylinder bore (12) is movably provided in the cylinder bore (12), and the housing part (10 ) And a suction valve (26) that allows the pump working chamber (16) to be coupled to the supply section (27), and the pump working chamber (16) is provided in the supply section (27). A low-pressure module (70; 170) provided with a metering device (80) for variably adjusting the amount of transport medium supplied, said supply part (27) being at least partly coupled with a pump. ), In which the metering device (80) is arranged in the low pressure module (70), in particular a fuel high pressure pump, the housing part (10) is connected to the cylinder bore (12). A hollow cylindrical protrusion (50) that is continued, the suction valve (26) being disposed in the protrusion, and the low pressure module (70) being the hollow of the housing part (10). It is placed on a cylindrical projection (50), and the supply part extends from the metering device (80) through the hollow cylindrical projection (50) to the suction valve (26). The low-pressure module (70) has a withdrawal part (74), the protrusion (50) of the housing part (10) protrudes into the withdrawal part, the supply part, From the low pressure module (70), through the withdrawal portion (74) of the low pressure module (70), and between the withdrawal portion (74) and the protrusion (50) of the housing portion (10). port, characterized by extending the Flop.   The pump according to claim 1, characterized in that the low-pressure module (70) can be mounted on the hollow cylindrical projection (50) of the housing part (10) at any rotational position.   The metering device (80) has a piston (82) guided so as to be displaceable, and the piston allows the cross-sectional cross section in the supply section (27) to be variably adjusted. When the low pressure module (70) is placed on the protrusion (50), the longitudinal axis (83) of the piston (82) is aligned with the longitudinal axis (13) of the cylinder bore (12) of the housing part (10). The pump according to claim 1, wherein the pump is arranged so as to extend at least substantially parallel to.   When the low pressure module (70) is placed on the protrusion (50), the weighing device (80) has a longitudinal axis (83) of the piston (82) that is aligned with the cylinder bore of the housing part (10). 4. Pump according to claim 3, characterized in that it is arranged to extend at least approximately coaxially with the longitudinal axis (13) of (12).   A pump according to any one of the preceding claims, characterized in that the low-pressure module (70) has a module housing (72) made of light metal or plastic.   The low pressure module (70) is provided with only one external hydraulic connection (88), and the supply unit (27) is coupled to the low pressure module (70) via the external hydraulic connection. The pump according to any one of claims 1 to 5, characterized in that   The external hydraulic connection (88) is arranged such that its longitudinal axis extends at least substantially perpendicular to the longitudinal axis (83) of the piston (82) of the metering device (80). The pump according to claim 6, characterized in that   The supply section extends from the piston (82) of the metering device (80) to the suction valve (26) at least approximately in the direction of the longitudinal axis (83) of the piston (82). The pump according to claim 7.

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