JP2006233805A - Fuel injection device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To secure good start of an engine while securing satisfactory boosting action by a boosting piston. <P>SOLUTION: A common rail comprises a first common rail 2 and a second common rail 3. Fuel is supplied to the first common rail 2 from a high pressure fuel pump 9. A communication control valve 5 for opening a valve when fuel pressure in the first common rail 2 becomes higher than set pressure, is arranged between the first common rail 2 and second common rail 3. The device is equipped with a boosting piston 25 for boosting fuel injection pressure. When starting the engine, the fuel pressure of the first common rail 2 only is boosted, wherein the boosting action by the boosting piston 25 is not performed. <P>COPYRIGHT: (C)2006,JPO&NCIPI

Description

  The present invention relates to a fuel injection device.

A fuel injection valve connected to a common rail is provided, and each fuel injection valve has a booster piston for increasing the fuel injection pressure. The booster piston is coaxially arranged with a large-diameter piston and a small-diameter An intermediate chamber is formed on the end surface of the large-diameter piston on the small-diameter piston side, and this intermediate chamber is connected to either the common rail or the fuel discharge passage by a flow path switching valve. 2. Description of the Related Art A fuel injection device is known in which a fuel injection pressure is increased by discharging high-pressure fuel guided to the intermediate chamber from the intermediate chamber (see, for example, Patent Document 1).
Japanese Patent Laid-Open No. 10-238432

  By the way, in order to increase the fuel injection pressure by the pressure-increasing piston, as described above, the high-pressure fuel fed from the common rail to the intermediate chamber must be discharged from the intermediate chamber, and therefore supplied from the common rail to the fuel injection valve. The amount of fuel to be increased greatly increases as compared with a normal fuel injection device not provided with a pressure-increasing piston. In this case, if the volume of the common rail is too small, the fuel pressure in the common rail is greatly reduced when fuel injection is performed or when high-pressure fuel is sent from the common rail to the intermediate chamber. The injection pressure when the injection pressure increases will decrease. Thus, in order to prevent the injection pressure from decreasing when the injection pressure increases, the volume of the common rail must be increased. However, if the volume of the common rail is increased, it takes time to boost the pressure of the common rail fuel at the time of engine start, and thus there is a problem that good engine start cannot be ensured.

  In order to solve the above problems, according to the present invention, a fuel injection valve connected to a common rail is provided, and the fuel injection valve includes a pressure increasing piston for increasing the fuel injection pressure. In a fuel injection device in which a fuel injection pressure is increased by discharging high-pressure fuel guided to an intermediate chamber of a piston from the intermediate chamber, the common rail is separated from the first common rail and the second common rail. The high-pressure fuel is supplied from the fuel pump to the first common rail and the fuel in the first common rail is sent to the fuel injection valve. When the engine is started, the communication between the first common rail and the second common rail is cut off. Supply high-pressure fuel only from the fuel pump to the first common rail and stop the operation of the booster piston. Also the fuel pressure in the common rail so that actuate the pressure increasing piston when necessary to supply high pressure fuel to the second common rail from the fuel pump when it is determined that it should increase.

  It is possible to ensure a good start of the engine while ensuring a good fuel injection pressure increasing action by the pressure increasing piston.

  FIG. 1 schematically shows the entire fuel injection apparatus, and a portion 1 surrounded by a one-dot chain line in FIG. 1 indicates a fuel injection valve attached to the engine. As shown in FIG. 1, according to the present invention, a common rail for storing high-pressure fuel is composed of a first common rail 2 and a second common rail 3 which are separated from each other, and the first common rail 2 and the second common rail 3 are separated from each other. A communication control valve 5 is disposed in a common rail communication path 4 that communicates with the common rail 3. In the embodiment shown in FIG. 1, the communication control valve 5 can only flow from the first common rail 2 toward the second common rail 3, and the fuel pressure in the first common rail 2 is set to a predetermined pressure, For example, it comprises a pressure regulating valve that opens when the pressure exceeds 100 MPa. As shown in FIG. 1, the volume of the first common rail 2 is smaller than the volume of the second common rail 3, and fuel pressure sensors 6 and 7 are attached to the first common rail 2 and the second common rail 3, respectively. Yes.

