EP2336545A1 - High-pressure fuel supply pump - Google Patents
High-pressure fuel supply pump Download PDFInfo
- Publication number
- EP2336545A1 EP2336545A1 EP10185169A EP10185169A EP2336545A1 EP 2336545 A1 EP2336545 A1 EP 2336545A1 EP 10185169 A EP10185169 A EP 10185169A EP 10185169 A EP10185169 A EP 10185169A EP 2336545 A1 EP2336545 A1 EP 2336545A1
- Authority
- EP
- European Patent Office
- Prior art keywords
- path
- fuel
- discharge
- pressure
- relief
- Prior art date
- Legal status (The legal status is an assumption and is not a legal conclusion. Google has not performed a legal analysis and makes no representation as to the accuracy of the status listed.)
- Granted
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- 239000000446 fuel Substances 0.000 title claims abstract description 232
- 230000007246 mechanism Effects 0.000 claims abstract description 113
- 238000011144 upstream manufacturing Methods 0.000 claims abstract description 16
- 238000007599 discharging Methods 0.000 claims abstract description 7
- 238000000034 method Methods 0.000 claims description 45
- 230000008569 process Effects 0.000 claims description 45
- 238000004891 communication Methods 0.000 claims description 15
- 230000033001 locomotion Effects 0.000 claims description 12
- 230000000903 blocking effect Effects 0.000 claims 2
- 230000001902 propagating effect Effects 0.000 abstract description 6
- 230000010349 pulsation Effects 0.000 description 22
- 239000002184 metal Substances 0.000 description 13
- 230000002159 abnormal effect Effects 0.000 description 11
- 238000007906 compression Methods 0.000 description 11
- 230000000712 assembly Effects 0.000 description 10
- 238000000429 assembly Methods 0.000 description 10
- 230000000694 effects Effects 0.000 description 6
- 230000006835 compression Effects 0.000 description 5
- 230000007257 malfunction Effects 0.000 description 5
- 238000003825 pressing Methods 0.000 description 5
- 238000002485 combustion reaction Methods 0.000 description 4
- 238000002347 injection Methods 0.000 description 4
- 239000007924 injection Substances 0.000 description 4
- 239000012530 fluid Substances 0.000 description 3
- 230000000644 propagated effect Effects 0.000 description 3
- 238000003466 welding Methods 0.000 description 3
- 230000003111 delayed effect Effects 0.000 description 2
- 230000013011 mating Effects 0.000 description 2
- 230000000630 rising effect Effects 0.000 description 2
- 238000007789 sealing Methods 0.000 description 2
- 230000001052 transient effect Effects 0.000 description 2
- 230000008859 change Effects 0.000 description 1
- 238000005520 cutting process Methods 0.000 description 1
- 230000007423 decrease Effects 0.000 description 1
- 230000003628 erosive effect Effects 0.000 description 1
- 239000002828 fuel tank Substances 0.000 description 1
- 239000011261 inert gas Substances 0.000 description 1
- 239000000314 lubricant Substances 0.000 description 1
- 230000001050 lubricating effect Effects 0.000 description 1
- 238000003754 machining Methods 0.000 description 1
- 235000012054 meals Nutrition 0.000 description 1
- 238000012986 modification Methods 0.000 description 1
- 230000004048 modification Effects 0.000 description 1
- 239000010705 motor oil Substances 0.000 description 1
- 230000002093 peripheral effect Effects 0.000 description 1
- 230000004044 response Effects 0.000 description 1
Images
Classifications
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- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F02—COMBUSTION ENGINES; HOT-GAS OR COMBUSTION-PRODUCT ENGINE PLANTS
- F02M—SUPPLYING COMBUSTION ENGINES IN GENERAL WITH COMBUSTIBLE MIXTURES OR CONSTITUENTS THEREOF
- F02M63/00—Other fuel-injection apparatus having pertinent characteristics not provided for in groups F02M39/00 - F02M57/00 or F02M67/00; Details, component parts, or accessories of fuel-injection apparatus, not provided for in, or of interest apart from, the apparatus of groups F02M39/00 - F02M61/00 or F02M67/00; Combination of fuel pump with other devices, e.g. lubricating oil pump
- F02M63/02—Fuel-injection apparatus having several injectors fed by a common pumping element, or having several pumping elements feeding a common injector; Fuel-injection apparatus having provisions for cutting-out pumps, pumping elements, or injectors; Fuel-injection apparatus having provisions for variably interconnecting pumping elements and injectors alternatively
- F02M63/0225—Fuel-injection apparatus having a common rail feeding several injectors ; Means for varying pressure in common rails; Pumps feeding common rails
- F02M63/023—Means for varying pressure in common rails
- F02M63/0235—Means for varying pressure in common rails by bleeding fuel pressure
- F02M63/0245—Means for varying pressure in common rails by bleeding fuel pressure between the high pressure pump and the common rail
-
- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F02—COMBUSTION ENGINES; HOT-GAS OR COMBUSTION-PRODUCT ENGINE PLANTS
- F02M—SUPPLYING COMBUSTION ENGINES IN GENERAL WITH COMBUSTIBLE MIXTURES OR CONSTITUENTS THEREOF
- F02M55/00—Fuel-injection apparatus characterised by their fuel conduits or their venting means; Arrangements of conduits between fuel tank and pump F02M37/00
- F02M55/04—Means for damping vibrations or pressure fluctuations in injection pump inlets or outlets
-
- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F02—COMBUSTION ENGINES; HOT-GAS OR COMBUSTION-PRODUCT ENGINE PLANTS
- F02M—SUPPLYING COMBUSTION ENGINES IN GENERAL WITH COMBUSTIBLE MIXTURES OR CONSTITUENTS THEREOF
- F02M59/00—Pumps specially adapted for fuel-injection and not provided for in groups F02M39/00 -F02M57/00, e.g. rotary cylinder-block type of pumps
- F02M59/20—Varying fuel delivery in quantity or timing
- F02M59/36—Varying fuel delivery in quantity or timing by variably-timed valves controlling fuel passages to pumping elements or overflow passages
- F02M59/366—Valves being actuated electrically
- F02M59/367—Pump inlet valves of the check valve type being open when actuated
-
- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F02—COMBUSTION ENGINES; HOT-GAS OR COMBUSTION-PRODUCT ENGINE PLANTS
- F02M—SUPPLYING COMBUSTION ENGINES IN GENERAL WITH COMBUSTIBLE MIXTURES OR CONSTITUENTS THEREOF
- F02M59/00—Pumps specially adapted for fuel-injection and not provided for in groups F02M39/00 -F02M57/00, e.g. rotary cylinder-block type of pumps
- F02M59/44—Details, components parts, or accessories not provided for in, or of interest apart from, the apparatus of groups F02M59/02 - F02M59/42; Pumps having transducers, e.g. to measure displacement of pump rack or piston
- F02M59/46—Valves
- F02M59/462—Delivery valves
-
- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F02—COMBUSTION ENGINES; HOT-GAS OR COMBUSTION-PRODUCT ENGINE PLANTS
- F02M—SUPPLYING COMBUSTION ENGINES IN GENERAL WITH COMBUSTIBLE MIXTURES OR CONSTITUENTS THEREOF
- F02M63/00—Other fuel-injection apparatus having pertinent characteristics not provided for in groups F02M39/00 - F02M57/00 or F02M67/00; Details, component parts, or accessories of fuel-injection apparatus, not provided for in, or of interest apart from, the apparatus of groups F02M39/00 - F02M61/00 or F02M67/00; Combination of fuel pump with other devices, e.g. lubricating oil pump
- F02M63/0012—Valves
- F02M63/0031—Valves characterized by the type of valves, e.g. special valve member details, valve seat details, valve housing details
- F02M63/005—Pressure relief valves
-
- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F02—COMBUSTION ENGINES; HOT-GAS OR COMBUSTION-PRODUCT ENGINE PLANTS
- F02M—SUPPLYING COMBUSTION ENGINES IN GENERAL WITH COMBUSTIBLE MIXTURES OR CONSTITUENTS THEREOF
- F02M63/00—Other fuel-injection apparatus having pertinent characteristics not provided for in groups F02M39/00 - F02M57/00 or F02M67/00; Details, component parts, or accessories of fuel-injection apparatus, not provided for in, or of interest apart from, the apparatus of groups F02M39/00 - F02M61/00 or F02M67/00; Combination of fuel pump with other devices, e.g. lubricating oil pump
- F02M63/0012—Valves
- F02M63/0031—Valves characterized by the type of valves, e.g. special valve member details, valve seat details, valve housing details
- F02M63/0054—Check valves
-
- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F02—COMBUSTION ENGINES; HOT-GAS OR COMBUSTION-PRODUCT ENGINE PLANTS
- F02M—SUPPLYING COMBUSTION ENGINES IN GENERAL WITH COMBUSTIBLE MIXTURES OR CONSTITUENTS THEREOF
- F02M63/00—Other fuel-injection apparatus having pertinent characteristics not provided for in groups F02M39/00 - F02M57/00 or F02M67/00; Details, component parts, or accessories of fuel-injection apparatus, not provided for in, or of interest apart from, the apparatus of groups F02M39/00 - F02M61/00 or F02M67/00; Combination of fuel pump with other devices, e.g. lubricating oil pump
- F02M63/0012—Valves
- F02M63/0031—Valves characterized by the type of valves, e.g. special valve member details, valve seat details, valve housing details
- F02M63/0056—Throttling valves, e.g. having variable opening positions throttling the flow
-
- F—MECHANICAL ENGINEERING; LIGHTING; HEATING; WEAPONS; BLASTING
- F02—COMBUSTION ENGINES; HOT-GAS OR COMBUSTION-PRODUCT ENGINE PLANTS
- F02M—SUPPLYING COMBUSTION ENGINES IN GENERAL WITH COMBUSTIBLE MIXTURES OR CONSTITUENTS THEREOF
- F02M59/00—Pumps specially adapted for fuel-injection and not provided for in groups F02M39/00 -F02M57/00, e.g. rotary cylinder-block type of pumps
- F02M59/20—Varying fuel delivery in quantity or timing
- F02M59/36—Varying fuel delivery in quantity or timing by variably-timed valves controlling fuel passages to pumping elements or overflow passages
- F02M59/366—Valves being actuated electrically
Definitions
- the present invention relates to a high-pressure fuel supply pump used to pressurize fuel supplied from a feed pump and then supply the pressurized fuel to a fuel injection valve and, more particularly, to a high-pressure fuel supply pump used in cylinder direct fuel injection type of internal combustion engine.
- the present invention relates to a high-pressure fuel supply pump in which a relief valve mechanism is incorporated in a pump housing as a safety valve to eliminate an excessive pressure rise of the fuel in a fuel path on a high pressure side.
- a fuel relief path is provided in the pump housing in the high-pressure fuel supply pump, the fuel relief path connecting a high-pressure fuel path downstream of an discharge valve (outlet valve) to a low-pressure fuel path upstream of an inlet valve, and a check valve is provided in the fuel relief path as a relief valve that passes fuel only from the high-pressure fuel path to the low-pressure fuel path, as disclosed in Japanese Patent Application Laid-open Publication No. 2003-343395 .
- the relief valve structured as the check valve opens and part of the high-pressure fuel is released to the low-pressure path, eliminating the excessively high pressure.
- a high-pressure fuel supply pump structured as described above causes a state in which the pressure of the fuel to be discharged exceeds a pressure to open the relief valve in momentary in a transient state in which the discharge valve is opened and the fuel is being pressurized by the high-pressure fuel pump.
- This momentary high-pressure state is not abnormal as a system state, so the relief valve does not need to operate; if anything, it is not desired for the relief valve to operate.
