JP5462143B2 - Fuel injection valve - Google Patents

Description

  The present invention relates to a fuel injection valve that injects fuel for an internal combustion engine.

2. Description of the Related Art Conventionally, there is known a fuel injection valve that includes a yoke, a nozzle member, a plunger, a movable core, a fixed core, and an electromagnetic coil, and sucks the plunger by a magnetic force generated by the electromagnetic coil. For example, in the fuel injection valve described in Patent Document 1, in order to ensure a sufficient distance between the valve seat and the plunger when the valve is opened, it is necessary to increase the lift amount of the plunger. Further, the lift amount of the plunger and the magnetic gap amount between the movable core and the fixed core are the same. Therefore, when the lift amount of the plunger is increased, the magnetic gap amount is increased. Therefore, it is necessary to increase the inrush current for securing the attractive force for attracting the movable core at the start of energization of the electromagnetic coil. Increasing the inrush current increases the cost of the circuit and increases the amount of heat generated by the circuit.
Further, when the magnetic gap amount is increased, the lift amount of the movable core is increased and the required lift time is lengthened. Therefore, the stability at the time of valve opening / closing of the plunger that lifts with the movement of the movable core is lowered, and the accuracy of the valve opening / closing cycle may be lowered.

JP2008-297966

  The present invention has been made in view of the above problems, and an object of the present invention is to provide a fuel injection valve capable of achieving both improvement in accuracy of a valve opening / closing cycle and reduction in circuit cost.

  According to the invention of claim 1, the fuel injection valve includes a housing, a nozzle part, a fixed core, a passive piston part, a fixed core, a needle, a movable core, a cylinder, a first biasing member, a second biasing member, and A coil is provided. The housing is cylindrical and has a fuel passage. The nozzle portion is provided at one end of the housing and has a nozzle hole and a valve seat communicating with the fuel passage. The fixed core has a cylindrical shape and is provided on the side opposite to the nozzle portion in the housing. The needle has a rod-shaped main body in which a seal portion that can be seated on the valve seat is formed at one end portion, and a passive piston portion that is formed to extend radially outward from the other end portion of the main body. The needle is accommodated in the housing so as to be able to reciprocate, and the seal part opens or closes the nozzle hole by being seated on the valve seat or seated on the valve seat. The movable core has a drive piston portion that is formed to extend radially outward from the end on the nozzle portion side. The movable core is provided so as to be reciprocally movable between the fixed core in the housing and the needle. A cylinder is formed in the cylinder shape which can accommodate a drive piston part and a passive piston part inside. The cylinder is formed between the drive piston portion and the passive piston portion, and is formed on an intermediate oil chamber communicating with the fixed core side and the nozzle portion side of the fuel passage, on the opposite side to the intermediate oil chamber of the drive piston portion. The first oil chamber, the second oil chamber formed on the side opposite to the intermediate oil chamber of the passive piston portion, and a communication path that communicates the first oil chamber and the second oil chamber. The first biasing member is provided between the fixed core and the movable core, and biases the movable core in the valve closing direction of the needle. The second urging member urges the needle in the valve closing direction. When electric power is supplied to the coil, magnetic force is generated, and the movable core is attracted to the fixed core side.

  In the present invention, the area of the end face on the first oil chamber side of the drive piston is formed larger than the area of the end face on the second oil chamber side of the passive piston. When the movable core moves in the needle opening direction, the fuel in the first oil chamber flows out into the communication passage, and the fuel in the communication passage flows into the second oil chamber. As a result, the needle moves in the valve opening direction. When the movable core moves in the needle closing direction, the fuel in the communication passage flows into the first oil chamber, and the fuel in the second oil chamber flows into the communication passage. Thereby, the needle moves in the valve closing direction. Here, when the needle is opened, the volume of the fuel flowing out from the first oil chamber to the communication passage is determined by the area of the end surface of the drive piston on the first oil chamber side and the distance that the movable core moves in the needle opening direction. It can be expressed by the product of On the other hand, the volume of the fuel flowing into the second oil chamber from the communication passage can be represented by the product of the area of the end surface of the passive piston on the second oil chamber side and the distance the needle moves in the valve opening direction. The volume of the fuel flowing out from the first oil chamber to the communication passage is the same as the volume of the fuel flowing into the second oil chamber from the communication passage, and the area of the end surface of the drive piston on the first oil chamber side is the same as that of the passive piston. 2 Since the area of the end face on the oil chamber side is larger, the distance that the movable core moves in the needle opening direction is smaller than the distance that the needle moves in the valve opening direction.