  As shown in FIG. 1, the fuel in the fuel tank 8 is supplied into the first common rail 2 via the high-pressure fuel pump 9. The fuel pressure in the first common rail 2 is maintained at the target fuel pressure corresponding to the engine operating state by controlling the discharge amount of the high-pressure fuel pump 9, and the fuel pressure in the first common rail 2 maintained at the target fuel pressure. High-pressure fuel is supplied to the fuel injection valve 1 through the high-pressure fuel supply passage 10. Further, the fuel in the second common rail 3 is also supplied to the fuel injection valve 1 through the fuel supply passage 11.

  As shown in FIG. 1, the fuel injection valve 1 includes a nozzle portion 12 for injecting fuel into the combustion chamber, a pressure intensifier 13 for increasing the injection pressure, a two-position switching valve for switching the fuel passage, That is, a three-way valve 14 is provided. The nozzle portion 12 includes a needle valve 15, and a nozzle hole 16 (not shown) that is controlled to open and close by the tip portion of the needle valve 15 is formed at the tip of the nozzle portion 12. A nozzle chamber 17 filled with high-pressure fuel to be injected is formed around the needle valve 15, and a pressure control chamber 18 filled with fuel is formed on the top surface of the needle valve 15. A compression spring 19 is inserted in the pressure control chamber 18 to urge the needle valve 15 downward, that is, in a valve closing direction. The pressure control chamber 18 is connected to the three-way valve 14 via a fuel circulation passage 20. It is connected. The nozzle chamber 17 is connected to a fuel circulation passage 21, and the fuel circulation passage 21 is connected to the high-pressure fuel supply passage 10 via a check valve 22 that can flow only from the high-pressure fuel supply passage 10 toward the fuel circulation passage 21. It is connected.

  On the other hand, the pressure booster 13 includes a pressure boosting piston 25 including a large-diameter piston 23 and a small-diameter piston 24 which are integrally formed. A high-pressure chamber 26 filled with fuel is formed on the top surface of the large-diameter piston 23 opposite to the small-diameter piston 24, and the high-pressure chamber 26 is connected to the second common rail 3 via the fuel supply passage 11. Has been. Accordingly, the fuel pressure in the second common rail 3 is constantly acting in the high pressure chamber 26. On the other hand, an intermediate chamber 27 filled with fuel is formed on the end face of the large-diameter piston 23 around the small-diameter piston 24, and the large-diameter piston 23 faces the high-pressure chamber 26 in the intermediate chamber 27. An urging compression spring 28 is inserted. The intermediate chamber 27 is connected on the one hand to the second common rail 3 via the throttle 29 and the fuel supply passage 11, and on the other hand, the fuel circulation passage is connected to the fuel circulation passage 30b, the passage opening / closing valve 31 and the fuel circulation passage 30a. 20 is connected. A pressure increasing chamber 32 filled with fuel is formed on the end face of the small diameter piston 24 opposite to the large diameter piston 23, and the pressure increasing chamber 32 is connected to the fuel flow passage 21.

  The passage opening / closing valve 31 includes a piston 33 and a valve body 35 connected to the piston 33 and having a communication hole 34. A pressure control chamber 36 is formed on the end surface of the piston 33 opposite to the valve body 35, and the pressure control chamber 36 is connected to the second common rail 3 via fuel supply passages 37 and 11. On the other hand, a spring chamber 38 is formed on the end surface of the valve body 35 opposite to the piston 33, and a compression spring 39 for urging the valve body 35 upward is inserted into the spring chamber 38. The spring chamber 38 is also connected to the second common rail 3 through the fuel supply passages 37 and 11. A piston chamber 40 is formed on the end face of the piston 33 on the valve body 35 side. The piston chamber 40 is connected to the second common rail 3 on the one hand via a throttle 41 and fuel supply passages 37 and 11, and on the other hand, a check valve 42 that can flow only from the fuel flow passage 30 a toward the piston chamber 40. To the fuel flow passage 30a.

