JP2004332645A - Fuel feed pump - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To make a straight pin 72 not requiring air bleeding shape such as an air bleeding groove or an air bleeding hole, and of low cost and high strength usable, and prevent a tip part of the straight pin 72 from sticking out of a washer 71 to a cam ring 45 side. <P>SOLUTION: A base end part of the straight pin 72 is loosely fitted in a pin insertion hole 74 by setting a pin diameter of the straight pin 72 smaller than a diameter of the pin insertion hole 74 opening on an inner wall surface of a cam chamber 50 of a pump housing 40 of a supply pump. The tip part of the straight pin 72 is prevented from sticking out of the washer 71 in avail direction cam ring 45 side and a tip end surface of the straight pin 72 is prevented from interfering with an end surface of the cam ring 45 by making a shape of a pin engagement hole 73 of the washer 71 a bottomed sack shaped hole (blocked hole). <P>COPYRIGHT: (C)2005,JPO&NCIPI

Description

[0001]
TECHNICAL FIELD OF THE INVENTION
The present invention relates to a fuel supply pump used in a pressure-accumulation type fuel injection device, and in particular, pressurizes fuel sucked into a plurality of pressurized chambers to increase the pressure, and pressurizes the pressurized high-pressure fuel into a common rail. Related to supply pumps.
[0002]
[Prior art]
BACKGROUND ART Conventionally, a common rail fuel injection system (accumulator fuel injection device) has been known as a fuel injection system for a diesel engine. This is because the high-pressure fuel pumped from a supply pump (fuel supply pump) that pressurizes the fuel sucked into a plurality of pressurized chambers through the suction metering valve and increases the pressure is stored in the common rail, and is stored in the common rail. The stored high-pressure fuel is injected and supplied from a plurality of injectors into the combustion chamber of each cylinder of the engine at a predetermined timing (for example, see Patent Documents 1 and 2).
[0003]
Here, in the supply pump as described above, when a cam integrated with a camshaft that is rotationally driven by an engine crankshaft rotates, a cam ring having a quadrangular outer shape revolving along a predetermined circular path is provided. An annular plate-shaped washer for positioning the cam ring in the thrust direction (axial direction) is rotatably accommodated in the cam chamber of the pump housing. Then, after press-fitting the base end of the spring pin into the pin insertion hole opened in the wall surface of the cam chamber of the pump housing, the tip of the spring pin penetrates through the both ends of the washer in a through hole. By assembling the washer so as to fit into the cam ring, the washer is prevented from rotating together with the cam ring.
[0004]
[Patent Document 1]
JP-A-2000-282929 (pages 1-13, FIGS. 1-15)
[Patent Document 2]
JP-A-2001-08230 (Page 1-18, FIG. 1 to FIG. 20)
[0005]
[Problems to be solved by the invention]
However, in the conventional supply pump, the strength of the spring pin is smaller than that of the straight pin, and social regulations such as stricter exhaust gas regulations in recent years, higher fuel injection pressure in the future, and higher engine rotation speed have been adopted. A problem arises in that it cannot meet needs. Then, as shown in FIG. 6, after the base end of the straight pin 101 is pressed into the pin insertion hole 103 of the pump housing 102, the tip of the straight pin 101 fits into the through hole 105. There is a supply pump in which the washer 104 is assembled to prevent the washer 104 from rotating together with the cam ring 106. The reason why the straight pin 101 is pressed into the pin insertion hole 103 is that the straight pin 101 passes through the through hole 105 when the straight pin 101 is free to move in the axial direction. This is to prevent contact interference between the tip of the straight pin 101 that has protruded and the end face of the cam ring 106.
[0006]
Further, as shown in FIG. 6, the base end of the straight pin 101 is press-fitted into the pin insertion hole 103, and an air vent hole 107 or an air vent for removing air remaining in the pin insertion hole 103 at the time of press-fitting. There is a structure in which a groove (not shown) is formed by inner diameter or outer diameter cutting or the like, but this becomes very expensive because the straight pin 101 is subjected to inner diameter or outer diameter cutting. When the base end of the straight pin 101 is press-fitted into the pin insertion hole 103 without forming the air release hole 107 or the air release groove, the air is compressed by the straight pin 101 and the pin insertion is performed. Since the supply pin remains in the hole 103, during operation of the supply pump, the straight pin 101 comes out of the pin insertion hole 103 toward the cam ring side in the axial direction due to the air pressure of the compressed air remaining in the depth of the pin insertion hole 103. The problem arises.
[0007]
[Object of the invention]
An object of the present invention is to make it possible to use an inexpensive and high-strength straight pin that does not require an air bleed shape, thereby strengthening exhaust gas regulations in recent years, further increasing the pressure of fuel injection, and increasing the engine speed. It is an object of the present invention to provide a fuel supply pump that can respond to social needs such as high rotation speed. Another object of the present invention is to provide a fuel supply pump capable of preventing the straight pin from protruding from the washer toward the cam ring, thereby preventing contact interference between the tip of the straight pin and the end face of the cam ring.
[0008]
[Means for Solving the Problems]
According to the first aspect of the present invention, the straight pin is provided on the wall surface of the cam chamber of the pump housing so that the base end of the straight pin is clearance-fitted. Even if it is inserted into the insertion hole, the air existing in the pin insertion hole escapes from the gap between the outer periphery of the straight pin and the hole wall surface of the pin insertion hole to the outside of the pin insertion hole. Accordingly, during operation of the fuel supply pump, the base end of the straight pin does not fall out of the pin insertion hole due to the air pressure of the compressed air remaining inside the pin insertion hole.