  Thus, in the present invention, the lift amount of the movable core can be made smaller than the lift amount of the needle. Therefore, the responsiveness of the movable core is improved, and the accuracy of the valve opening / closing cycle can be increased. In addition, by reducing the lift amount of the movable core, it is possible to suppress an increase in inrush current and reduce the cost of the circuit.

  According to the invention of claim 2, the fuel injection valve includes a housing, a nozzle part, a fixed core, a passive piston part, a fixed core, a needle, a movable core, a cylinder, a first urging member, a second urging member, and A coil is provided. The housing is cylindrical and has a fuel passage. The nozzle portion is provided at one end of the housing and has a nozzle hole and a valve seat communicating with the fuel passage. The fixed core has a cylindrical shape and is provided on the side opposite to the nozzle portion in the housing. The needle has a rod-shaped main body in which a seal portion that can be seated on the valve seat is formed at one end portion, and a passive piston portion that is formed to extend radially outward from the other end portion of the main body. The needle is accommodated in the housing so as to be able to reciprocate, and the seal part opens or closes the nozzle hole by being seated on the valve seat or seated on the valve seat. The movable core has a drive piston portion that is formed to extend radially outward from the end on the nozzle portion side. The movable core is provided so as to be reciprocally movable between the fixed core in the housing and the needle. The cylinder is formed in a cylindrical shape that can accommodate the drive piston portion and the passive piston portion. The cylinder has an intermediate oil chamber formed between the drive piston portion and the passive piston portion on the inner side, a fuel passage on the opposite side of the drive piston portion from the intermediate oil chamber, and an intermediate oil chamber of the passive piston portion. A communication passage communicating with the opposite fuel passage is provided. The first biasing member is provided between the fixed core and the movable core, and biases the movable core in the valve closing direction of the needle. The second urging member urges the needle in the valve closing direction. When electric power is supplied to the coil, magnetic force is generated, and the movable core is attracted to the fixed core side.

In the present invention, the drive piston portion is formed such that the area of the end surface on the intermediate oil chamber side is larger than the area of the end surface on the intermediate oil chamber side of the passive piston portion. When the movable core moves in the needle opening direction, the needle moves in the valve opening direction because the pressure in the intermediate oil chamber decreases. Further, when the movable core moves in the needle valve closing direction, the pressure in the intermediate oil chamber increases, so that the needle moves in the valve closing direction. Here, since the area of the end face on the intermediate oil chamber side of the drive piston part is formed larger than the area of the end face on the intermediate oil chamber side of the passive piston part, the lift amount of the movable core is smaller than the lift amount of the needle. Become.
Thereby, compared with the invention according to claim 1, the same effect as that of the invention according to claim 1 can be achieved with a simpler configuration.

According to the invention which concerns on Claim 3, it has further provided the cylindrical outer piston provided so that a reciprocation between a passive piston and a cylinder is possible. The inner wall of the cylinder has a first restricting portion that restricts relative movement of the outer piston with respect to the cylinder. The outer wall of the passive piston has a second restricting portion that restricts relative movement of the outer piston with respect to the passive piston in the valve opening direction.
When the movable core moves in the needle opening direction, the needle and the outer piston move in the valve opening direction due to a change in fuel pressure in the first oil chamber and the second oil chamber or a change in fuel pressure in the intermediate oil chamber. To do. When the outer piston comes into contact with the first restricting portion, the needle and the outer piston are temporarily stopped. When the movable core further moves in the needle opening direction, only the needle moves in the valve opening direction and lifts up to the maximum lift amount of the needle.
Further, when the movable core moves in the valve closing direction of the needle, the needle moves in the valve opening direction due to a change in fuel pressure in the first oil chamber and the second oil chamber or a change in fuel pressure in the intermediate oil chamber. When the second restricting portion of the passive piston contacts the outer piston, the outer piston moves together with the needle in the valve closing direction.