- the present invention addresses this problem with the object of preventing the relief valve from opening even when the pressure of the fuel to be discharged is raised in momentary in the transient state in which the discharge valve is opened and the fuel is being pressurized by the high-pressure fuel pump.
- the above object is achieved by providing, in an discharge path disposed upstream of the relief valve in a relief path (that is, on the discharge valve side), a mechanism that prevents a momentary pressure rise caused in the discharge path from being transmitted to the relief valve.
- the above object is achieved by providing, in the relief path, an energy attenuating mechanism that prevents energy acting on the relief valve on the basis of a pressure rise caused in a short period on the discharge path side while the high-pressure fuel supply pump is performing a valve open operation.
- the energy attenuating mechanism can be structured with a plate that is disposed near the relief valve on the high-pressure path side (a discharge port side) and has at least one orifice.
- the energy attenuating mechanism can be structured with a discharge valve in an open state that narrows or shuts down a fuel relief path near upstream of the relief valve.
- a high-pressure fuel supply pump which has a high compression ratio, that is, a high energy coefficient with the effect that when an excessive (abnormal) high-pressure is generated due to a fuel injection valve failure or the like, The fuel pressurerized to the excessiv (abnormal) high-pressure is released through the relief valve and high-pressure side piping and other high-pressure side devices are not damaged by the excessive (abnormal) high-pressure.
- the fuel released through the relief valve can be expelled not only to the low-pressure path but also to a pressurizing chamber.
- FIG. 1 A first embodiment of the present invention will be specifically described with reference to FIGs. 1 to 3 .
- the structure and operation of a system will be described with reference to the entire system structure shown in FIG. 3 .
- a section enclosed by broken lines is a pump housing 1 of the high-pressure fuel supply pump.
- the mechanisms and parts within the broken lines are included in the pump housing 1 in an integrated manner.
- Fuel in a fuel tank 20 is drawn up by a feed pump 21 and delivered to an inlet port 10a in the pump housing 1 through an inlet pipe 28. Fuel drawn into the pump housing 1 is adjusted to a constant pressure by a pressure regulator 22.
- the fuel which has passed through the inlet port 10a, further passes through a pressure pulsation reducing mechanism 9 and inlet paths 10c and 10d, and then reaches an inlet port 30a in an electromagnetic inlet valve mechanism 30.
- the pressure pulsation reducing mechanism 9 will be described in detail later.
- the electromagnetic inlet valve mechanism 30 has an electromagnetic coil 30b; while the electromagnetic coil 30b is energized, an electromagnetic plunger 30c is shifted to the right side in FIG. 3 and a spring 33 is kept compressed.
- An inlet valve body 31 attached to an end of the electromagnetic plunger 30c then opens an inlet port 32 that communicates with a pressurizing chamber 11 of the high-pressure pump.
- the inlet valve body 31 When the electromagnetic coil 30b is not energized and there is no difference in fluid pressure between the inlet path 10d (inlet port 30a) and the pressurizing chamber 11, the inlet valve body 31 is biased by a bias force of the spring 33 in the closing direction, keeping the inlet port 32 closed.
- the inlet valve body 31 is set so that when the valve opening force due to the differential fluid pressure becomes stronger than the bias force of the spring 33, the inlet valve body 31 opens and thus the inlet port 32 opens.
- ECU engine control unit
- the volume of the pressurizing chamber 11 decreases as the plunger 2 is raised. In this state, however, the fuel intaked into the pressurizing chamber 11 is spilled to the inlet path 10d (inlet port 30a) through the inlet valve body 31 in the open state, so the pressure in the pressurizing chamber is not increased. This process is called a spill process.
- the fuel remaining in the pressurizing chamber 11 is pressurized and the fuel pressure in the pressurizing chamber 11 becomes equal to or more than the pressure at an discharge port 12, the fuel is discharged into a high-pressure pipe 29 through a discharge valve mechanism 8 and the discharge port 12, and then supplied to a common rail 23.
- This process is called a discharge process. That is, the compression process (a rising process from the bottom dead center to the top dead center) of the plunger 2 comprises the spill process and the discharge process.
- the amount of high-pressure fuel to be discharged can be controlled by controlling a timing at which the electromagnetic coil 30b in the electromagnetic inlet valve mechanism 30 is deenergized.
- the electromagnetic coil 30b is deenergized early, the ratio of the spill process in the compression process is small and the ratio of the discharge process in the compression process is large.
- the above structure enables a timing to deenergize the electromagnetic coil 30b to be controlled, and the amount of fuel to be highly pressurized and discharged can be thus controlled to an amount required by the internal combustion engine.
- Injectors 24 and a pressure sensor 26 are mounted on the common rail 23; the number of injectors 24 mounted matches the number of cylinders in the internal combustion engine.
- the injectors 24 inject fuel into the cylinders by being opened and closed by control signals from the ECU 27.
- the pump housing 1 further includes relief paths 210 and 215 for enabling the downstream side of the discharge valve 8b to communicate with the inlet path 10c.
- a relief valve 202 is provided to restrict the fuel flow only to one way from the discharge (outlet) path 12b to the inlet path 10c.
- the concrete structure will be described with reference to FIG. 2 .
- a relief valve mechanism 200 comprises a relief valve seat 201, a relief valve 202, a relief retainer 203, a relief spring 204, and a relief spring adjuster 205.
- the relief valve seat 201 is press-fitted into the pump housing 1 and fixed.
- An orifice plate 214 is fixed between the pump housing 1 and the relief valve seat 201.
- the relief valve 202 is seated against the relief valve seat 201 by a pressing force generated by the relief spring 204, the pressing force being transmitted through the relief retainer 203.
- the force to open the relief valve 202 is determined by the pressing force generated by the relief spring 204, and the pressing force is determined by engaging threads formed on the outer periphery of the relief spring adjuster 205 into threads formed on the pump housing 1 and adjusting an amount by which the relief spring 204 is compressed.
- An O-ring 213 prevents the fuel from leaking to the outside.
- the relief valve 202 is pressed against the relief valve seat 201 by the relief spring 204, which generates the pressing force.
- the relief valve 202 is released from the relief valve seat 201, opening the relief valve 202.
- the orifice plate 214 is disposed at some midpoint in the relief path 210; the relief valve 202 is adapted so that it does not open sensitively in response to a rapid pressure change in the relief path 210.
- the discharge valve mechanism 8 and electromagnetic inlet valve mechanism 30 are disposed coaxially in series with the pressurizing chamber 11 positioned therebetween.
- the relief valve mechanism 200 is incorporated into relief valve mounting holes formed in the pump housing in parallel to mounting axis lines for the discharge valve mechanism 8 and electromagnetic inlet valve mechanism 30.
- a concave 1A is formed as the pressurizing chamber 11 at the center of the pump housing 1.
- Another concave 11A is formed for mounting the discharge valve mechanism 8 between the discharge port 12 and the inner peripheral wall of the pressurizing chamber 11.
- holes 30A are formed coaxially with the concave 11A for mounting the discharge valve mechanism, which supplies fuel to the pressurizing chamber 11, the hole 30A being used to mount the electromagnetic inlet valve mechanism 30.
- the axis lines of the concave 11A for mounting the discharge valve mechanism 8 and the hole 30A for attaching the electromagnetic inlet valve mechanism 30 are formed so that they are orthogonal to the central axis line of the concave 1A formed as the pressurizing chamber 11.
- the discharge valve mechanism 8 for discharging fuel from the pressurizing chamber 11 to the discharge path is disposed.
- a cylinder 6 for guiding the reciprocating motion of the plunger 2 is attached in a way that it extends to the pressurizing chamber 11.
- the concave 11A for mounting the discharge valve mechanism 8 and the hole 30A for attaching the electromagnetic inlet valve mechanism 30 are formed so that their axis lines are aligned. Accordingly, straight assembling is possible from the hole 30A for attaching the electromagnetic inlet valve mechanism 30 to the concave 11A for mounting the discharge valve mechanism 8. Alternatively, a force to press-fit the discharge valve mechanism 8 can be applied from the hole 30A for attaching the electromagnetic inlet valve mechanism 30. In this case, the smallest diameter of the hole 30A must be greater than the maximum outer diameter of the discharge valve mechanism 8.
- the discharge valve mechanism 8 needs to be assembled from an opening 1B formed for attaching the cylinder 6.
- the outer periphery of the cylinder 6 is held by a cylinder holder 7, and fixed to the pump housing 1 because the males threads formed on the outer periphery of the cylinder holder 7 are screwed into the female threads formed on the pump housing 1.
- the cylinder 6 slidably holds the plunger 2, which reciprocates in the pressurizing chamber 11, along the reciprocating motion.
- the cylinder 6 is mounted in the opening 1B for mounting the cylinder 6 after the discharge valve mechanism 8 is mounted in the concave 11A.
- An end of the cylinder 6 can be thus inserted up to a position at which the end faces the internal end of the discharge valve mechanism 8 mounted in the concave 11A. Accordingly, the volume to accommodate fuel in the pressurizing chamber 11 can be made small, increasing the fuel compression efficiency.
- a meal seal part is formed on a mating surface S1 between a flange-like annular surface part formed on the outer periphery of the cylinder 6 and the end surface of the opening 1B in the pump housing 1 so as to isolate the pressurizing chamber 11 from the ambient atmosphere.
- the mating surface S1 erodes due to cavitation generated by variations in pressure in the pressurizing chamber 11.
- the cylinder 6 is adapted to extend into the pressurizing chamber and thus the matching surface S1 for sealing can be positioned away from the generated cavitation, the possibility of erosion can be reduced.
- an arrangement for preventing the discharge valve mechanism 8 from coming off is achieved by press-fitting a cylindrical member 11D into the internal periphery at the bottom (the upper end in FIG. 1 ) of the concave 1A after the discharge valve mechanism 8 is mounted.
- the cylindrical member 11D also has a function for increasing the fuel compression efficiency by reducing the volume of the pressurizing chamber 11.
- the cylinder 6 can be used to prevent the discharge valve mechanism 8 from coming off.
- the cylinder 6 does not need to be used as a retainer to prevent the discharge valve mechanism 8 from coming off.
- the cylinder 6 can be thus structured so that it does not reach the position of the discharge valve mechanism 8 by being shortened.
- the discharge valve mechanism 8 After the discharge valve mechanism 8 is press-fitted into the concave 11A, the discharge valve mechanism 8 itself can be used as the retainer by, for example, swaging the periphery on the pressurizing chamber 11 side to the internal wall of the pump housing. In this case, the cylindrical member 11D is not necessary.
- the cylinder 6 When the cylinder 6 is shortened so that it does not reach the position of the discharge valve mechanism 8, it is also possible to fix the cylinder 6 first and then mount the discharge valve mechanism 8 into the concave 11A.
- a tappet 3 that converts the rotational motion of a cam 5 attached to a cam shaft of the engine into vertical motion and transfers the vertical motion to the plunger 2.
- the plunger 2 is seated against the tappet 3 by a spring 4 through a retainer 15. Accordingly, the plunger 2 can advance and retract (reciprocate) as the cam 5 rotates.
- a plunger seal 13 held at the bottom of the internal periphery of the cylinder holder 7 is provided in a state in which the plunger seal 13 is slidably in contact with the outer periphery of the plunger 2 at the bottom, shown in the drawing, of the cylinder 6, preventing fuel from leaking to the outside. It is also prevented that a lubricant (possibly engine oil) for lubricating a sliding part in the engine room enters the inside of the pump housing 1.
- a lubricant possibly engine oil
- the pressure pulsation reducing mechanism 9, which reduces the propagation of pressure pulsation generated in the pump to the fuel pipe 28, is fixed to a damper cover 14.