As a result, the inexpensive, high-strength straight pin that does not need to be cut inside or outside the air vent shape is used as a washer fixing means to prevent the washer from rotating together with the cam ring. Therefore, it is possible to respond to social needs such as stricter exhaust gas regulations in recent years, further increase in fuel injection pressure, and increase in engine speed.
[0009]
In addition, a pin fitting hole into which the tip of the straight pin is fitted is provided on the facing surface of the washer facing the wall surface of the cam chamber, and at least one of the pin insertion hole and the pin fitting hole is provided. In the case where the pin fitting hole of the washer is temporarily formed as a through hole by providing a stopper that stops the axial movement of the straight pin at a position just before the tip of the straight pin comes into contact with the end surface of the cam ring, However, since the tip of the straight pin can be prevented from protruding from the pin fitting hole of the washer toward the cam ring in the axial direction, contact interference between the tip of the straight pin and the end face of the cam ring can be reliably prevented.
[0010]
According to the second aspect of the present invention, a pin locking portion for locking the tip end of the straight pin may be provided in the pin fitting hole of the washer as the above-mentioned stopping portion. Even in this case, since the tip of the straight pin can be prevented from protruding from the pin fitting hole of the washer toward the cam ring in the axial direction, contact interference between the tip of the straight pin and the end face of the cam ring can be reliably prevented. it can.
[0011]
According to the invention described in claim 3, a bottom wall surface may be provided in the pin fitting hole of the washer as the above-mentioned pin locking portion. As the above-mentioned pin locking portion, for example, a hole shape of a pin fitting hole of a washer is formed in a bottomed bag-shaped hole (a blind hole) that is opened only on an opposing surface side that is disposed opposite to a wall surface of a cam chamber of a pump housing. ) It may be shaped. Further, an opening having an opening diameter smaller than the pin diameter of the straight pin may be provided on the bottom wall surface.
[0012]
According to the invention described in claim 4, the inner diameter of the pin engagement portion on the wall surface side of the cam chamber of the pin fitting hole is set to be larger than the pin diameter of the straight pin, and Also, the inner diameter of the pin fitting hole on the cam ring side may be set small. The hole shape of the pin fitting hole of the washer may be, for example, a hole having a substantially conical hole wall surface.
[0013]
According to the fifth aspect of the present invention, the press-fitting portion for press-fitting and fixing the tip of the straight pin may be provided in the pin fitting hole of the washer as the stopping portion. However, in this case, after the tip of the straight pin and the washer are press-fitted and fixed, the washer is inserted into the pump housing so that the base end of the straight pin is inserted into the pin insertion hole of the pump housing in a clearance-fitted state. Is desirably assembled on the wall of the cam chamber.
[0014]
According to the sixth aspect of the present invention, as the straight pin, a stepped straight pin having a pin diameter smaller on the distal end side than on the step portion may be smaller than a pin diameter on the base end side than the step portion. And, as the above-mentioned stopping portion, a pin locking portion for locking the step portion of the stepped straight pin may be provided in the pin insertion hole of the pump housing. Even in this case, since the tip of the straight pin can be prevented from protruding from the pin fitting hole of the washer toward the cam ring in the axial direction, contact interference between the tip of the straight pin and the end face of the cam ring can be reliably prevented. it can.
[0015]
According to the seventh aspect of the present invention, the pin locking portion is provided separately from the pump housing, and holds the step portion of the stepped straight pin in the pin insertion hole of the pump housing. May be provided. According to the eighth aspect of the present invention, the pin locking portion is provided integrally with the pump housing, and the step portion of the stepped straight pin is caulked and fixed in the pin insertion hole of the pump housing. A caulking portion may be provided.
[0016]
BEST MODE FOR CARRYING OUT THE INVENTION
[Configuration of First Embodiment]
1 and 2 show a first embodiment of the present invention. FIG. 1 is a view showing the entire structure of a common rail type fuel injection system, and FIGS. 2 (a) and 2 (b) show main components of a supply pump. FIG. 3 is a diagram showing a structure.
[0017]
The fuel injection device for an internal combustion engine according to the present embodiment is a common rail fuel injection system (accumulator fuel injection device) known as a fuel injection system for an internal combustion engine (hereinafter referred to as an engine) such as a multi-cylinder diesel engine. The high-pressure fuel accumulated in the engine 1 is injected and supplied to the combustion chamber of each cylinder of the engine through a plurality of injectors (electromagnetic fuel injection valves) 2 mounted corresponding to each cylinder of the engine. It is configured as follows.
[0018]
This common rail fuel injection system includes a common rail 1 for accumulating high-pressure fuel, a plurality of injectors 2 for injecting fuel into the combustion chamber of each cylinder of the engine, and a plurality of pressurized chambers via a suction metering valve (SCV) 5. Intake metering type supply pump (fuel supply pump) 4 that pressurizes fuel sucked into the tank to increase the pressure, and an engine that electronically controls the solenoid valves 3 of the plurality of injectors 2 and the suction metering valve 5 of the supply pump 4. A control unit (hereinafter referred to as an ECU). In FIG. 1, only the injectors 2 corresponding to one cylinder of the four-cylinder engine are shown, and the injectors for the other cylinders are not shown.