  On the other hand, in addition to the high pressure fuel supply passage 10 and the fuel circulation passage 20, for example, a fuel discharge passage 43 connected to the inside of the fuel tank 8 is connected to the three-way valve 14. The three-way valve 14 is driven by an actuator such as an electromagnetic solenoid or a piezoelectric element, and the fuel flow passage 20 is selectively connected to the high-pressure fuel supply passage 10 or the fuel discharge passage 43 by the three-way valve 14.

  When the operation of the engine is stopped, the fuel in the first common rail 2 and the second common rail 3 passes through a minute gap in the high-pressure fuel pump 9, the pressure intensifier 13, the passage opening / closing valve 31, or the three-way valve 14 and enters the fuel tank 8. Therefore, the fuel pressure in the first common rail 2 and the second common rail 3 gradually decreases. Next, when the operation of the engine is resumed, that is, when the engine is started and the high-pressure fuel pump 9 is driven, the fuel pressure in the first common rail 2 increases. At this time, the pressure regulating valve 5 is closed, and the first common rail 2 has a small volume, so that the fuel pressure in the first common rail 2 rises rapidly. Next, when the fuel pressure in the first common rail 2 exceeds a predetermined set pressure, the pressure regulating valve 5 is opened. As a result, the fuel in the first common rail 2 is also supplied into the second common rail 3 via the common rail communication path 4, and thus the fuel pressure in the second common rail 3 also increases.

Next, injection control when the fuel pressure in the second common rail 3 is sufficiently increased as described above, that is, injection control during normal operation will be described first.
FIG. 1 shows a case where the fuel circulation passage 20 is connected to the high-pressure fuel supply passage 10 by the fuel passage switching action by the three-way valve 14. In this case, the fuel pressure in the pressure control chamber 18 of the nozzle portion 12 is the fuel pressure in the first common rail 2 (referred to as the first common rail pressure). On the other hand, the fuel pressure in the first common rail 2 is applied to the nozzle chamber 17 of the nozzle portion 12 via the check valve 22, so the fuel pressure in the nozzle chamber 17 is also the first common rail pressure. At this time, the force of lowering the needle valve 15 by the fuel pressure in the pressure control chamber 18 and the spring force of the compression spring 18 is stronger than the force of raising the needle valve 15 by the fuel pressure in the nozzle chamber 17. Therefore, the needle valve 15 is lowered, and as a result, the needle valve 15 is closed, so that fuel injection from the nozzle 16 is stopped.

  On the other hand, at this time, the pressure in the pressure control chamber 36, the spring chamber 38, and the piston chamber 40 of the passage opening / closing valve 31 are all at the fuel pressure in the second common rail 3 (referred to as the second common rail pressure). The body 35 is in a position raised by the spring force of the compression spring 39 as shown in FIG. At this time, the valve body 35 is closed, and the communication between the fuel flow passages 30a and 30b is blocked by the valve body 35. Thus, since the valve body 35 is closed at this time, the intermediate chamber 27 of the pressure intensifier 13 has the second common rail pressure, and the high pressure chamber 26 of the pressure intensifier 13 has the second common rail pressure. On the other hand, the pressure increasing chamber 32 of the pressure booster 13 has the first common rail pressure, but the first common rail pressure and the second common rail pressure are substantially equal during normal operation. Therefore, at this time, the pressure increasing piston 25 is shown in FIG. In this way, it is held at the raised position by the spring force of the compression spring 28.