- the damper cover 14 is fixed to the pump housing 1.
- the inlet path as the low-pressure path comprises 10a, 10b, and 10c.
- the pressure pulsation reducing mechanism 9, which reduces the propagation of pressure pulsation generated in the pump to the fuel pipe 28 as a result of the reciprocating motion of the plunger 2, comprises two metal diaphragm assemblies 9A and 9B.
- the pump housing 1 includes a damper housing 10B, which is part of the inlet paths.
- the two metal diaphragm assemblies 9A and 9B are accommodated in the damper housing 10B.
- Supporting members 10A1 and 10A2 are provided on the periphery so that the two metal diaphragm assemblies 9A and 9B are disposed with a particular interval therebetween.
- the threads formed on the outer periphery of the damper cover 14 are screwed into the thread grooves 10C formed on the inner periphery of the damper housing 10B, and a seal member 10D is pressed so as to provide a seal, making the damper chamber hermetic. Accordingly, the damper chamber is defined in the inlet path 10, and the pressure pulsation reducing mechanism 9 is formed.
- Intaked fuel is also guided between the damper cover 14 and the metal diaphragm assembly 9A and between the metal diaphragm assemblies 9A and 9B through an inlet path 10E, basically causing the same pressure to act on the four diaphragms.
- damper cover 14 is fixed to the pump housing by being screwed in this embodiment, the damper cover 14 can also be fixed by, for example, welding the entire periphery at the P position. In this case, a seal is also provided by the welding, so the seal member 10D in the first embodiment can be eliminated.
- the discharge port (pipe connection part on the discharge side) 12 is formed in the pump housing 1.
- the pressurizing chamber 11 for pressurizing fuel is formed at some point on the fuel path from the inlet port 10a to the discharge port 12.
- the electromagnetic inlet valve mechanism 30 is formed at the entrance of the pressurizing chamber 11.
- the inlet valve spring 33 disposed in the electromagnetic inlet valve mechanism 30 generates a biased force in the direction to close the inlet port; the biased force is applied to the inlet valve body 31.
- the electromagnetic inlet valve mechanism 30 thus functions as the check valve for limiting the direction in which the fuel flows.
- the discharge valve mechanism 8 is provided at the exit of the pressurizing chamber 11.
- the discharge valve mechanism 8 comprises a seat member 8a, an discharge valve 8b, an discharge valve spring 8c, a holding member 8d used as an discharge valve stopper.
- the discharge valve 8b When there is no differential pressure between the pressurizing chamber 11 and the discharge port 12, the discharge valve 8b is seated against the seat member 8a by the biased force of the discharge valve spring 8c and thus placed in the closed state. Only when the fuel pressure in the pressurizing chamber 11 is higher than the fuel pressure at the discharge port 12 by a predetermined value, the discharge valve 8b opens against the discharge valve spring 8c, discharging the fuel in the pressurizing chamber 11 to the common rail 23 through the discharge port 12.
- the discharge valve 8b After being opened, the discharge valve 8b comes into contact with the holding member 8d and its operation is restricted. Accordingly, the stroke of the discharge valve 8b is appropriately determined by the holding member 8d. If the stroke is too large, the closing of the discharge valve 8b is delayed and the fuel discharged to the discharge port 12 spills to the pressurizing chamber 11, lowering the efficiency of the high pressure pump. While the discharge valve 8b repeats valve opening and closing motions, the holding member 8d guides the discharge valve 8b so that the discharge valve 8b moves only in the stroke direction. This arrangement enables the discharge valve mechanism 8 to function as the check valve for limiting the fuel flow direction.
- pressure pulsation is generated in the inlet path 10 by the fuel returned (spilled) to the inlet path 10d.
- the pressure pulsation is absorbed and reduced when the metal diaphragm assemblies 9A and 9B expand and contract. Only a small amount of fuel is returned (spilled) from the inlet port 10a through the inlet pipe 28 during the spill process. Most of the amount of fuel is absorbed by changes in volumes of the metal diaphragm assemblies 9A and 9B.
- the relief path 215 is connected to the inlet path 10c as shown again in FIG. 2 . Accordingly, the exit of the relief valve 202 is connected between the pressure pulsation reducing mechanism 9 and the inlet valve 31.
- the orifice plate 214 has one or two or more orifices as shown in FIGs. 5 and 6 .
- a pressure overshoot is generated in the pressurizing chamber 11 in a period from an instant when a shift occurs from the spill process to the pressurizing process to a time immediately after the shift.
- the pressure overshoot generated in the pressurizing chamber 11 propagates from the discharge port 12 through the relief path 210 to the orifice plate 214.
- the orifice 214a or the orifices 214b or 214c prevent the pressure overshoot that has propagated up to the orifice plate 214 from further propagating to a relief path 211, so the pressure overshoot in the relief path 211 does not exceed the pressure to open the relief valve seat 201.
- the differential pressure between the entrance and exit of the relief valve does not therefore exceed the pressure to open the relief valve, so malfunction of the relief valve is eliminated and the amount of fuel discharged under high pressure is not reduced.
- orifices (214a, 214b, 214c) of the orifice plate 214 is an attenuating mechanism that attenuates the energy of the pressure overshoot of he discharged fuel because it explained above.
- the holding member 8d used as the discharg valve stopper is fitted to the seat member 8a by being slightly press-fitted with the discharge valve 8b and discharge valve spring 8c disposed, and assembled to the pump housing 1 as the discharge valve mechanism 8 by being press-fitted from the pressurizing chamber 11 side.
- the ease of assembling can be improved.
- the relief valve can be easily incorporated in the pump.
- a stopper part of the discharge valve mechanism 8 is provided in the pump housing 1; the cylinder 6 disposed in the pressurizing chamber 11 has a part for preventing the seat member 8a from coming off; a clearance smaller than a length by which the seat member 8a is press-fitted to the pump housing 1 is provided between the seat member 8a and the cylinder 6.
- the seat member does not come off, so the press-fitting force (the difference) does not need to be large. This prevents the seat part from being deformed during press-fitting and thus prevents the valve seat capability from being lowered. Accordingly, tolerance ranges for press-fitting forces (the differences) can be roughly managed, making inexpensive machining possible.
- the inner diameter of the discharge port 12 into which a joint for piping on the discharging side is screwed can also be made equal to or smaller than the outer diameter of the seat member 8a having the largest outer diameter in the discharge valve mechanism 8. Accordingly, it is also possible to reduce the area of the sealed part between the discharge port and the joint and thereby to reduce the area of the sealed part at which a pressure is received.
- the outer periphery of the cylinder 6 is held by the cylinder holder 7.
- the cylinder holder 7 obtains a thrust, fixing the cylinder 6 to pump housing 1.
- the cylinder 6 holds the plunger 2, which is the pressurizing member, while allowing the plunger 2 to slide upward and downward.
- the high-pressure fuel supply pump is fixed to the engine through the flange holder 40 and flange 41.
- the flange holder 40 is pressed against and fixed to the engine with setscrews 42 through the flange 41. Since the flange holder 40 is fixed to the pump housing 1 by the threads formed on the inner periphery, the pump housing is thus fixed to the engine.
- the relief path 215 is connected through the inlet path 10c to the inlet path 10b in which the pressure pulsation reducing mechanism 9 is disposed.
- the exit of the relief valve 202 is thus connected between the pressure pulsation reducing mechanism 9 and the inlet valve 31.
- the orifice plate 214 has one or two or more orifices.
- FIGs. 5 and 6 show examples of the orifice plate 214.
- the example in FIG. 5 has one orifice 214a; one example in FIG. 6 has four orifices 214b, and the other example has many orifices 214c.
- each of the orifices is adapted to have a such a small diameter that the viscosity of the fuel to causes an effect.
- the function of the orifice will be described below.
- a pressure overshoot is generated in the pressurizing chamber 11.
- the pressure overshoot generated in the pressurizing chamber 11 propagates from the discharge port 12 through the relief path 210 to the orifice plate 214.
- the orifice 214a (214b or 214c) as an energy attenuating mechanism prevents the pressure overshoot that has propagated up to the orifice plate 214 from further propagating to the relief path 211, so the pressure overshoot in the relief path 211 can be reduced. Accordingly, malfunction of the relief valve is eliminated and a drop in the amount of fuel discharged under high pressure can also be reduced. That is, the efficiency as the high-pressure fuel supply pump can be maintained at a high level.
- orifices (214a, 214b, 214c) of the orifice plate 214 is an attenuating mechanism that attenuates the energy of the pressure overshoot of he discharged fuel because it explained above.
- the pressure overshoot generated in the pressurizing chamber 11 also propagates from the discharge port 12 through the high-pressure pipe 29 to the common rail 23.
- An orifice 25 provided at the entrance of the common rail 23 blocks the propagation of the pressure overshoot to the common rail 23, achieving fuel supply to the injector 24 under stable pressure.
- FIG. 7 indicates the relation between the amount of fuel discharged under high pressure from the high-pressure fuel supply pump and the pressure in the common rail 23.
- the fuel pressure in the common rail 23 always increases even when the pressure to open the relief valve 202 is the same.
- the malfunction of the relief valve 202 due to the pressure overshoot propagated from compression chamber 11 to the relief path 210 as described above can be reduced.
- the orifice 214a must be very small. If an excessively high pressure is generated, the high-pressure fuel passes through the orifice 214a and is spilled through the relief path 215 to the inlet path 10b. However, a pressure drop is generated at the orifice 214a. As a result, the fuel pressure in the common rail 23 or the like is much higher than the pressure to open the relief valve 202, which is problematic in terms of the durability of the high-pressure part and costs.
- the pressure pulsation reducing mechanism 9 disposed in the inlet path 10b can sufficiently reduce this pressure pulsation, preventing the pressure pulsation from propagating to the low-pressure pipe 28 and thereby preventing the pipe from being broken.
- the exit of the relief path is connected to the inlet (low-pressure) path.
- the relief valve can be disposed at a position near the pressurizing chamber, preferably in the pressurizing chamber. If only the compression efficiency is not lowered, the exit of the relief path can be connected to the pressurizing chamber so as to spill the fuel to the pressurizing chamber at the occurrence of an excessively high pressure.
- FIG. 1 A second embodiment of the present invention will be described with reference to FIG. 1 and FIGs. 8 to 18 .
- the relief valve mechanism B200 comprises a relief valve housing B206, which is integrally formed with a relief valve seat B201, as well as a relief valve B202, a relief valve retainer B203, a relief spring B204, and a relief valve adjuster B205.
- the relief valve mechanism B200 is assembled as a sub-assembly outside the pump housing 1, and then fixed to the pump housing 1 by being press-fitted.
- the relief valve B202, relief valve retainer B203, and relief spring B204 are inserted in succession into a relief valve housing B206 in that order.
- the relief spring adjuster B205 is then fixed to the relief valve housing B206 by being press-fitted.
- a load set by the relief spring B204 is determined.
- a pressure to open the relief valve B202 is determined by the load set by the relief spring B204.
- the relief valve mechanism B200 structured in this way is fixed to the pump housing 1 by being press-fitted.
- the relief path 211 is integrally formed to the pump housing 1, in parallel to the cylinder 6.
- the discharge valve mechanism 8 is disposed at the exit of the pressurizing chamber 11.
- the discharge valve mechanism 8 comprises an discharge valve seat 8a, an discharge valve 8b, an discharge valve spring 8c, and an discharge valve holder 8d.
- the discharge valve 8b is slidably held by the discharge valve holder 8d, and guided by the discharge valve holder 8d so that the discharge valve 8b moves only in the stroke direction when the discharge valve 8b repeats open and close motions.