[0019]
Since it is necessary to constantly accumulate high-pressure fuel corresponding to the injection pressure of the fuel, high-pressure fuel is supplied from the supply pump 4 via the high-pressure fuel pipe 6 to the common rail 1 under pressure. The common rail 1 has a fuel pressure sensor (not shown) for detecting the fuel pressure (common rail pressure) in the common rail 1 and a valve which is opened when the common rail pressure exceeds the limit setting pressure to set the common rail pressure to the limit. A pressure limiter 7 for keeping the pressure below the pressure is provided.
[0020]
Injection of fuel from the injector 2 into the combustion chamber of each cylinder of the engine is performed by energizing and stopping energization of the solenoid valve 3 that controls the fuel pressure in the back pressure control chamber that controls the operation of a command piston that works in conjunction with the nozzle needle. Controlled. That is, while the solenoid valve 3 of the injector 2 is energized and the nozzle needle is opened, the high-pressure fuel stored in the common rail 1 is injected and supplied into the combustion chamber of each cylinder of the engine. Thus, the engine is operated. Here, leaked fuel that overflows from the injector 2, the supply pump 4, and the pressure limiter 7 to the low-pressure side of the fuel system is returned to the fuel tank 9 through the fuel recirculation path 8.
[0021]
The supply pump 4 of the present embodiment is provided with a pump drive shaft (camshaft) 11 that is rotationally driven by an engine. And a drive pulley (not shown) that is drivingly connected to the crank pulley via a belt. The supply pump 4 is an inner-cam type feed pump (low-pressure supply pump) 12 that pumps low-pressure fuel from the fuel tank 9 through the fuel supply path 10 by rotating the camshaft 11 with rotation of the crankshaft of the engine. Built-in. In FIG. 1, the feed pump 12 is disclosed in a form in which the feed pump 12 is expanded by 90 degrees. Here, a fuel filter 13 for filtering or trapping impurities contained in the fuel drawn into the feed pump 12 from the fuel tank 9 is provided in the middle of the fuel supply path 10.
[0022]
When the camshaft 11 rotates and the feed pump 12 is driven, the fuel is introduced into the fuel introduction path 15 from the fuel tank 9 via the fuel filter 13, the sleeve nipple and an inlet (fuel inlet) 14 composed of a screw. Then, it is sucked into the suction side of the feed pump 12. Then, the feed pump 12 pressurizes the sucked fuel to a predetermined pressure and sends out the fuel to the fuel reservoir 17 of the suction metering valve 5 via the fuel outlet path 16.
[0023]
In addition, in the vicinity of the feed pump 12 of the present embodiment, pressure adjustment is performed so that the discharge pressure discharged from the feed pump 12 into the fuel reservoir 17 of the suction metering valve 5 does not exceed a predetermined fuel pressure. A valve (regulating valve) 18 is provided. Excess fuel that has overflowed from the suction metering valve 5 is returned to the suction side of the feed pump 12 through the fuel recirculation path 12a and the fuel introduction path 15. A part of the fuel discharged from the feed pump 12 lubricates sliding parts such as a pump element, which will be described later, and then passes through an outlet (fuel outlet) 19 composed of a sleeve nipple and a screw, and a fuel recirculation passage 8. It is returned to the fuel tank 9.
[0024]
The fuel in the fuel reservoir 17 is sucked into the first and second pressurizing chambers 51 and 52 via the suction metering valve 5 and the first and second suction valves 31 and 32. That is, the suction metering valve 5 is provided in the fuel suction path 20 from the fuel accumulation chamber 17 to the first and second suction valves 31 and 32. The suction metering valve 5 is a normally open type (normally open type) electromagnetic flow control valve, and a valve (valve element) 22 slidably held in a sleeve-shaped housing 21 and a valve (valve element) 22. It has a valve body driving means (solenoid coil) 23 for driving the body 22 in the valve closing direction and a valve body biasing means (coil spring) 24 for biasing the valve body 22 in the valve opening direction.
[0025]
The solenoid coil 23 is held by a resin housing 25 fixed to the right end side of the sleeve-shaped housing 21 in the drawing, and attracts a plunger (movable body) 26 interlocked with the valve element 22 by electromagnetic force. The valve body 22 is opened by the urging force of the coil spring 24 when the solenoid coil 23 is not energized, and opens when the solenoid coil 23 is energized against the urging force of the coil spring 24.
[0026]
In the supply pump 4 of the present embodiment, two first and second cylinder heads 33 and 34 are fixed to the upper and lower end surfaces of the pump housing 40 in the drawing. In the sliding holes of the two first and second cylinder heads 33 and 34, two first and second plungers 41 and 42 are accommodated so as to be reciprocally slidable. A first pressurizing chamber 51 for fuel formed by the inner wall surface of the first cylinder head 33 is provided at the upper end in the drawing of the first plunger 41. A second pressurizing chamber 52 for fuel formed by the inner wall surface of the second cylinder head 34 is provided at the lower end of the second plunger 42 in the drawing.
[0027]
That is, the first and second pressurization chambers 51 and 52 are configured such that low-pressure fuel flows from the outlet of the suction metering valve 5 through the fuel suction path 20 and the first and second suction valves 31 and 32. ing. In the present embodiment, a pump element (high-pressure supply pump) of the supply pump 4 is configured by the two first and second plungers 41 and 42 and the two first and second cylinder heads 33 and 34.