  On the other hand, when the fuel flow passage 20 is connected to the fuel discharge passage 43 by the passage switching action by the three-way valve 14, the fuel pressure in the pressure control chamber 18 of the nozzle portion 12 is lowered, so that the needle valve 15 is raised. The needle valve 15 is opened and the fuel in the nozzle chamber 17 is injected from the nozzle 16. On the other hand, at this time, the fuel in the piston chamber 40 of the passage opening / closing valve 31 flows out into the fuel circulation passage 30a via the check valve 42, and as a result, the fuel pressure in the piston chamber 40 rapidly decreases. When the fuel pressure in the piston chamber 40 decreases, the valve body 35 descends if the second common rail pressure acting in the pressure control chamber 36 at this time is higher than the valve opening pressure determined from the spring force of the compression spring 39, As a result, the fuel flow passages 30a and 30b are communicated with each other through the communication hole 34 of the valve body 35. That is, the valve body 35 is opened.

  When the valve body 35 is opened, the fuel in the intermediate chamber 27 of the pressure intensifier 13 is discharged to the fuel discharge passage 43 through the passage opening / closing valve 31. Accordingly, since the fuel pressure in the intermediate chamber 27 decreases, a large downward force acts on the pressure-increasing piston 25. As a result, the fuel pressure in the pressure-increasing chamber 32 becomes higher than the first common rail pressure. Therefore, at this time, the fuel pressure in the nozzle chamber 17 connected to the pressure increasing chamber 32 via the fuel circulation passage 21 is also higher than the first common rail pressure, and this high fuel is being consumed during fuel injection. Maintained at pressure. Therefore, when the needle valve 15 is opened, fuel is injected from the nozzle 16 with an injection pressure higher than the first common rail pressure.

  Next, when the fuel flow passage 20 is again connected to the high pressure fuel supply passage 10 as shown in FIG. 1 by the fuel passage switching action by the three-way valve 14, the pressure control chamber 18 of the nozzle portion 12 becomes the first common rail pressure, As a result, fuel injection is stopped. At this time, the pressure in the intermediate chamber 27 of the pressure booster 13 gradually becomes the second common rail pressure, the pressure in the pressure increase chamber 32 becomes the first common rail pressure, and the pressure increasing piston 25 is returned to FIG. It is held in the raised state as shown. Further, since the piston chamber 40 of the passage opening / closing valve 31 gradually becomes the second common rail pressure, the valve body 35 rises as shown in FIG. 1, and the passage opening / closing valve 31 is closed again.

  Next, injection control at the time of engine start will be described. As described above, after the engine is started, the pressure regulating valve 5 is closed before the fuel pressure in the first common rail 2 reaches a predetermined set pressure. At this time, the second common rail pressure is low, and as a result, the passage opening / closing valve 31 is held in the closed state. Accordingly, the fuel in the intermediate chamber 27 is not discharged at the time of fuel injection, and thus the fuel injection pressure is not increased by the pressure-increasing piston 25. During this time, the fuel in the first common rail 2 is injected from the fuel injection valve 1, and the fuel injection pressure at this time is the first common rail pressure.

  On the other hand, as described above, when the fuel pressure in the first common rail 2 exceeds a predetermined set pressure, the pressure regulating valve 5 is opened. In this case, if the valve opening pressure of the passage opening / closing valve 31 is set equal to or lower than the set pressure, the pressure increasing piston 25 can increase the pressure when the pressure regulating valve 5 is opened. If the valve opening pressure of the passage opening / closing valve 31 is set higher than the set pressure, the pressure increasing piston 25 can increase the pressure after the second common rail pressure becomes higher than the valve opening pressure of the passage opening / closing valve 31. It becomes.

  As described above, according to the present invention, when the engine is started, the communication between the first common rail 2 and the second common rail 3 is cut off, and high pressure fuel is supplied from the high pressure fuel pump 9 only to the first common rail 2 and the pressure is increased. The operation of the piston 25 is stopped. On the other hand, when it is determined that the fuel pressure of the second common rail 3 should be increased for a while after the engine is started, high-pressure fuel is supplied from the high-pressure fuel pump 9 to the second common rail 3 as needed. Thus, the pressure increasing piston 25 is actuated.