- the discharge valve 8b opens and comes into contact with a contact part 8d3 of the discharge valve holder 8d, the operation of the discharge valve 8b is restricted. Accordingly, it is prevented that fuel discharged to the discharge port 12 under high pressure is spilled to the pressurizing chamber 11 due to a delay of the discharge valve 8b being closed and thus the efficiency as a high pump is lowered.
- Discharge ports 8dl, relief ports 8d2, and a spill port 8d4 are formed in the discharge valve holder 8d.
- the relief ports 8d2 communicate with the relief path 211.
- the discharge valve 8b While the high-pressure fuel supply pump is in the discharge process, the discharge valve 8b is in the open state as shown in FIG. 12 .
- the discharge valve 8b comes in contact with the discharge valve holder 8d at the contact part 8d3, at which fuel is sealed, so the discharge path 12b is blocked from the relief path 211 and thus communication therebetween is disabled.
- the discharge valve 8b While the high-pressure fuel supply pump is in the intake and spill processes, the discharge valve 8b is in the closed state as shown in FIG. 13 .
- the discharge valve 8b blocks the discharge path 12b from the pressurizing chamber 11 at a seat part 8a3 on the discharge valve seat 8a. Accordingly, even when the pressure in the pressurizing chamber 11 is reduced due the motion of the plunger 2, the fuel under high pressure in the discharge path 12b does not spill to the pressurizing chamber 11.
- a clearance is formed between the discharge valve 8b and the discharge valve holder 8d at the contact part 8d3 by the amount equal to the stroke of the discharge valve 8b.
- the discharge port 12 communicates with the relief path 211 through this clearance. That is, while in the discharge process, there is no communication between the discharge path 12b and the relief path 211; while in the intake and spill processes, there is communication between the discharge port 12 and the relief path 211.
- the fuel highly pressurized in the pressurizing chamber 11 is supplied from the discharge port 12 through the high-pressure pipe 29 to the common rail 23, as shown in FIG. 12 .
- a pressure overshoot is generated in the pressurizing chamber 11 at this time.
- the pressure overshoot generated in pressurizing chamber 11 propagates to the discharge port 12, but the discharge valve 8b is in the open state. That is, there is no communication between the discharge port 12 and relief path 211 as described above, so the pressure overshoot does not propagate to the relief path 211.
- contact part 8d3 for sealing fuel is the path switching mechanism that makesa switchover to enable or disable communication between the relief path and the discharge path because it explained above.
- the fuel under excessively (abnormal) high pressure flows from the discharge path 12b through the relief path 211, and reaches the relief valve B202.
- the fuel that passes through the relief valve B202 further passes through a relief path B205a formed in the relief spring adjuster B205, and is released to the inlet path 10b, which is a low-pressure part.
- the high-pressure parts such as the common rail 23 are thus protected.
- the pressure pulsation reducing mechanism 9 disposed further upstream in the inlet path 10b can sufficiently reduce this pressure pulsation, preventing the pressure pulsation from propagating to the low-pressure pipe 28 and thereby preventing the pipe from being broken.
- the discharge valve mechanism 8 is assembled outside the pump housing 1 as a sub-assembly before being incorporated into the pump housing 1.
- the discharge valve spring 8c, discharge valve 8b, and discharge valve seat 8a are inserted in succession into the discharge valve holder 8d in that order.
- the discharge valve seat 8a is then fixed to the discharge valve holder 8d at a press-fitted part 8a1 by being press-fitted.
- the discharge valve mechanism 8 structured in this way is fixed to the pump housing by being press-fitted. Places in which press-fitting is performed are a press-fitted part 8a2, which is a side part of the discharge valve seat 8a, and press-fitted parts 8d5, which are sides of the discharge valve holder 8d. Other sides of the discharge valve holder 8d have a shape formed by cutting two planes 8d6 parallel on its cylindrical shape. That is, the sides of the discharge valve holder 8d comprise the press-fitted parts 8d5, which are cylindrical, and the planes 8d6.
- the two discharge ports 8d1 are machined so that connection to the two planes 8d6 is established.
- the two relief parts 8d2 are machined so that connection to the cylindrical press-fitted parts 8d5 is established.
- the discharge valve mechanism 8 is press-fitted to the pump housing 1, the relief ports 8d2 machined in the discharge valve holder 8d overlap the relief path 211 machined in the pump housing 1.
- the press-fitted part of the pump housing is machined in a cylindrical shape.
- the fuel pressurized in the pressurizing chamber 11 is delivered from the discharge ports 8d1, flows along the planes 8d6 machined on the sides of the discharge valve holder 8d, and are discharged to the discharge path 12b through the clearance in the pump housing 1, as shown in FIGs. 15 and 17 .
- the relief path 211 is blocked from the discharge path 12b by the contact part 8d3 on the discharge valve holder 8d, so there is no communication therebetween. Accordingly, the pressure overshoot generated in the pressurizing chamber 11 does not propagate to the relief valve B202.
- a clearance is formed at the contact part 8d3 between the discharge valve 8b and the discharge valve holder 8d by the amount equal to the stroke of the discharge valve 8b, as shown in FIGs. 16 and 18 .
- This clearance is used for the discharge port 12 to communicate with the relief path 211 through the communicating port 8d4 and relief ports 8d2 formed in the discharge valve holder 8d.
- the fuel under excessively (abnormal) high pressure can reach the relief valve B202, passes through a relief path B205a formed in the relief spring adjuster B205, and is released to the inlet path 10b, which is a low-pressure part.
- the discharge valve mechanism 8 assembled outside the pump housing 1 is press-fitted to the pump housing 1 at the press-fitted parts 8d5 of the discharge valve holder 8d and an discharge valve seat 8a3.
- the press-fitted part between 8d5 and the pump housing 1 is structured so that the press-fitted part serves as a blockade between the discharge path 12b and the relief path 211.
- the clearance between the press-fitted parts 8d5 and the pump housing 1 may be such a minute clearance that the viscosity of the fuel causes an effect. Accordingly, the same effect as described above is obtained, and the load to press-fit the discharge valve mechanism 8 to the pump housing 1 can be reduced, improving the ease of assembling the high-pressure fuel supply pump.
- the present invention is applied to high-pressure fuel supply pumps used in cylinder injection types of internal combustion engines.
- High-pressure fuel supply pumps having only one pressurizing chamber that is, so-called single-cylinder types of high-pressure fuel supply pumps have been described in the embodiments, but the present invention can also be used far high-pressure fuel supply pumps having a plurality of pressurizing chamber, that is, so-called multicylinder types of high-pressure fuel supply pumps.
- high-pressure fuel supply pumps according to one or more of the following clauses:
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Abstract
Description
- The present invention relates to a high-pressure fuel supply pump used to pressurize fuel supplied from a feed pump and then supply the pressurized fuel to a fuel injection valve and, more particularly, to a high-pressure fuel supply pump used in cylinder direct fuel injection type of internal combustion engine.
- More particularly, the present invention relates to a high-pressure fuel supply pump in which a relief valve mechanism is incorporated in a pump housing as a safety valve to eliminate an excessive pressure rise of the fuel in a fuel path on a high pressure side.
- In conventional high-pressure fuel supply pumps of this type, a fuel relief path is provided in the pump housing in the high-pressure fuel supply pump, the fuel relief path connecting a high-pressure fuel path downstream of an discharge valve (outlet valve) to a low-pressure fuel path upstream of an inlet valve, and a check valve is provided in the fuel relief path as a relief valve that passes fuel only from the high-pressure fuel path to the low-pressure fuel path, as disclosed in Japanese Patent Application Laid-open Publication No.
2003-343395 - If the pressure in the high-pressure fuel discharge path is excessively raised, the relief valve structured as the check valve opens and part of the high-pressure fuel is released to the low-pressure path, eliminating the excessively high pressure.
- Patent Document 1: Japanese Patent Application Laid-open Publication No.
2003-343395 - However, a high-pressure fuel supply pump structured as described above causes a state in which the pressure of the fuel to be discharged exceeds a pressure to open the relief valve in momentary in a transient state in which the discharge valve is opened and the fuel is being pressurized by the high-pressure fuel pump.
- This momentary high-pressure state is not abnormal as a system state, so the relief valve does not need to operate; if anything, it is not desired for the relief valve to operate.
- When the relief valve opens in this situation, the amount of fuel discharged by the high-pressure fuel supply pump is reduced and the energy efficiency is lowered.
- The present invention addresses this problem with the object of preventing the relief valve from opening even when the pressure of the fuel to be discharged is raised in momentary in the transient state in which the discharge valve is opened and the fuel is being pressurized by the high-pressure fuel pump.
- The above object is achieved by providing, in an discharge path disposed upstream of the relief valve in a relief path (that is, on the discharge valve side), a mechanism that prevents a momentary pressure rise caused in the discharge path from being transmitted to the relief valve.
- Specifically, the above object is achieved by providing, in the relief path, an energy attenuating mechanism that prevents energy acting on the relief valve on the basis of a pressure rise caused in a short period on the discharge path side while the high-pressure fuel supply pump is performing a valve open operation.
- Preferably, the energy attenuating mechanism can be structured with a plate that is disposed near the relief valve on the high-pressure path side (a discharge port side) and has at least one orifice.
- Preferably, the energy attenuating mechanism can be structured with a discharge valve in an open state that narrows or shuts down a fuel relief path near upstream of the relief valve.
- According to the present invention structured as described above, a high-pressure fuel supply pump can be provided which has a high compression ratio, that is, a high energy coefficient with the effect that when an excessive (abnormal) high-pressure is generated due to a fuel injection valve failure or the like, The fuel pressurerized to the excessiv (abnormal) high-pressure is released through the relief valve and high-pressure side piping and other high-pressure side devices are not damaged by the excessive (abnormal) high-pressure.
- The fuel released through the relief valve can be expelled not only to the low-pressure path but also to a pressurizing chamber.
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FIG. 1 is the vertical cross section drawing to show an entire high-pressure fuel supply pump in first and second embodiments of the present invention. -
FIG. 2 is the horizontal cross section drawing to show an entire high-pressure fuel supply pump in the first embodiment of the present invention. -
FIG. 3 is the drawing to show a fuel supply system which uses the high-pressure fuel supply pump in the first embodiment of the present invention. -
FIG. 4 is the drawing to show pressure waveforms in individual parts and a common rail in the high-pressure fuel supply pump in the first and second embodiments of the present invention. -
FIG. 5 is the drawing to show an orifice plate in the first embodiment of the present invention. -
FIG. 6 is the drawing to show other orifice plates in the first embodiment of the present invention. -
FIG. 7 is the drawng to show the relation between the pressure in the common rail and the amount of fuel discharged in high-pressure by the high-pressure fuel supply pump in the first embodiment of the present invention. -
FIG. 8 is the drawing to show the structure of a relief valve mechanism in the second embodiment of the present invention. -
FIG. 9 is the vertical cross section drawing to show the high-pressure fuel supply pump in the second embodiment of the present invention. -
FIG. 10 is the horizontal cross section drawing to show a high-pressure fuel supply pump in the second embodiment of the present invention. -
FIG. 11 is the drawing to show a fuel supply system which uses the high-pressure fuel supply pump in the second embodiment of the present invention. -
FIG. 12 is the schematical drawing to show the operation of an discharge valve mechanism in the high-pressure fuel supply pump in the second embodiment of the present invention, and the high-pressure fuel supply pump is in an discharge process. -
FIG. 13 is the schematic drawing to show the principle of operation of the discharge valve mechanism in the high-pressure fuel supply pump in the second embodiment of the present invention, and the high-pressure fuel supply pump is in the relief condition. -
FIG. 14 is the assembly drawing of the discharge valve mechanism in the high-pressure fuel supply pump in the second embodiment of the present invention. -
FIG. 15 is the drawing to show the structure of the discharge valve mechanism in the high-pressure fuel supply pump in the second embodiment of the present invention, and the high-pressure fuel supply pump is in the discharge process. -
FIG. 16 is the drawing to show the structure of the discharge valve mechanism in the high-pressure fuel supply pump in the second embodiment of the present invention, and the high-pressure fuel supply pump is the intake and spill processes. -
FIG. 17 is the vertical and horizontal cross section drawings to show the structure of the discharge valve mechanism in the high-pressure fuel supply pump in the second embodiment of the present invention, and the high-pressure fuel supply pump is in the discharge process. -
FIG. 18 is the vertical and horizontal cross section drawing to show the structure of the discharge valve mechanism in the high-pressure fuel supply pump in the second embodiment of the present invention, and the high-pressure fuel supply pump is the intake and spill processes. - Embodiments of the present invention will be specifically described with reference to the drawings.