[0028]
Each of the first and second suction valves 31 and 32 has a valve body and a coil spring, and is a check valve for preventing a backflow of fuel from the first and second pressurizing chambers 51 and 52 toward the suction metering valve 5. And is provided between the fuel suction path 20 and the first and second pressurizing chambers 51 and 52. In the normal state, the valve bodies of the first and second suction valves 31 and 32 are urged in the vertical direction in the figure by the urging forces of the respective coil springs, and are seated on the seat surface and closed. When low-pressure fuel flows from the suction metering valve 5 through the fuel suction path 20, the valve body opens by the fuel pressure, and the fuel is sucked into the first and second pressurizing chambers 51 and 52. When the pressurization is started, each valve body of the first and second suction valves 31 and 32 is closed by the fuel pressure in the first and second pressurization chambers 51 and 52, and the fuel pumping ends. This state is maintained until.
[0029]
The fuel pressurized in the first pressurizing chamber 51 is discharged from the first discharge valve 61 via the first fuel pressure feed path 35. Similarly, the fuel pressurized in the second pressurizing chamber 52 is discharged from a second discharge valve (not shown) via a second fuel pressure feed path (not shown). These first discharge valve 61 and second discharge valve prevent reverse flow of fuel from the first discharge hole 63 and the second discharge hole (not shown) toward the first pressurizing chamber 51 and the second pressurizing chamber 52. It functions as a stop valve and has a ball valve and a coil spring. The high-pressure fuel discharged from the first discharge hole 63 and the second discharge hole is supplied to the fuel pressure supply path 67 in the first sleeve nipple (pipe joint) 65 and the fuel pressure supply path in the second sleeve nipple (pipe joint) ( After flowing into the high-pressure fuel pipe 6 through the high-pressure fuel pipe 6 through the high-pressure fuel pipe 6, it is supplied to the common rail 1 from the high-pressure fuel pipe 6.
[0030]
A camshaft 11 that is driven to rotate in synchronization with the crankshaft of the engine is inserted through a pump housing 40 made of a metal material, and is rotatably supported via a journal bearing. An eccentric cam 44 is integrally formed on the outer periphery of the intermediate portion of the camshaft 11, and the two first and second plungers 41 and 42 are arranged at symmetric positions in the vertical direction in the drawing with the eccentric cam 44 interposed therebetween. ing. The eccentric cam 44 is provided eccentrically with respect to the axis of the camshaft 11 and has a circular cross section.
[0031]
On the outer periphery of the eccentric cam 44, a cam ring 45 having a substantially square outer shape is slidably held via an annular bush 43. A hollow portion having a circular cross section is formed inside the cam ring 45, and the bush 43 and the eccentric cam 44 are accommodated therein. Further, on the upper and lower end surfaces of the cam ring 45 in the figure, first and second plate members 46 and 47 integrated with the two first and second plungers 41 and 42 are provided on the outer periphery of the first and second plungers 41 and 42. The cam ring 45 is pressed against the upper and lower end surfaces of the cam ring 45 by the urging forces of the first and second coil springs 48 and 49 disposed on the side. The eccentric cam 44 and the cam ring 45 are made of a metal material, and are rotatably accommodated in a cam chamber 50 formed inside the pump housing 40.
[0032]
With this configuration, when the eccentric cam 44 integrated with the camshaft 11 rotates, the cam ring 45 revolves along a predetermined circular path, and the first and second plate members 46 and 47 move on the upper and lower end surfaces of the cam ring 45 in the drawing. Reciprocating sliding. Along with this, the two first and second plungers 41 and 42 slide back and forth on the sliding surfaces in the two first and second cylinder heads 33 and 34 in the vertical direction in FIG. It is possible to pressurize the fuel in the chambers 51 and 52 to increase the pressure.
[0033]
Here, in the present embodiment, as shown in FIG. 1, between the annular wall surface of the cam chamber 50 of the pump housing 40 and both end surfaces in the thrust direction (axial direction) of the eccentric cam 44 integrated with the camshaft 11. In addition, two thrust washers (hereinafter referred to as "thrust washers") for allowing the eccentric cam 44, the cam ring 45, and the first and second plate members 46 and 47 to easily move in the rotational direction, and for positioning the cam ring 45 in the axial direction (thrust direction). (Abbreviated as washer) 71 is interposed. These washers 71 are formed of an annular plate-shaped metal plate having an outer diameter corresponding to the range of revolution of the cam ring 45. In the present embodiment, the clearance formed between the end face of the two washers 71 and the end face of the cam ring 45 is set to a predetermined value or less, and the movement range of the two washers 71 in the axial direction (thrust direction) is set. It constitutes a movement range regulating means for regulating.
[0034]
As shown in FIGS. 1 and 2, the two washers 71 are provided at their opposing surfaces (annular end surfaces) facing the annular wall surface of the cam chamber 50 of the pump housing 40 with clearances between the ends of the two straight pins 72. Two pin fitting holes 73 for fitting are respectively opened. Here, the two straight pins 72 are made of a cylindrical metal member, and prevent the two washers 71 from rotating together with the cam ring 45. Each of the pin fitting holes 73 of the two washers 71 is formed with a predetermined tool of the two washers 71 by a combination of a rotary cutting motion and a linear feed motion in the direction of the center line of the rotation using a processing tool such as a drill. A hole is drilled at the bottom.