  When the pressure-increasing action by the pressure-increasing piston 25 is performed, the fuel of both the first common rail 2 and the second common rail 3 is used. That is, at this time, since the volume of the common rail is increased, the fuel pressure in the first and second common rails 2 and 3 is greatly reduced even if the fuel injection and the pressure increasing action by the pressure increasing piston 25 are performed. Therefore, the fuel injection pressure can be sufficiently increased. On the other hand, when the engine is started, the fuel pressure of only the common rail 2 having the smaller volume is increased, so that the fuel pressure can be increased in a short time, and thus a good start of the engine can be ensured. it can.

  FIG. 2 shows a second embodiment. In this embodiment, unlike the embodiment shown in FIG. 1, the intermediate chamber 27 of the pressure booster 13 is not connected to the second common rail 3, and is connected via the fuel circulation passage 30b, the passage opening / closing valve 31 and the fuel circulation passage 30a. It is connected only to the fuel flow passage 20. Further, in this embodiment, unlike the embodiment shown in FIG. 1, the spring chamber 38 and the piston chamber 40 of the passage opening / closing valve 31 are both connected to the fuel tank 8. Therefore, in this embodiment, when the second common rail pressure acting in the pressure control chamber 36 is lower than the valve opening pressure determined by the spring force of the compression spring 39, the passage opening / closing valve 31 is the same as in the embodiment shown in FIG. The valve is kept closed.

  On the other hand, in this embodiment, when the second common rail pressure acting in the pressure control chamber 36 becomes higher than the valve opening pressure, the passage opening / closing valve 31 is held in an open state, unlike the embodiment shown in FIG. The Therefore, in this embodiment, when the fuel circulation passage 20 is connected to the high-pressure fuel supply passage 10 as shown in FIG. 1 common rail pressure. Next, when the fuel flow passage 20 is connected to the fuel discharge passage 43 by the fuel passage switching action of the three-way valve 14, the fuel in the intermediate chamber 27 is discharged, and the pressure increasing action by the pressure increasing piston 25 is performed.

  FIG. 3 shows a third embodiment. In this embodiment, instead of the pressure regulating valve 5 shown in FIG. 1, a communication control valve capable of equalizing the first common rail pressure and the second common rail pressure when the first common rail 2 and the second common rail 3 are communicated. 5 is used. That is, the communication control valve 5 shown in FIG. 3 includes a piston 50 and a valve body 52 connected to the piston 50 and having a communication hole 51. A pressure control chamber 53 is formed on the end surface of the piston 50 opposite to the valve body 52, and the pressure control chamber 53 is connected to the first common rail 2. On the other hand, a spring chamber 54 is formed on the end surface of the valve body 52 opposite to the piston 50, and a compression spring 55 is inserted into the spring chamber 54 to urge the valve body 52 upward. A piston chamber 56 is formed on the end face of the piston 50 on the valve body 52 side. The spring chamber 54 and the piston chamber 56 are connected to the fuel tank 8.

  In this embodiment, when the first common rail pressure acting in the pressure control chamber 53 is lower than the valve opening pressure determined by the spring force of the compression spring 55, the communication control valve 5 is held in the closed state. On the other hand, when the first common rail pressure acting in the pressure control chamber 53 becomes higher than the valve opening pressure, the communication control valve 5 is held in the valve open state, and the first common rail 2 and the second common rail 3 Are communicated with each other through the communication hole 51.

  FIG. 4 shows a fourth embodiment. The difference between this embodiment and the embodiment shown in FIG. 3 is that in this fourth embodiment, a communication hole 51 for communicating the first common rail 2 and the second common rail 3 with the valve body 52 of the communication control valve 5. In addition to this, another communication hole 57 is formed. Further, in the fourth embodiment, unlike the embodiment shown in FIG. 3, the intermediate chamber 27 of the pressure intensifier 13 is not connected to the second common rail 3, and the fuel flow passage 30b, the communication control valve 5, and the fuel flow passage. It is connected only to the fuel flow passage 20 through 30a.