- A first embodiment of the present invention will be specifically described with reference to
FIGs. 1 to 3 . First, the structure and operation of a system will be described with reference to the entire system structure shown inFIG. 3 . - A section enclosed by broken lines is a
pump housing 1 of the high-pressure fuel supply pump. The mechanisms and parts within the broken lines are included in thepump housing 1 in an integrated manner. - Fuel in a
fuel tank 20 is drawn up by afeed pump 21 and delivered to aninlet port 10a in thepump housing 1 through aninlet pipe 28. Fuel drawn into thepump housing 1 is adjusted to a constant pressure by apressure regulator 22. - The fuel, which has passed through the
inlet port 10a, further passes through a pressurepulsation reducing mechanism 9 andinlet paths inlet port 30a in an electromagneticinlet valve mechanism 30. The pressurepulsation reducing mechanism 9 will be described in detail later. - The electromagnetic
inlet valve mechanism 30 has anelectromagnetic coil 30b; while theelectromagnetic coil 30b is energized, anelectromagnetic plunger 30c is shifted to the right side inFIG. 3 and aspring 33 is kept compressed. - An
inlet valve body 31 attached to an end of theelectromagnetic plunger 30c then opens aninlet port 32 that communicates with a pressurizingchamber 11 of the high-pressure pump. - When the
electromagnetic coil 30b is not energized and there is no difference in fluid pressure between theinlet path 10d (inlet port 30a) and the pressurizingchamber 11, theinlet valve body 31 is biased by a bias force of thespring 33 in the closing direction, keeping theinlet port 32 closed. - A specific operation will be described below.
- When a
plunger 2 is displaced downward inFIG. 1 due to the rotation of a cam described later and an intake process is brought, the volume of the pressurizingchamber 11 increases and thereby the fuel pressure in the pressurizingchamber 11 lowers. When the fuel pressure in the pressurizingchamber 11 falls below the pressure in theinlet path 10d (inlet port 30a) in this process, a differential fluid pressure of the fuel causes a valve opening force (a force to displace theinlet valve body 31 to the right inFIG. 1 ) in theinlet valve body 31. - The
inlet valve body 31 is set so that when the valve opening force due to the differential fluid pressure becomes stronger than the bias force of thespring 33, theinlet valve body 31 opens and thus theinlet port 32 opens. - When, in this state, a control signal from an engine control unit (hereinafter referred to as ECU) 27 is applied to the electromagnetic
inlet valve mechanism 30, current flows in theelectromagnetic coil 30b of the electromagneticinlet valve mechanism 30 and theelectromagnetic plunger 30c is moved by the magnetic bias force to the right inFIG. 1 , keeping thespring 33 compressed. As a result, the state in which theinlet valve body 31 opens theinlet port 32 is maintained. - When the
plunger 2 completes the intake process and shifts to a compression process (theplunger 2 moves upward inFIG. 1 ) with the input voltage applied to the electromagneticinlet valve mechanism 30, the magnetic bias force is maintained because theelectromagnetic coil 30b is kept energized, so theinlet valve body 31 is kept open. - The volume of the pressurizing
chamber 11 decreases as theplunger 2 is raised. In this state, however, the fuel intaked into the pressurizingchamber 11 is spilled to theinlet path 10d (inlet port 30a) through theinlet valve body 31 in the open state, so the pressure in the pressurizing chamber is not increased. This process is called a spill process. - When, in this state, the control signal from the
ECU 27 is removed to deenergize theelectromagnetic coil 30b, the magnetic bias force acting on theelectromagnetic plunger 30c disappears after the elapse of a constant time (after magnetic and mechanical delay time). Since the bias force by thespring 33 is acting on theinlet valve body 31, the bias force by thespring 33 causes theinlet valve body 31 to close theinlet port 32 when the electromagnetic force acting on theelectromagnetic plunger 30c disappears. When theinlet port 32 is closed, the fuel pressure in the pressurizingchamber 11 starts to rise as theplunger 2 moves upward. - When the fuel remaining in the pressurizing
chamber 11 is pressurized and the fuel pressure in the pressurizingchamber 11 becomes equal to or more than the pressure at andischarge port 12, the fuel is discharged into a high-pressure pipe 29 through adischarge valve mechanism 8 and thedischarge port 12, and then supplied to acommon rail 23. - This process is called a discharge process. That is, the compression process (a rising process from the bottom dead center to the top dead center) of the
plunger 2 comprises the spill process and the discharge process. - The amount of high-pressure fuel to be discharged can be controlled by controlling a timing at which the
electromagnetic coil 30b in the electromagneticinlet valve mechanism 30 is deenergized. When theelectromagnetic coil 30b is deenergized early, the ratio of the spill process in the compression process is small and the ratio of the discharge process in the compression process is large. - That is, little fuel is returned (spilled) to the
inlet path 10d (inlet port 30a), and much high-pressure fuel is discharged. When the timing at which the input voltage is turned off is delayed, the ratio of the spill process in the compression process is large and the ratio of the discharge process in the compression process is small. - That is, much fuel is returned (spilled) to the
inlet path 10d, and little high-pressure fuel is discharged. When to deenergize theelectromagnetic coil 30b is controlled by a command from the ECU. - The above structure enables a timing to deenergize the
electromagnetic coil 30b to be controlled, and the amount of fuel to be highly pressurized and discharged can be thus controlled to an amount required by the internal combustion engine. - Accordingly, out of the fuel delivered to the
fuel inlet port 10a, only a necessary amount of fuel is highly pressurized by the reciprocating motion of theplunger 2 in the pressurizingchamber 11 of thepump housing 1 and supplied under pressure from thedischarge port 12 to thecommon rail 23. -
Injectors 24 and apressure sensor 26 are mounted on thecommon rail 23; the number ofinjectors 24 mounted matches the number of cylinders in the internal combustion engine. Theinjectors 24 inject fuel into the cylinders by being opened and closed by control signals from theECU 27. - An
orifice 25 provided at the entrance of thecommon rail 23, and as a result the spread of the pressure overshooting thecommon rail 23 is intercepted, and theinjectors 24 can be supplied the steady (constant) pressure. - The
pump housing 1 further includesrelief paths discharge valve 8b to communicate with theinlet path 10c. - In the
relief paths relief valve 202 is provided to restrict the fuel flow only to one way from the discharge (outlet)path 12b to theinlet path 10c. The concrete structure will be described with reference toFIG. 2 . - A
relief valve mechanism 200 comprises arelief valve seat 201, arelief valve 202, arelief retainer 203, arelief spring 204, and arelief spring adjuster 205. - The
relief valve seat 201 is press-fitted into thepump housing 1 and fixed. Anorifice plate 214 is fixed between thepump housing 1 and therelief valve seat 201. Therelief valve 202 is seated against therelief valve seat 201 by a pressing force generated by therelief spring 204, the pressing force being transmitted through therelief retainer 203. The force to open therelief valve 202 is determined by the pressing force generated by therelief spring 204, and the pressing force is determined by engaging threads formed on the outer periphery of therelief spring adjuster 205 into threads formed on thepump housing 1 and adjusting an amount by which therelief spring 204 is compressed. An O-ring 213 prevents the fuel from leaking to the outside. - How the relief valve operates will be described below. The
relief valve 202 is pressed against therelief valve seat 201 by therelief spring 204, which generates the pressing force. When the differential pressure between the inlet chamber and the relief path reaches or exceeds a prescribed pressure, therelief valve 202 is released from therelief valve seat 201, opening therelief valve 202. Theorifice plate 214 is disposed at some midpoint in therelief path 210; therelief valve 202 is adapted so that it does not open sensitively in response to a rapid pressure change in therelief path 210. - If an excessively (abnormal) high pressure is generated in the
common rail 23 or another place due to a failure in theinjector 24 or the like, when the differential pressure between therelief path 210 and theinlet path 10a reaches or exceeds the valve opening pressure for therelief valve 202, therelief valve 202 opens and the fuel under excessively (abnormal) high pressure is spilled through therelief path 210 to theinlet path 10c, thereby protecting high-pressure pipes such as thecommon rail 23. - In the first embodiment, the
discharge valve mechanism 8 and electromagneticinlet valve mechanism 30 are disposed coaxially in series with the pressurizingchamber 11 positioned therebetween. Therelief valve mechanism 200 is incorporated into relief valve mounting holes formed in the pump housing in parallel to mounting axis lines for thedischarge valve mechanism 8 and electromagneticinlet valve mechanism 30. - The structure and operation of the high-pressure fuel supply pump will be described in more detail with reference to
FIGs. 1 and2 . - A concave 1A is formed as the pressurizing
chamber 11 at the center of thepump housing 1. Another concave 11A is formed for mounting thedischarge valve mechanism 8 between thedischarge port 12 and the inner peripheral wall of the pressurizingchamber 11. In the outer wall of the pump housing, holes 30A are formed coaxially with the concave 11A for mounting the discharge valve mechanism, which supplies fuel to the pressurizingchamber 11, thehole 30A being used to mount the electromagneticinlet valve mechanism 30. - The axis lines of the concave 11A for mounting the
discharge valve mechanism 8 and thehole 30A for attaching the electromagneticinlet valve mechanism 30 are formed so that they are orthogonal to the central axis line of the concave 1A formed as the pressurizingchamber 11. - The
discharge valve mechanism 8 for discharging fuel from the pressurizingchamber 11 to the discharge path is disposed. - A
cylinder 6 for guiding the reciprocating motion of theplunger 2 is attached in a way that it extends to the pressurizingchamber 11. - In the first embodiment, the concave 11A for mounting the
discharge valve mechanism 8 and thehole 30A for attaching the electromagneticinlet valve mechanism 30 are formed so that their axis lines are aligned. Accordingly, straight assembling is possible from thehole 30A for attaching the electromagneticinlet valve mechanism 30 to the concave 11A for mounting thedischarge valve mechanism 8. Alternatively, a force to press-fit thedischarge valve mechanism 8 can be applied from thehole 30A for attaching the electromagneticinlet valve mechanism 30. In this case, the smallest diameter of thehole 30A must be greater than the maximum outer diameter of thedischarge valve mechanism 8. - However, it is also possible to shift the axis lines of the hole and concave part upward or downward.