[0035]
In addition, the pin fitting holes 73 of the two washers 71 are changed from through holes (see FIG. 6) like conventional products to blind holes having blind holes. In other words, the movement of the straight pin 72 in the axial direction is restrained on the cam ring 45 side of each pin fitting hole 73 of the two washers 71 at a position before the tip of the straight pin 72 comes into contact with the end face of the cam ring 45. A bottom wall surface 73a is provided as a stopping portion, that is, a pin locking portion for locking the distal end portion of the straight pin 72. The bottom wall surface 73a is provided on a bottom wall portion (blocking portion) 71a that completely blocks the cam ring 45 side of the pin fitting hole 73. The bottom wall portion 71a may be formed integrally with the washer 71 or may be press-fitted as a separate component. However, the bottom wall portion 71a is integrated with the washer 71 to reduce the number of assembly steps and the number of components. It is desired to form it.
[0036]
Further, two pin insertion holes 74 for fitting the base ends of the two straight pins 72 into respective gaps are respectively opened on the annular wall surfaces opposed to each other in the cam chamber 50 of the pump housing 40. The outer diameter (pin diameter) of the two straight pins 72 is set smaller than the inner diameter of the two pin insertion holes 74 of the pump housing 40. The two pin insertion holes 74 are formed in a circular shape forming the cam chamber 50 of the pump housing 40 by a combination of a rotary cutting motion and a linear feed motion in the direction of the center line of the rotation using a processing tool such as a drill. A hole is formed at a predetermined position on the wall surface (a position on the same axis as the center line of the pin fitting hole 73 of the washer 71) with a bottom.
[0037]
Here, FIG. 2 shows the cam ring 45, the (first) washer 71, the (first) straight pin 72, the (first) pin fitting hole 73, and the (first) pin insertion hole 74 on the left side in FIG. 1, only the (second) washer 71, the (second) straight pin 72, the (second) pin fitting hole 73, and the (second) pin insertion hole 74 on the right side in FIG. 1 has the same configuration as the components on the left side in the figure. Further, in the present embodiment, after the base end of the straight pin 72 is inserted into the pin insertion hole 74 opened on the wall surface of the cam chamber 50 of the pump housing 40, the distal end of the straight pin 72 is inserted into the pin fitting hole 73. By attaching the washer 71 to the wall surface of the cam chamber 50 of the pump housing 40 so as to fit inside, the washer 71 is prevented from rotating together with the cam ring 45.
[0038]
[Operation of First Embodiment]
Next, the operation of the supply pump 4 used in the common rail fuel injection system of the present embodiment will be briefly described with reference to FIG.
[0039]
When the camshaft 11 of the supply pump 4 is driven by a belt driven by the crankshaft of the engine and rotates, the eccentric cam 44 integrated with the camshaft 11 rotates. Along with this, the cam ring 45 having an approximately quadrangular outer shape revolves along a predetermined circular path, and the first and second plate members 46 and 47 slide back and forth on the upper and lower end surfaces of the cam ring 45 in the drawing. At this time, the clearance formed between the inner wall surface of the cam chamber 50 and both end faces of the cam ring 45 is adjusted by the two washers 71 installed in the cam chamber 50 of the pump housing 40. The range of movement in the axial direction (thrust direction) is restricted. Then, the two first and second plungers 41 and 42 reciprocate on the sliding surfaces in the two first and second cylinder heads 33 and 34 in the vertical direction in the figure. Then, the two first and second plungers 41 and 42 are alternately lifted with the revolution of the cam ring 45, and in the state of FIG. 1, the first plunger 41 is at the top dead center and the second plunger 42 is at the bottom dead center. positioned.
[0040]
When the first plunger 41 located at the top dead center is lowered, the pressure in the first pressurizing chamber 51 is reduced, and the valve body of the first suction valve 31 is opened by the fuel pressure, and the first suction valve 31 is opened from the fuel suction path 20. Fuel is sucked into the pressurizing chamber 51. When the first plunger 41 reaches the bottom dead center and starts rising again, the pressure in the first pressurizing chamber 51 increases, and the valve body of the first suction valve 31 is closed by the fuel pressure. The fuel pressure in the first pressurizing chamber 51 rises, the ball valve of the first discharge valve 61 is opened, and the fuel pressure feed path 67 in the first sleeve nipple 65 from the first discharge hole 63 to the high pressure fuel pipe 6 Is fed into the common rail 1 via a high-pressure supply passage therein.
[0041]
On the other hand, the second plunger 42 also slides back and forth between the top dead center and the bottom dead center in the same manner as the first plunger 41, so that the fuel in the second pressurization chamber 52 is discharged from the second discharge hole through the second discharge hole. The pressure is fed into the common rail 1 through the two-sleeve nipple and the high-pressure fuel pipe 6. Thus, the supply pump 4 is configured such that the suction stroke and the pressure feeding stroke are performed two cycles per rotation of the camshaft 11. The high-pressure fuel stored in the common rail 1 can be injected and supplied into the combustion chamber of each cylinder of the engine at a predetermined timing by driving the solenoid valve 3 of the injector 2 at an arbitrary injection timing.