  In this embodiment, when the first common rail pressure acting in the pressure control chamber 53 is lower than the valve opening pressure determined by the spring force of the compression spring 55, the communication control valve 5 is held in the closed state. That is, at this time, the communication between the first common rail 2 and the second common rail 3 through the communication passage 51 is blocked, and the communication between the fuel flow passage 20 and the intermediate chamber 27 through the communication hole 57 is also blocked.

  On the other hand, when the first common rail pressure acting in the pressure control chamber 53 becomes higher than the valve opening pressure, the communication control valve 5 is held in the valve open state. That is, the first common rail 2 and the second common rail 3 are communicated with each other via the communication hole 51, and at the same time, the intermediate chamber 27 is communicated with the fuel circulation passage 20 via the communication hole 57. Accordingly, at this time, the pressure increasing action by the pressure increasing piston 25 is performed. Thus, in this embodiment, the communication control valve 5 also has the function of the passage opening / closing valve 31.

  FIG. 5 shows a fifth embodiment. In this embodiment, a communication control valve 5 having the same structure as that of the communication control valve 5 shown in FIG. 3 is arranged in the common rail communication passage 4, but in this fifth embodiment, the pressure control chamber 53 is an electromagnetic solenoid or a piezoelectric element. The first common rail 2 or the fuel tank 8 is selectively connected by a three-way valve 60 driven by such an actuator. In this embodiment, when the pressure control chamber 53 is connected to the first common rail 2 by the switching action of the three-way valve 60, the communication control valve 5 is opened, and the first common rail 2 and the second common rail 3 are connected to the communication hole. Communicating via 51. That is, in this embodiment, when it is determined that the fuel pressure of the second common rail 3 should be increased, the boosting action of the fuel pressure of the second common rail 3 can be started by switching the three-way valve 60 whenever it is determined. .

  FIG. 6 shows a sixth embodiment. In this embodiment, the pressure control chamber 18 of the needle valve 15 and the intermediate chamber 27 of the pressure increasing piston 25 are selectively connected to one of the first common rail 2 and the fuel discharge passage 43 via a three-position switching valve 70. The In this embodiment, the intermediate chamber 27 of the pressure intensifier 13 is not connected to the second common rail 3 but is connected only to the three-position switching valve 70 via the fuel flow passage 30.

  The three-position switching valve 70 includes a position where the pressure control chamber 18 of the needle valve 15 and the intermediate chamber 27 of the pressure increasing piston 25 are both connected to the first common rail 2, and the pressure control chamber 18 and the pressure increasing piston 25 of the needle valve 15. The intermediate chamber 27 is connected to the fuel discharge passage 43 together with the position where only the pressure control chamber 18 of the needle valve 15 is connected to the fuel discharge passage 43.

  When the pressure control chamber 18 of the needle valve 15 and the intermediate chamber 27 of the pressure increasing piston 25 are connected to the first common rail 2 by the switching action of the three-position switching valve 70, the needle valve 15 is closed and fuel injection is stopped. The intermediate chamber 27 has a first common rail pressure. On the other hand, when both the pressure control chamber 18 of the needle valve 15 and the intermediate chamber 27 of the pressure increasing piston 25 are connected to the fuel discharge passage 43 by the switching action of the three-position switching valve 70, the needle valve 15 opens and fuel injection is performed. At the same time, the pressure-increasing piston 25 is actuated to increase the fuel injection pressure. On the other hand, when only the pressure control chamber 18 of the needle valve 15 is connected to the fuel discharge passage 43 by the switching action of the three-position switching valve 70, the needle valve 15 is opened without operating the pressure increasing piston 25 and the fuel is discharged. Injection is performed.

1 is an overall view showing a first embodiment of a fuel injection device according to the present invention. It is a general view which shows 2nd Example of the fuel-injection apparatus by this invention. It is a general view which shows 3rd Example of the fuel-injection apparatus by this invention. It is a general view which shows 4th Example of the fuel-injection apparatus by this invention. It is a general view which shows 5th Example of the fuel-injection apparatus by this invention. It is a general view which shows 6th Example of the fuel-injection apparatus by this invention.