- In this case, the
discharge valve mechanism 8 needs to be assembled from anopening 1B formed for attaching thecylinder 6. - The outer periphery of the
cylinder 6 is held by acylinder holder 7, and fixed to thepump housing 1 because the males threads formed on the outer periphery of thecylinder holder 7 are screwed into the female threads formed on thepump housing 1. Thecylinder 6 slidably holds theplunger 2, which reciprocates in the pressurizingchamber 11, along the reciprocating motion. - In the first embodiment, the
cylinder 6 is mounted in theopening 1B for mounting thecylinder 6 after thedischarge valve mechanism 8 is mounted in the concave 11A. - An end of the
cylinder 6 can be thus inserted up to a position at which the end faces the internal end of thedischarge valve mechanism 8 mounted in the concave 11A. Accordingly, the volume to accommodate fuel in the pressurizingchamber 11 can be made small, increasing the fuel compression efficiency. - In the embodiment, a meal seal part is formed on a mating surface S1 between a flange-like annular surface part formed on the outer periphery of the
cylinder 6 and the end surface of theopening 1B in thepump housing 1 so as to isolate the pressurizingchamber 11 from the ambient atmosphere. In general, there is a worry that the mating surface S1 erodes due to cavitation generated by variations in pressure in the pressurizingchamber 11. However, since thecylinder 6 is adapted to extend into the pressurizing chamber and thus the matching surface S1 for sealing can be positioned away from the generated cavitation, the possibility of erosion can be reduced. - In the first embodiment, an arrangement for preventing the
discharge valve mechanism 8 from coming off is achieved by press-fitting acylindrical member 11D into the internal periphery at the bottom (the upper end inFIG. 1 ) of the concave 1A after thedischarge valve mechanism 8 is mounted. - The
cylindrical member 11D also has a function for increasing the fuel compression efficiency by reducing the volume of the pressurizingchamber 11. When thecylindrical member 11D is not mounted, thecylinder 6 can be used to prevent thedischarge valve mechanism 8 from coming off. - When the
cylindrical member 11D is provided, thecylinder 6 does not need to be used as a retainer to prevent thedischarge valve mechanism 8 from coming off. Thecylinder 6 can be thus structured so that it does not reach the position of thedischarge valve mechanism 8 by being shortened. - After the
discharge valve mechanism 8 is press-fitted into the concave 11A, thedischarge valve mechanism 8 itself can be used as the retainer by, for example, swaging the periphery on the pressurizingchamber 11 side to the internal wall of the pump housing. In this case, thecylindrical member 11D is not necessary. When thecylinder 6 is shortened so that it does not reach the position of thedischarge valve mechanism 8, it is also possible to fix thecylinder 6 first and then mount thedischarge valve mechanism 8 into the concave 11A. - Provided at the lower end of the
plunger 2 is atappet 3 that converts the rotational motion of acam 5 attached to a cam shaft of the engine into vertical motion and transfers the vertical motion to theplunger 2. Theplunger 2 is seated against thetappet 3 by aspring 4 through aretainer 15. Accordingly, theplunger 2 can advance and retract (reciprocate) as thecam 5 rotates. - A
plunger seal 13 held at the bottom of the internal periphery of thecylinder holder 7 is provided in a state in which theplunger seal 13 is slidably in contact with the outer periphery of theplunger 2 at the bottom, shown in the drawing, of thecylinder 6, preventing fuel from leaking to the outside. It is also prevented that a lubricant (possibly engine oil) for lubricating a sliding part in the engine room enters the inside of thepump housing 1. - The pressure pulsation reducing
mechanism 9, which reduces the propagation of pressure pulsation generated in the pump to thefuel pipe 28, is fixed to adamper cover 14. - The damper cover 14 is fixed to the
pump housing 1. The inlet path as the low-pressure path comprises 10a, 10b, and 10c. The pressure pulsation reducingmechanism 9, which reduces the propagation of pressure pulsation generated in the pump to thefuel pipe 28 as a result of the reciprocating motion of theplunger 2, comprises twometal diaphragm assemblies metal diaphragm assemblies pump housing 1 includes adamper housing 10B, which is part of the inlet paths. The twometal diaphragm assemblies damper housing 10B. Supporting members 10A1 and 10A2 are provided on the periphery so that the twometal diaphragm assemblies damper cover 14 are screwed into the thread grooves 10C formed on the inner periphery of thedamper housing 10B, and aseal member 10D is pressed so as to provide a seal, making the damper chamber hermetic. Accordingly, the damper chamber is defined in theinlet path 10, and the pressurepulsation reducing mechanism 9 is formed. Intaked fuel is also guided between thedamper cover 14 and themetal diaphragm assembly 9A and between themetal diaphragm assemblies inlet path 10E, basically causing the same pressure to act on the four diaphragms. - Although the
damper cover 14 is fixed to the pump housing by being screwed in this embodiment, thedamper cover 14 can also be fixed by, for example, welding the entire periphery at the P position. In this case, a seal is also provided by the welding, so theseal member 10D in the first embodiment can be eliminated. - In this case, the force to fix the metal diaphragm assemblies is also eliminated, so a process for fixing the
metal diaphragm assemblies damper cover 14. - It is also possible to perform welding after the
damper cover 14 is screwed. In this case, the seal member can be eliminated and themetal diaphragm assemblies - The discharge port (pipe connection part on the discharge side) 12 is formed in the
pump housing 1. The pressurizingchamber 11 for pressurizing fuel is formed at some point on the fuel path from theinlet port 10a to thedischarge port 12. The electromagneticinlet valve mechanism 30 is formed at the entrance of the pressurizingchamber 11. Theinlet valve spring 33 disposed in the electromagneticinlet valve mechanism 30 generates a biased force in the direction to close the inlet port; the biased force is applied to theinlet valve body 31. The electromagneticinlet valve mechanism 30 thus functions as the check valve for limiting the direction in which the fuel flows. The specific structure and operation have been described above. - The
discharge valve mechanism 8 is provided at the exit of the pressurizingchamber 11. Thedischarge valve mechanism 8 comprises aseat member 8a, andischarge valve 8b, andischarge valve spring 8c, a holdingmember 8d used as an discharge valve stopper. When there is no differential pressure between the pressurizingchamber 11 and thedischarge port 12, thedischarge valve 8b is seated against theseat member 8a by the biased force of thedischarge valve spring 8c and thus placed in the closed state. Only when the fuel pressure in the pressurizingchamber 11 is higher than the fuel pressure at thedischarge port 12 by a predetermined value, thedischarge valve 8b opens against thedischarge valve spring 8c, discharging the fuel in the pressurizingchamber 11 to thecommon rail 23 through thedischarge port 12. - After being opened, the
discharge valve 8b comes into contact with the holdingmember 8d and its operation is restricted. Accordingly, the stroke of thedischarge valve 8b is appropriately determined by the holdingmember 8d. If the stroke is too large, the closing of thedischarge valve 8b is delayed and the fuel discharged to thedischarge port 12 spills to the pressurizingchamber 11, lowering the efficiency of the high pressure pump. While thedischarge valve 8b repeats valve opening and closing motions, the holdingmember 8d guides thedischarge valve 8b so that thedischarge valve 8b moves only in the stroke direction. This arrangement enables thedischarge valve mechanism 8 to function as the check valve for limiting the fuel flow direction. - During the spill process, pressure pulsation is generated in the
inlet path 10 by the fuel returned (spilled) to theinlet path 10d. The pressure pulsation is absorbed and reduced when themetal diaphragm assemblies inlet port 10a through theinlet pipe 28 during the spill process. Most of the amount of fuel is absorbed by changes in volumes of themetal diaphragm assemblies - The
relief path 215 is connected to theinlet path 10c as shown again inFIG. 2 . Accordingly, the exit of therelief valve 202 is connected between the pressurepulsation reducing mechanism 9 and theinlet valve 31. - The
orifice plate 214 has one or two or more orifices as shown inFIGs. 5 and6 . - Next, a case in which fuel is normally supplied under high pressure to the
common rail 23 by the high-pressure fuel supply pump will be described. - While in the pressurizing process, that is, the
plunger 2 is rising, a pressure overshoot is generated in the pressurizingchamber 11 in a period from an instant when a shift occurs from the spill process to the pressurizing process to a time immediately after the shift. The pressure overshoot generated in the pressurizingchamber 11 propagates from thedischarge port 12 through therelief path 210 to theorifice plate 214. Theorifice 214a or theorifices orifice plate 214 from further propagating to arelief path 211, so the pressure overshoot in therelief path 211 does not exceed the pressure to open therelief valve seat 201. The differential pressure between the entrance and exit of the relief valve does not therefore exceed the pressure to open the relief valve, so malfunction of the relief valve is eliminated and the amount of fuel discharged under high pressure is not reduced. - It can be thought that orifices (214a, 214b, 214c) of the
orifice plate 214 is an attenuating mechanism that attenuates the energy of the pressure overshoot of he discharged fuel because it explained above. - In the structure described above, the holding
member 8d used as the discharg valve stopper is fitted to theseat member 8a by being slightly press-fitted with thedischarge valve 8b anddischarge valve spring 8c disposed, and assembled to thepump housing 1 as thedischarge valve mechanism 8 by being press-fitted from the pressurizingchamber 11 side. - Accordingly, the ease of assembling can be improved. When a fuel path to the relief valve is connected between the
discharge valve mechanism 8 and thedischarge port 12, the relief valve can be easily incorporated in the pump. - A stopper part of the
discharge valve mechanism 8 is provided in thepump housing 1; thecylinder 6 disposed in the pressurizingchamber 11 has a part for preventing theseat member 8a from coming off; a clearance smaller than a length by which theseat member 8a is press-fitted to thepump housing 1 is provided between theseat member 8a and thecylinder 6. - Accordingly, even when the force to press-fit the seat member to the pump housing is small (that is, the difference between the outer diameter of the seat member and the inner diameter of the pump housing before press-fitting is small), the seat member does not come off, so the press-fitting force (the difference) does not need to be large. This prevents the seat part from being deformed during press-fitting and thus prevents the valve seat capability from being lowered. Accordingly, tolerance ranges for press-fitting forces (the differences) can be roughly managed, making inexpensive machining possible.