[0042]
The discharge of the fuel discharged from the first and second pressurizing chambers 51 and 52 of the supply pump 4 into the common rail 1 through the first and second discharge valves 61, the first sleeve nipple 65, and the high-pressure fuel pipe 6. The feed amount is controlled from the feed pump 12 by controlling the pump drive current value to the solenoid coil 23 by the ECU to adjust the lift amount of the valve body 22 of the suction metering valve 5, that is, the opening area of the fuel suction path 20. Control can be performed by adjusting the amount of fuel sucked into the first and second pressurizing chambers 51 and 52 via the suction metering valve 5, the fuel suction path 20, and the first and second suction valves 31 and 32. .
[0043]
That is, by electronically controlling the suction metering valve 5 by the pump drive signal from the ECU, the first and second pump drive current values are applied in proportion to the magnitude of the pump drive current value applied to the solenoid coil 23 via the pump drive circuit. 2 The amount of fuel sucked into the pressurizing chambers 51 and 52 is adjusted. Thus, by changing the discharge amount of the fuel discharged from the first and second pressurizing chambers 51 and 52, the combustion of each cylinder of the engine from the injector 2 mounted corresponding to each cylinder of the engine is performed. The common rail pressure (fuel pressure in the common rail 1) corresponding to the injection pressure of the fuel injected into the room can be controlled.
[0044]
[Features of the first embodiment]
As described above, the supply pump 4 used in the common rail type fuel injection system of the present embodiment has a bottomed bottom opening at the facing surface of the two washers 71 facing the inner wall surface of the cam chamber 50 of the pump housing 40. By setting the pin diameter of the straight pin 72 smaller than the hole diameter of the pin fitting hole 73, the distal end of the straight pin 72 can be gap-fitted in the pin fitting hole 73.
[0045]
Also, by setting the pin diameter of the straight pin 72 smaller than the hole diameter of the bottomed pin insertion hole 74 opened on the inner wall surface of the cam chamber 50 of the pump housing 40, the base end of the straight pin 72 can be pinned. A gap can be fitted in the insertion hole 74. Thereby, the press-fitting operation of the straight pin 72 into the pin fitting hole 73 and the press-fitting operation of the base end of the straight pin 72 into the pin insertion hole 74 can be eliminated.
[0046]
In particular, even if the base end of the straight pin 72 is inserted into the pin insertion hole 74 opened on the inner wall surface of the cam chamber 50 of the pump housing 40, the pin insertion hole 74 is inserted before the base end of the straight pin 72 is inserted. The air existing inside the cam chamber 50 passes through the gap between the outer peripheral surface of the straight pin 72 and the wall surface of the pin insertion hole 74 toward the cam chamber 50. Thus, when the supply pump 4 is operated, the straight pin 72 is moved from the pin insertion hole 74 toward the cam ring 45 in the axial direction (the thrust direction) by the air pressure of the compressed air remaining in the depth of the pin insertion hole 74 (see FIG. There is no escape in the direction of the arrow shown in a)).
[0047]
Further, the hole shape of the pin fitting holes 73 of the two washers 71 is changed from a through hole shape to a bottomed bag-shaped hole (blind hole) in which only the facing surface facing the inner wall surface of the cam chamber 50 is opened. For example, even if engine vibration is transmitted to the pump housing 40 and the straight pin 72 attempts to move in the direction of the arrow shown in FIG. 2A, the tip of the straight pin 72 becomes the tip of the straight pin 72. Is locked by the bottom wall surface 73a of the pin fitting hole 73 at a position just before contact with the end surface of the cam ring 45, so that the tip of the straight pin 72 is axially (in the thrust direction) from the pin fitting hole 73 of the washer 71. ) Does not protrude toward the cam ring 45 side.
[0048]
As a result, the distal end of the straight pin 72 protrudes from the pin fitting hole 73 of the washer 71 toward the cam ring 45 in the axial direction (thrust direction). Problems such as malfunction of the cam ring 45, and problems such as wear and damage of the cam ring 45 do not occur. Thereby, it is possible to use an inexpensive and high-strength straight pin 72 which does not need to perform an inner or outer diameter cutting process for an air release shape such as an air release groove or an air release hole. Therefore, it is possible to respond to social needs such as a further increase in fuel injection pressure and an increase in engine speed in the future.
[0049]
Further, the movement range of the two washers 71 in the axial direction (the thrust direction) is made possible by the clearance formed between the end faces of the two washers 71 and both end faces of the cam ring 45, so that the camshaft 11 and the camshaft 11 can be moved. The wear of the two plungers 41 and 42 and the wear of the cam ring 45 and the plate members 46 and 47 integrated with the two plungers 41 and 42 can be reduced.
[0050]
Here, instead of the substantially cylindrical straight pin 72 shown in FIG. 2A, a substantially frustoconical pillar-shaped straight pin 75 shown in FIG. 2B may be used. Also in this case, the pin diameters of the cylindrical portions (tip portions) 75a of the two straight pins 75 are set smaller than the hole diameters of the pin fitting holes 73 of the two washers 71. Further, the pin diameter of the tapered portion (base end) 75 b of the two straight pins 75 is set smaller than the diameter of the pin insertion hole 74 of the pump housing 40.
[0051]
Further, the hole shape of the pin fitting hole 73 of the two washers 71 is changed from a through hole shape to a blind hole shape in which only the facing surface facing the inner wall surface of the cam chamber 50 is opened. That is, by providing the bottom wall surface 73a that locks the distal end portion of the straight pin 75, the distal end portion of the straight pin 72 protrudes from the pin fitting hole 73 of the washer 71 toward the cam ring side in the axial direction (thrust direction). The tip surface of the straight pin 75 contacts and interferes with the cam ring 45, and no trouble such as damaging the cam ring 45 occurs.