Explanation of symbols

DESCRIPTION OF SYMBOLS 1 Fuel injection valve 2 1st common rail 3 2nd common rail 5 Communication control valve 10 High-pressure fuel supply passage 12 Nozzle part 13 Intensifier 14 Three-way valve 15 Needle valve 18 Pressure control chamber 25 Pressure increase piston 27 Intermediate | middle chamber 31 Passage opening / closing valve 43 Fuel discharge passage

Claims (8)

  A fuel injection valve connected to the common rail, the fuel injection valve having a pressure increasing piston for increasing the fuel injection pressure, and supplying high pressure fuel led from the common rail to the intermediate chamber of the pressure increasing piston; In the fuel injection device in which the fuel injection pressure is increased by being discharged from the intermediate chamber, the common rail is composed of the first common rail and the second common rail separated from each other, and the high pressure is supplied from the fuel pump to the first common rail. The fuel in the first common rail is supplied to the fuel injection valve and the communication between the first common rail and the second common rail is cut off when the engine is started, and the high pressure fuel is supplied only from the fuel pump to the first common rail. And the operation of the booster piston should be stopped, and the fuel pressure of the second common rail should also rise for a while after the engine is started. The fuel injection system so as to actuate the pressure increasing piston when necessary to supply high pressure fuel to the second common rail from the fuel pump when it is determined that that.   2. The fuel injection according to claim 1, wherein the first common rail communicates with the second common rail via a communication control valve that opens when the fuel pressure of the first common rail exceeds a predetermined set pressure. apparatus.   The first common rail communicates with the second common rail via a communication control valve, and the communication control is performed when it is determined that the fuel pressure of the second common rail should be increased for a while after the engine is started. The fuel injection device according to claim 1, wherein the valve is opened.   The pressure control chamber of the needle valve of the fuel injection valve and the intermediate chamber of the booster piston are selectively connected to one of the first common rail and the fuel discharge passage via the two-position switching valve, and the intermediate chamber and the two-position A passage opening / closing valve is disposed between the switching valves, and when the pressure control chamber of the needle valve is connected to the first common rail by the switching action of the two-position switching valve, the needle valve is closed to stop fuel injection and When the pressure control chamber is connected to the fuel discharge passage, the needle valve is opened to perform fuel injection, and when the intermediate chamber of the pressure increasing piston is connected to the fuel discharge passage by the switching action of the two-position switching valve, If the passage opening / closing valve is closed, the operation of the pressure increasing piston is stopped. At this time, if the passage opening / closing valve is opened, the high-pressure fuel in the intermediate chamber is discharged into the fuel discharge passage to increase the pressure. Piston Injector according to claim 1 which is caused to dynamic.   5. The fuel injection device according to claim 4, wherein the passage opening / closing valve is driven by the fuel pressure of the second common rail and opens when the fuel pressure of the second common rail becomes higher than a predetermined set fuel pressure. .   A communication control valve for controlling communication between the first common rail and the second common rail is disposed between the first common rail and the second common rail, and the communication control valve also has a function of the passage opening / closing valve. The fuel injection device according to claim 4.   The pressure control chamber of the needle valve of the fuel injection valve and the intermediate chamber of the pressure increasing piston are selectively connected to either the first common rail or the fuel discharge passage via the three-position switching valve, and the three-position switching valve is switched. When the pressure control chamber of the needle valve is connected to the first common rail by the action, the needle valve is closed and the fuel injection is stopped, and the pressure control chamber of the needle valve and the pressure increasing piston are switched by the switching action of the three-position switching valve. When both of the intermediate chambers are connected to the fuel discharge passage, the needle valve is opened to perform fuel injection, and the pressure increasing piston is operated to increase the fuel injection pressure, and the needle valve is activated by the switching action of the three-position switching valve. The fuel injection is performed by opening the needle valve without operating the pressure-increasing piston when only the pressure control chamber is connected to the fuel discharge passage. Fuel injection system.   The fuel injection device according to claim 1, wherein the intermediate chamber of the boosting piston is connected to the second common rail via a throttle.

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