- Since there is a clearance between the
seat member 8a and thecylinder 6, incorrect positioning due to dimensional tolerances allowed for the assembling of individual parts can be corrected by the clearance. Even if theseat member 8a moves by the amount equal to the clearance when the pump operates, a press-fitted part can be obtained, maintaining the seal capability of the press-fitted part. - In this embodiment, the inner diameter of the
discharge port 12 into which a joint for piping on the discharging side is screwed can also be made equal to or smaller than the outer diameter of theseat member 8a having the largest outer diameter in thedischarge valve mechanism 8. Accordingly, it is also possible to reduce the area of the sealed part between the discharge port and the joint and thereby to reduce the area of the sealed part at which a pressure is received. - The outer periphery of the
cylinder 6 is held by thecylinder holder 7. When the threads formed on the inner periphery of aflange holder 40 are screwed into the threads formed on thepump housing 1, thecylinder holder 7 obtains a thrust, fixing thecylinder 6 to pumphousing 1. Thecylinder 6 holds theplunger 2, which is the pressurizing member, while allowing theplunger 2 to slide upward and downward. - The high-pressure fuel supply pump is fixed to the engine through the
flange holder 40 andflange 41. Theflange holder 40 is pressed against and fixed to the engine withsetscrews 42 through theflange 41. Since theflange holder 40 is fixed to thepump housing 1 by the threads formed on the inner periphery, the pump housing is thus fixed to the engine. - The
relief path 215 is connected through theinlet path 10c to theinlet path 10b in which the pressurepulsation reducing mechanism 9 is disposed. The exit of therelief valve 202 is thus connected between the pressurepulsation reducing mechanism 9 and theinlet valve 31. - The
orifice plate 214 has one or two or more orifices.FIGs. 5 and6 show examples of theorifice plate 214. The example inFIG. 5 has oneorifice 214a; one example inFIG. 6 has fourorifices 214b, and the other example hasmany orifices 214c. In this case, when a plurality of orifices are formed, each of the orifices is adapted to have a such a small diameter that the viscosity of the fuel to causes an effect. The function of the orifice will be described below. - First, a case in which fuel is normally supplied under high pressure by the high-pressure fuel supply pump to the
common rail 23 will be described. - While the high-pressure fuel supply pump is in the discharge process, a pressure overshoot is generated in the pressurizing
chamber 11. The pressure overshoot generated in the pressurizingchamber 11 propagates from thedischarge port 12 through therelief path 210 to theorifice plate 214. Theorifice 214a (214b or 214c) as an energy attenuating mechanism prevents the pressure overshoot that has propagated up to theorifice plate 214 from further propagating to therelief path 211, so the pressure overshoot in therelief path 211 can be reduced. Accordingly, malfunction of the relief valve is eliminated and a drop in the amount of fuel discharged under high pressure can also be reduced. That is, the efficiency as the high-pressure fuel supply pump can be maintained at a high level. - It can be thought that orifices (214a, 214b, 214c) of the
orifice plate 214 is an attenuating mechanism that attenuates the energy of the pressure overshoot of he discharged fuel because it explained above. - The pressure overshoot generated in the pressurizing
chamber 11 also propagates from thedischarge port 12 through the high-pressure pipe 29 to thecommon rail 23. Anorifice 25 provided at the entrance of thecommon rail 23 blocks the propagation of the pressure overshoot to thecommon rail 23, achieving fuel supply to theinjector 24 under stable pressure. - Described next is a case in which an excessively high pressure is generated in the
common rail 23 or another part under high pressure due to a failure in theinjector 24 or the like. -
FIG. 7 indicates the relation between the amount of fuel discharged under high pressure from the high-pressure fuel supply pump and the pressure in thecommon rail 23. In general, as the amount of fuel discharged under high pressure increases, the fuel pressure in thecommon rail 23 always increases even when the pressure to open therelief valve 202 is the same. - When an orifice is provided at the entrance of the
relief valve 202 by using theorifice plate 214 or the like as shown inFIG. 2 , the malfunction of therelief valve 202 due to the pressure overshoot propagated fromcompression chamber 11 to therelief path 210 as described above can be reduced. However, to block the propagation of the pressure overshoot to therelief valve 202, theorifice 214a must be very small. If an excessively high pressure is generated, the high-pressure fuel passes through theorifice 214a and is spilled through therelief path 215 to theinlet path 10b. However, a pressure drop is generated at theorifice 214a. As a result, the fuel pressure in thecommon rail 23 or the like is much higher than the pressure to open therelief valve 202, which is problematic in terms of the durability of the high-pressure part and costs. - When a plurality of
orifices FIG. 6 , the propagation of the pressure overshoot to therelief valve 202 can be blocked. In addition, when an excessively high pressure is generated, a pressure rise in thecommon rail 23 or the like can be suppressed. This is because although the path area of each of theorifices 214b and theorifices 214c is small, a total path area of these orifices can be made sufficiently large and thus a pressure loss is not generated at theorifice - When the fuel under excessively high pressure is released to the
inlet path 10b, the fuel pressure is rapidly lowered, causing large pressure pulsation in theinlet path 10b. However, the pressurepulsation reducing mechanism 9 disposed in theinlet path 10b can sufficiently reduce this pressure pulsation, preventing the pressure pulsation from propagating to the low-pressure pipe 28 and thereby preventing the pipe from being broken. - The use of sintered metal with mesh stracture or the like instead of the
orifice plate 214 provides the same effect. - In this embodiment described above, the exit of the relief path is connected to the inlet (low-pressure) path. However, the relief valve can be disposed at a position near the pressurizing chamber, preferably in the pressurizing chamber. If only the compression efficiency is not lowered, the exit of the relief path can be connected to the pressurizing chamber so as to spill the fuel to the pressurizing chamber at the occurrence of an excessively high pressure.
- A second embodiment of the present invention will be described with reference to
FIG. 1 andFIGs. 8 to 18 . - First, the structure of a relief valve mechanism B200 will be specifically described with reference to
FIGs. 8 to 10 . - The relief valve mechanism B200 comprises a relief valve housing B206, which is integrally formed with a relief valve seat B201, as well as a relief valve B202, a relief valve retainer B203, a relief spring B204, and a relief valve adjuster B205. The relief valve mechanism B200 is assembled as a sub-assembly outside the
pump housing 1, and then fixed to thepump housing 1 by being press-fitted. - The relief valve B202, relief valve retainer B203, and relief spring B204 are inserted in succession into a relief valve housing B206 in that order. The relief spring adjuster B205 is then fixed to the relief valve housing B206 by being press-fitted. According to the position at which the relief spring adjuster B205 is fixed, a load set by the relief spring B204 is determined. A pressure to open the relief valve B202 is determined by the load set by the relief spring B204. The relief valve mechanism B200 structured in this way is fixed to the
pump housing 1 by being press-fitted. In the second embodiment, therelief path 211 is integrally formed to thepump housing 1, in parallel to thecylinder 6. - Next, the function of the
discharge valve mechanism 8 will be described with reference toFIGs. 11 ,12 , and13 . Thedischarge valve mechanism 8 is disposed at the exit of the pressurizingchamber 11. Thedischarge valve mechanism 8 comprises andischarge valve seat 8a, andischarge valve 8b, andischarge valve spring 8c, and andischarge valve holder 8d. Thedischarge valve 8b is slidably held by thedischarge valve holder 8d, and guided by thedischarge valve holder 8d so that thedischarge valve 8b moves only in the stroke direction when thedischarge valve 8b repeats open and close motions. When thedischarge valve 8b opens and comes into contact with a contact part 8d3 of thedischarge valve holder 8d, the operation of thedischarge valve 8b is restricted. Accordingly, it is prevented that fuel discharged to thedischarge port 12 under high pressure is spilled to the pressurizingchamber 11 due to a delay of thedischarge valve 8b being closed and thus the efficiency as a high pump is lowered. - Discharge ports 8dl, relief ports 8d2, and a spill port 8d4 are formed in the
discharge valve holder 8d. The relief ports 8d2 communicate with therelief path 211. While the high-pressure fuel supply pump is in the discharge process, thedischarge valve 8b is in the open state as shown inFIG. 12 . Thedischarge valve 8b comes in contact with thedischarge valve holder 8d at the contact part 8d3, at which fuel is sealed, so thedischarge path 12b is blocked from therelief path 211 and thus communication therebetween is disabled. - While the high-pressure fuel supply pump is in the intake and spill processes, the
discharge valve 8b is in the closed state as shown inFIG. 13 . Thedischarge valve 8b blocks thedischarge path 12b from the pressurizingchamber 11 at a seat part 8a3 on thedischarge valve seat 8a. Accordingly, even when the pressure in the pressurizingchamber 11 is reduced due the motion of theplunger 2, the fuel under high pressure in thedischarge path 12b does not spill to the pressurizingchamber 11. A clearance is formed between thedischarge valve 8b and thedischarge valve holder 8d at the contact part 8d3 by the amount equal to the stroke of thedischarge valve 8b. Thedischarge port 12 communicates with therelief path 211 through this clearance. That is, while in the discharge process, there is no communication between thedischarge path 12b and therelief path 211; while in the intake and spill processes, there is communication between thedischarge port 12 and therelief path 211. - Next, a case in which fuel is normally supplied under high pressure to the
common rail 23 by the high-pressure fuel supply pump will be described. - While in the discharge process, the fuel highly pressurized in the pressurizing
chamber 11 is supplied from thedischarge port 12 through the high-pressure pipe 29 to thecommon rail 23, as shown inFIG. 12 . - A pressure overshoot is generated in the pressurizing
chamber 11 at this time. The pressure overshoot generated in pressurizingchamber 11 propagates to thedischarge port 12, but thedischarge valve 8b is in the open state. That is, there is no communication between thedischarge port 12 andrelief path 211 as described above, so the pressure overshoot does not propagate to therelief path 211. - Even when a pressure overshoot is generated in the pressurizing
chamber 11, therefore, the relief valve B202 does not malfunction. This means that the amount of fuel discharged from the high-pressure fuel supply pump to thecommon rail 23 is not reduced. - It can be thought that contact part 8d3 for sealing fuel is the path switching mechanism that makesa switchover to enable or disable communication between the relief path and the discharge path because it explained above.
- While in the intake and spill processes, there is communication between the
discharge path 12b andrelief path 211. Since there is no pressure overshoot, however, the relief valve B202 does not malfunction. That is, the amount of fuel discharged from the high-pressure fuel supply pump to thecommon rail 23 is not reduced. - Furthermore, a case in which an excessively (abnormal) high pressure is generated in a high-pressure part such as the
common rail 23 due to a failure of theinjector 24 or the like will be described. - While in the discharge process, there is no communication between the
discharge path 12b andrelief path 211 as described above, so the fuel under excessively high pressure cannot reach the relief valve B202. - While in the intake and spill processes, there is communication between the
discharge port 12 andrelief path 211 as described above. - Accordingly, the fuel under excessively (abnormal) high pressure flows from the
discharge path 12b through therelief path 211, and reaches the relief valve B202. The fuel that passes through the relief valve B202 further passes through a relief path B205a formed in the relief spring adjuster B205, and is released to theinlet path 10b, which is a low-pressure part. The high-pressure parts such as thecommon rail 23 are thus protected. - When the fuel under excessively (abnormal) high pressure is released to the
inlet path 10b, the fuel pressure is rapidly lowered, causing large pressure pulsation in theinlet path 10b. However, the pressurepulsation reducing mechanism 9 disposed further upstream in theinlet path 10b can sufficiently reduce this pressure pulsation, preventing the pressure pulsation from propagating to the low-pressure pipe 28 and thereby preventing the pipe from being broken. - Next, the structure of the
discharge valve mechanism 8 having the function as described above will be described with reference toFIGs. 14 ,15 ,16 ,17 , and18 . - The
discharge valve mechanism 8 is assembled outside thepump housing 1 as a sub-assembly before being incorporated into thepump housing 1. Thedischarge valve spring 8c,discharge valve 8b, and dischargevalve seat 8a are inserted in succession into thedischarge valve holder 8d in that order. Thedischarge valve seat 8a is then fixed to thedischarge valve holder 8d at a press-fitted part 8a1 by being press-fitted. - The
discharge valve mechanism 8 structured in this way is fixed to the pump housing by being press-fitted. Places in which press-fitting is performed are a press-fitted part 8a2, which is a side part of thedischarge valve seat 8a, and press-fitted parts 8d5, which are sides of thedischarge valve holder 8d. Other sides of thedischarge valve holder 8d have a shape formed by cutting two planes 8d6 parallel on its cylindrical shape. That is, the sides of thedischarge valve holder 8d comprise the press-fitted parts 8d5, which are cylindrical, and the planes 8d6. - The two discharge ports 8d1 are machined so that connection to the two planes 8d6 is established. The two relief parts 8d2 are machined so that connection to the cylindrical press-fitted parts 8d5 is established. When the
discharge valve mechanism 8 is press-fitted to thepump housing 1, the relief ports 8d2 machined in thedischarge valve holder 8d overlap therelief path 211 machined in thepump housing 1. The press-fitted part of the pump housing is machined in a cylindrical shape. - While in the discharge process, the fuel pressurized in the pressurizing
chamber 11 is delivered from the discharge ports 8d1, flows along the planes 8d6 machined on the sides of thedischarge valve holder 8d, and are discharged to thedischarge path 12b through the clearance in thepump housing 1, as shown inFIGs. 15 and17 . At that time, therelief path 211 is blocked from thedischarge path 12b by the contact part 8d3 on thedischarge valve holder 8d, so there is no communication therebetween. Accordingly, the pressure overshoot generated in the pressurizingchamber 11 does not propagate to the relief valve B202. - When an excessively (abnormal) high pressure is generated in a high-pressure part such as the
common rail 23 due to a failure of theinjector 24 or the like, a clearance is formed at the contact part 8d3 between thedischarge valve 8b and thedischarge valve holder 8d by the amount equal to the stroke of thedischarge valve 8b, as shown inFIGs. 16 and18 . This clearance is used for thedischarge port 12 to communicate with therelief path 211 through the communicating port 8d4 and relief ports 8d2 formed in thedischarge valve holder 8d. - Accordingly, the fuel under excessively (abnormal) high pressure can reach the relief valve B202, passes through a relief path B205a formed in the relief spring adjuster B205, and is released to the
inlet path 10b, which is a low-pressure part. - The
discharge valve mechanism 8 assembled outside thepump housing 1 is press-fitted to thepump housing 1 at the press-fitted parts 8d5 of thedischarge valve holder 8d and an discharge valve seat 8a3. Particularly, the press-fitted part between 8d5 and thepump housing 1 is structured so that the press-fitted part serves as a blockade between thedischarge path 12b and therelief path 211. - The clearance between the press-fitted parts 8d5 and the
pump housing 1 may be such a minute clearance that the viscosity of the fuel causes an effect. Accordingly, the same effect as described above is obtained, and the load to press-fit thedischarge valve mechanism 8 to thepump housing 1 can be reduced, improving the ease of assembling the high-pressure fuel supply pump. - The present invention is applied to high-pressure fuel supply pumps used in cylinder injection types of internal combustion engines. High-pressure fuel supply pumps having only one pressurizing chamber, that is, so-called single-cylinder types of high-pressure fuel supply pumps have been described in the embodiments, but the present invention can also be used far high-pressure fuel supply pumps having a plurality of pressurizing chamber, that is, so-called multicylinder types of high-pressure fuel supply pumps.