[0052]
[Second embodiment]
3 and 4 show a second embodiment of the present invention. FIG. 3 is a view showing the entire structure of the supply pump, and FIGS. 4 (a) and 4 (b) show the main structure of the supply pump. FIG.
[0053]
In the present embodiment, the first discharge hole 63 of the first discharge valve 61 and the connection head of the high-pressure fuel pipe 6 are liquid-tightly connected to each other by using the first sleeve nipple 65 having the fuel pressure feed path 67 and the fastening nut 69. Connected. The fastening nut 69 is fixedly fastened to the outer peripheral portion of the first sleeve nipple 65, and a predetermined fastening between the pressure receiving seat surface of the first sleeve nipple 65 and the tapered contact surface of the connection head of the high-pressure fuel pipe 6 is performed. It is a fastener that is brought into close contact with an axial force.
[0054]
In this embodiment, a straight pin whose base end is gap-fitted in the pin insertion hole 74 of the pump housing 40 and whose tip end is gap-fitted in the pin fitting hole 77 of the two washers 71 is shown in FIG. As shown in a), a cylindrical small-diameter portion 76a is located on the right side of the stepped portion 76c in the figure, and a cylindrical large-diameter portion 76b is located on the left side of the stepped portion 76c and has a larger pin diameter than the small-diameter portion 76a. Stepped straight pin 76 having
[0055]
Further, the base end of the stepped straight pin 76 is prevented from coming out of the pin insertion hole 74 in the axial direction (thrust direction), and the tip end of the stepped straight pin 76 is inserted through the pin fitting hole 77 of the washer 71. A C-shaped clip (restriction) for locking the stepped portion 76c of the stepped straight pin 76 to the stepped portion 74a of the pin insertion hole 74 in order to prevent the protrusion from protruding toward the cam ring 45 in the axial direction (thrust direction). , A pin locking portion, and a holder) 78. The clip 78 is provided separately from the pump housing 40.
[0056]
The hole shape of the pin fitting hole 77 of each of the two washers 71 is changed from a blind hole shape to a through hole shape in which both end surfaces of the two washers 71 are open. Accordingly, even when the pin fitting holes 77 of the two washers 71 are formed into through-hole shapes, the tip of the stepped straight pin 76 projects from the pin fitting hole 77 of the washer 71 toward the cam ring 45 in the axial direction. Therefore, contact interference between the tip of the small diameter portion 76a of the stepped straight pin 76 and the end face of the cam ring 45 can be reliably prevented. Thereby, the same effect as in the first embodiment can be achieved.
[0057]
Also, instead of the C-shaped clip 78 shown in FIG. 4A, a substantially annular caulking portion (a stopping portion, a pin insertion hole 74) of the pin insertion hole 74 of the pump housing 40 as shown in FIG. By pinching the step portion 76c of the stepped straight pin 76 by caulking the pin locking portion 79, the tip end of the stepped straight pin 76 is axially (thrust direction) from the pin fitting hole 77 of the washer 71. May be prevented from protruding toward the cam ring 45 side. In this case, since the caulking portion 79 is provided integrally with the pump housing 40 and the C-shaped clip 78 is not required, the number of parts is reduced, and a more inexpensive structure can be obtained.
[0058]
[Third embodiment]
FIG. 5 shows a third embodiment of the present invention, and FIGS. 5A and 5B show the main structure of a supply pump.
[0059]
In the present embodiment, the pin fitting holes 77 of the two washers 71 are set so that the inner diameter of the pin on the pin insertion side of the washer 71 is larger than the pin diameter of the tip of the straight pin 72 as shown in FIG. Further, the inner diameter of the washer 71 on the cam ring side is set to be smaller than the diameter of the pin at the tip of the straight pin 72. That is, the hole shape of the pin fitting hole 77 of each of the two washers 71 has a substantially conical hole wall surface 77a whose inner diameter gradually decreases from the pin insertion side toward the cam ring side. Thereby, the axial movement of the straight pin 72 is restricted to the pin fitting hole 77 of the two washers 71 at a position just before the distal end of the straight pin 72 comes into contact with the end surface of the cam ring 45 (pin). Locking portion).
[0060]
Further, instead of the hole shape of the pin fitting hole 77 shown in FIG. 5A, the bottom for closing the cam ring 45 side of the pin fitting hole 73 of the first embodiment as shown in FIG. 5B. An opening 73b smaller than the pin diameter of the tip of the straight pin 72 may be opened in the wall 71a. That is, the bottom wall surface 73 a provided on the cam ring 45 side of the pin fitting hole 73 stops the movement of the straight pin 72 in the axial direction at a position before the end of the straight pin 72 comes into contact with the end surface of the cam ring 45. As long as a blocking portion (pin locking portion) can be formed, either the hole bottom may be completely closed or the hole bottom may be partially open.
[0061]
[Other embodiments]
In the present embodiment, two washers 71 are arranged between both end surfaces of the cam ring 45 and the inner wall surface of the cam chamber 50 of the pump housing 40. However, the illustrated left end surface of the cam ring 45 and the cam chamber 50 of the pump housing 40 are arranged. One washer 71 may be arranged between the inner wall surface of the cam ring 45 and the inner wall surface of the cam chamber 50 of the pump housing 40. May be.