- Features, components and specific details of the structures of the above-described embodiments may be exchanged or combined to form further embodiments optimized for the respective application. As far as those modifications are readily apparent for an expert skilled in the art they shall be disclosed implicitly by the above description without specifying explicitly every possible combination, for the sake of conciseness of the present description.
- According to the invention, there may be provided high-pressure fuel supply pumps according to one or more of the following clauses:
- 1. A high-pressure fuel supply pump having a fuel relief path for connecting a high-pressure fuel path downstream of a discharge valve (8) for discharging fuel pressurized in a pressurizing chamber (11) to a low-pressure fuel path upstream of an inlet valve (30) or the pressurizing chamber (11), a check valve being provided in the fuel relief path as a relief valve for allowing the fuel to flow only to the low-pressure fuel path or the pressurizing chamber (11), wherein an energy attenuating mechanism is provided in a discharge path on a side facing the discharge valve (8) upstream of the relief valve in the fuel relief path so as to prevent an instantaneous pressure rise caused in the discharge path from propagating to the relief valve.
- 2. The high-pressure fuel supply pump according to clause1, wherein an energy attenuating mechanism for reducing energy based on a pressure rise in the discharge path is provided in the relief path, the energy attenuating mechanism acting on the relief valve in a direction to open the relief valve while the discharge valve (8) is in an open operation.
- 3. The high-pressure fuel supply pump according to
cause - 4. The high-pressure fuel supply pump according to at least one of
clauses 1 to 3, wherein the energy attenuating mechanism is structured by including the discharge valve (8); the discharge valve (8) narrows or blocks the high-pressure path near the relief valve while the discharge valve (8) is in the open operation. - 5. A high-pressure fuel supply pump having a low-pressure inlet path for intaking fuel into a pressurizing chamber (11), a discharge path for discharging the fuel from the pressurizing chamber (11), an inlet valve disposed in the inlet path, a discharge valve (8) disposed in the discharge path, a relief path for connecting a side downstream of the discharge valve (8) in the discharge path to a side upstream of the inlet valve in the inlet path or connecting the side downstream of the discharge valve (8) to the pressurizing chamber (11), the discharge path side being the upstream side and the inlet path side being the downstream side or the discharge path side being the upstream side and the pressurizing chamber (11) side being the downstream side, and a relief valve, disposed in the relief path, for limiting a flow of the fuel to only one direction, from the upstream side to the downstream side, the relief valve being structured so that the relief valve is opened when a differential pressure between an entrance and an exit
thereof is raised to or above a predetermined valve opening pressure, wherein an energy attenuating mechanism is provided upstream of the relief valve in the relief path so as to prevent a pressure pulsation caused in the discharge path from acting on the relief valve or reduce the pressure pulsation. - 6. The high-pressure fuel supply pump According to
clause 5, wherein an orifice is provided near the relief valve in the relief path, as the energy attenuating mechanism. - 7. The high-pressure fuel supply pump according to
clauses - 8. The high-pressure fuel supply pump according to at least one of
clauses 5 to 7, wherein a member having a mesh structure is provided near the relief valve in the relief path, as the energy attenuating mechanism. - 9. The high-pressure fuel supply pump according to at least one of
clauses 5 to 8, wherein a path switching mechanism is provided near the relief valve in the relief path, as the energy attenuating mechanism; the path switching mechanism makes a switchover to enable or disable communication between the relief path and the discharge path. - 10. The high-pressure fuel supply pump according to at least one of
clauses 5 to 9, wherein the path switching mechanism is structured by including a switching mechanism for disabling the communication between the relief path and the discharge path while the high-pressure fuel supply pump is in a process to discharge high-pressure fuel and enabling the communications in other processes. - 11. The high-pressure fuel supply pump according to at least one of
clauses 5 to 10, wherein the discharge valve (8) is used as the switching mechanism; the discharge valve (8) narrows or blocks a connection part between the discharge path and the relief path while the discharge valve is in the open operation. - 12. The high-pressure fuel supply pump according to at least one of
clauses 5 to 11, wherein a connection opening between the relief path and the discharge path is formed on a side of a cylindrical holding part that guides reciprocating motion of the discharge valve (8); the discharge valve narrows or blocks the connection opening when the discharge valve (8) is open. - 13. The high-pressure fuel supply pump according to at least one of
clauses 5 to 12, wherein a guiding path is provided on a side of the cylindrical holding part so as to guide the fuel in the pressurizing chamber (11) to the discharge path while the discharge valve (8) in the open operation. - 14. The high-pressure fuel supply pump according to at least one of
clauses 5 to 13, wherein the cylindrical holding part is fixed to
a discharge opening part in the pressurizing chamber (11); a seat member for the discharge valve (8) is fixed to an end on the pressurizing chamber (11) side of the cylindrical holding part; the discharge valve (8) is pressed against the seat member by a spring held in the cylindrical holding part.
Claims (8)
- A high-pressure fuel supply pump comprising:a pressurizing chamber (11) for pressurizing fuel,an intake fuel path (28) for intaking, during an intake process, low-pressure fuel into the pressurizing chamber (11) during an intake process,a discharge fuel path (29) for discharging, during a discharge process, high pressure fuel pressurized in the pressurizing chamber (11),an inlet valve (30) being disposed in the intake fuel path (28),a discharge valve (8) being disposed in the discharge fuel path (29),a fuel relief path (215) for connecting the discharge fuel path (29) to the intake fuel path (28) or the pressurizing chamber (11), anda relief valve (202) being provided in the fuel relief path (215) for allowing the fuel to flow only from the discharge fuel path (29) at the upstream side of the relief valve (202) to the intake fuel path (28) at the downstream side of the relief valve (202) or the pressurizing chamber (11) at the downstream side of the relief valve (202), the relief valve (202) being structured so that the relief valve (202) is opened when a differential pressure between an entrance and an exit thereof is raised to or above a predetermined valve opening pressure,wherein an energy attenuating mechanism is provided between the relief path (215) and the discharge path (29) so as to prevent the relief valve (202) to be opened by an instantaneous pressure rise caused in the discharge path (29) during the discharge process.
- The high-pressure fuel supply pump according to claim 1,
wherein the energy attenuating mechanism is provided in the fuel relief path (215) at the upstream side of the relief valve (202). - The high-pressure fuel supply pump according to claim 1 or 2,
wherein the energy attenuating mechanism is structured by including at least one orifice. - The high-pressure fuel supply pump according to at least one of claims 1 to 3, wherein the energy attenuating mechanism is structured by including a path switching mechanism for making a switchover to enable or disable communication between the fuel relief path (215) and the discharge fuel path (29), the path switching mechanism being provided in the discharge fuel path (29) at the upstream side of the discharge valve (8), and the path switching mechanism being configured to disable the communication between the fuel relief path (215) and the discharge fuel path (29) during the discharge process and to enable the communication between the fuel relief path (215) and the discharge fuel path (29) in other processes including at least the intake process.
- The high-pressure fuel supply pump according to claim 4,
wherein the discharge valve (8) is used as the switching mechanism, the discharge valve (8) narrowing or blocking a connection part between the discharge fuel path (29) and the fuel relief path (215) while the discharge valve (8) is in the open operation. - The high-pressure fuel supply pump according to claim 5,
wherein a connection opening between the fuel relief path (215) and the discharge fuel path (29) is formed an a side of a cylindrical holding part that guides reciprocating motion of the discharge valve (8), the discharge valve (8) narrowing or blocking the connection opening when the discharge valve (8) is open. - The high-pressure fuel supply pump according to claim 6,
wherein a guiding path is provided on a side of the cylindrical holding part so as to guide the fuel in the pressurizing chamber (11) to the discharge path (8) while the discharge valve (8) is in the open operation. - The high-pressure fuel supply pump according to claim 6,
wherein the cylindrical holding part is fixed to a discharge opening part in the pressurizing chamber (11), a seat member for the discharge valve (8) is fixed to an end on the pressurizing chamber side of the cylindrical holding part, and the discharge valve (8) is pressed against the seat member by a spring held in the cylindrical holding part.
Applications Claiming Priority (2)
Application Number | Priority Date | Filing Date | Title |
---|---|---|---|
JP2006235866A JP2008057451A (en) | 2006-08-31 | 2006-08-31 | High-pressure fuel supply pump |
EP07015699A EP1898084B1 (en) | 2006-08-31 | 2007-08-09 | High-pressure fuel supply pump |
Related Parent Applications (1)
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EP07015699.7 Division | 2007-08-09 |
Publications (2)
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EP2336545A1 true EP2336545A1 (en) | 2011-06-22 |
EP2336545B1 EP2336545B1 (en) | 2013-07-31 |
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Family Applications (2)
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EP07015699A Active EP1898084B1 (en) | 2006-08-31 | 2007-08-09 | High-pressure fuel supply pump |
EP10185169.9A Active EP2336545B1 (en) | 2006-08-31 | 2007-08-09 | High-pressure fuel supply pump |
Family Applications Before (1)
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EP07015699A Active EP1898084B1 (en) | 2006-08-31 | 2007-08-09 | High-pressure fuel supply pump |
Country Status (4)
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US (1) | US20080056914A1 (en) |
EP (2) | EP1898084B1 (en) |
JP (1) | JP2008057451A (en) |
CN (1) | CN101135283B (en) |
Cited By (1)
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WO2014083979A1 (en) * | 2012-11-29 | 2014-06-05 | 日立オートモティブシステムズ株式会社 | High-pressure fuel supply pump |
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Also Published As
Publication number | Publication date |
---|---|
JP2008057451A (en) | 2008-03-13 |
EP2336545B1 (en) | 2013-07-31 |
US20080056914A1 (en) | 2008-03-06 |
CN101135283B (en) | 2010-06-16 |
EP1898084A1 (en) | 2008-03-12 |
CN101135283A (en) | 2008-03-05 |
EP1898084B1 (en) | 2013-01-09 |
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