[0062]
In the present embodiment, one washer 71 is prevented from rotating by one straight pin 72, 75 and a stepped straight pin 76, but two or more straight pins 72, 75 and one stepped straight pin 76 are used. The rotation of the two washers 71 may be implemented. Further, the pin fitting holes 73 and 77 having the stopping portions (pin locking portions) may be press-fitted and fixed to the tips of the straight pins 72 and 75 and the stepped straight pin 76. However, in this case, after the distal ends of the straight pins 72 and 75 and the stepped straight pin 76 and the washer 71 are press-fitted and fixed, the straight pins 72 and 75 are inserted into the pin insertion holes 74 of the pump housing 40 with a gap. It is desired that the washer 71 be mounted on the wall surface of the cam chamber 50 of the pump housing 40 so that the base ends of the stepped pin 75 and the stepped straight pin 76 are inserted.
[0063]
In the present embodiment, an example in which the present invention is applied to the supply pump 4 used in the common rail type fuel injection system has been described. However, the present invention is applied to a distribution type fuel injection pump or a fuel injection device used in an internal combustion engine fuel injection device. The invention may be applied to a row type fuel injection pump. Note that the number of pump elements, that is, the number of plungers, may be one or three or more.
[Brief description of the drawings]
FIG. 1 is a schematic diagram showing the entire structure of a common rail fuel injection system (first embodiment).
FIGS. 2A and 2B are cross-sectional views showing a main structure of a supply pump (first embodiment).
FIG. 3 is a cross-sectional view illustrating an entire structure of a supply pump (second embodiment).
4A is a cross-sectional view enlarging a portion A in FIG. 3, and FIG. 4B is a cross-sectional view illustrating a main structure of a supply pump (second embodiment).
FIGS. 5A and 5B are cross-sectional views showing a main structure of a supply pump (third embodiment).
FIG. 6 is a cross-sectional view showing a main structure of a supply pump (prior art).
[Explanation of symbols]
1 common rail
2 Injector (electromagnetic fuel injection valve)
3 Solenoid valve
4 Supply pump (fuel supply pump)
5 Suction metering valve (SCV)
11 Camshaft
40 pump housing
44 Exencom
45 cam ring
50 cam room
71 Washer
72 straight pin
73 pin mating hole
74 pin insertion hole
75 straight pin
76 Stepped straight pin
77 pin mating hole
78 clips (stop, pin stop, holder)
79 Caulking part (stop part, pin locking part)
73a Bottom wall surface of pin fitting hole (stop portion, pin locking portion)
73b opening
76c Step
77a Pin wall surface of pin fitting hole (restriction part, pin locking part)

Claims (8)

(A) a cam that rotates eccentrically with respect to the rotation axis of a camshaft that is driven to rotate by an internal combustion engine;
(B) a cam ring that revolves along a predetermined circular path when the cam rotates;
(C) a pump housing that internally defines a cam chamber that rotatably houses the cam and the cam ring;
(D) a washer interposed between a wall surface of the cam chamber and an end face of the cam ring for positioning the cam ring in an axial direction;
(E) a fuel supply pump having a straight pin for preventing the washer from rotating together with the cam ring;
A pin insertion hole formed in a wall surface of the cam chamber, and a base end of the straight pin is gap-fitted;
A pin fitting hole formed on the facing surface of the washer that is disposed facing the wall surface of the cam chamber, and into which the tip of the straight pin is fitted;
The straight pin is provided in at least one of the pin insertion hole and the pin fitting hole, and moves the straight pin in the axial direction at a position before the tip of the straight pin comes into contact with the end face of the cam ring. A fuel supply pump having a stopping portion for stopping. The fuel supply pump according to claim 1,
The fuel supply pump according to claim 1, wherein the stopping portion is a pin locking portion provided in the pin fitting hole and locking a tip end of the straight pin. The fuel supply pump according to claim 2,
The pin locking portion is a bottom wall surface provided in the pin fitting hole,
The fuel supply pump, wherein the bottom wall has an opening having an opening diameter smaller than a diameter of the straight pin. The fuel supply pump according to claim 2,
The pin engagement portion sets the inner diameter of the pin fitting hole on the wall surface side of the cam chamber to be larger than the pin diameter of the straight pin, and the pin fitting hole of the pin fitting hole has a larger diameter than the straight pin. A fuel supply pump formed by setting the inner diameter on the cam ring side small. The fuel supply pump according to claim 1,
The fuel supply pump according to claim 1, wherein the stopping portion is a press-fitting portion provided in the pin fitting hole and press-fitting and fixing the tip of the straight pin. The fuel supply pump according to any one of claims 1 to 5,
The straight pin is a stepped straight pin whose pin diameter on the distal end side is smaller than the pin diameter on the base end side than the stepped portion,
The fuel supply pump according to claim 1, wherein the stopping portion is a pin locking portion provided in the pin insertion hole and locking a step portion of the stepped straight pin. The fuel supply pump according to claim 6,
The fuel is characterized in that the pin locking portion is a holder provided separately from the pump housing to hold a stepped portion of the stepped straight pin in the pin insertion hole. Feed pump. The fuel supply pump according to claim 6,
The fuel supply, wherein the pin locking portion is a caulking portion provided integrally with the pump housing for caulking and fixing a step portion of the stepped straight pin in the pin insertion hole. pump.

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