  In the present invention, the lift amount of the needle can be adjusted by controlling the moving distance and moving speed of the movable core. The moving distance and moving speed of the movable core are controlled by adjusting the supply time and the magnitude of the power supplied to the coil. Therefore, the lift variation of the needle can be adjusted by adjusting the power supply time and size.

Sectional drawing of the fuel injection valve of 1st Embodiment of this invention. The principal part sectional view of the fuel injection valve of a 1st embodiment of the present invention. Sectional drawing of the fuel injection valve of 2nd Embodiment of this invention. Sectional drawing of the fuel injection valve of 3rd Embodiment of this invention. The characteristic view of the fuel injection valve of 3rd Embodiment of this invention. The characteristic view of the fuel injection valve of 3rd Embodiment of this invention. The characteristic view of the fuel injection valve of 3rd Embodiment of this invention. Sectional drawing of the fuel injection valve of 4th Embodiment of this invention.

Hereinafter, a plurality of embodiments of the present invention will be described with reference to the drawings. Note that, in a plurality of embodiments, substantially the same components are denoted by the same reference numerals, and description thereof is omitted.
(First embodiment)
A fuel injection valve according to a first embodiment of the present invention is shown in FIG. The fuel injection valve 1 is used in an internal combustion engine (not shown) and supplies fuel to the internal combustion engine.

  The fuel injection valve 1 includes a housing 10, a nozzle portion 20, a fixed core 30, a needle 40, a movable core 50, a cylinder 60, a first spring 71 as a first biasing member, and a second spring 72 as a second biasing member. And a coil 80 and the like.

  As shown in FIG. 1, the housing 10 includes a first cylinder member 11, a second cylinder member 12, a third cylinder member 13, an outer peripheral member 14, and a resin mold portion 15. The 1st cylinder member 11, the 3rd cylinder member 13, and the outer peripheral member 14 are formed, for example with magnetic materials, such as ferritic stainless steel, and the magnetic stabilization process is performed. On the other hand, the second cylinder member 12 is formed of a nonmagnetic material such as austenitic stainless steel, for example.

  The first cylinder member 11, the second cylinder member 12, and the third cylinder member 13 are all formed in a substantially cylindrical shape, and are coaxial in the order of the first cylinder member 11, the second cylinder member 12, and the third cylinder member 13. Arranged and connected to each other. The outer peripheral member 14 is provided on the radially outer side of the first cylindrical member 11, the second cylindrical member 12, and the third cylindrical member 13.

  The nozzle portion 20 is made of a metal such as martensitic stainless steel. The nozzle part 20 is formed in a substantially bottomed cylindrical shape, and has a bottom part 21 and a cylindrical part 22. The bottom portion 21 closes one end portion of the cylindrical portion 22. A nozzle hole 211 that connects the inner wall and the outer wall is formed in the bottom portion 21. An annular valve seat 212 is formed on the inner wall of the bottom 21 so as to surround the injection hole 211.

  The nozzle portion 20 is provided at the end of the first cylinder member 11 of the housing 10 opposite to the second cylinder member 12. The cylinder portion 22 is connected to the first cylinder member 11 such that the outer wall is fitted to the inner wall of the first cylinder member 11. The fitting part of the cylinder part 12 and the 1st cylinder member 11 is welded.

  The fixed core 30 is formed in a substantially cylindrical shape by a magnetic material such as ferritic stainless steel. The fixed core 30 is subjected to a magnetic stabilization process. The fixed core 30 is provided inside the housing 10. The fixed core 30 and the third cylindrical member 13 of the housing 10 are welded.

  The needle 40 is formed in a rod shape from a metal such as martensitic stainless steel. At one end portion of the rod-shaped main body 42 of the needle 40, a seal portion 41 capable of contacting the valve seat 212 is formed. Further, a passive piston portion 43 is provided on the opposite side of the main body 42 from the seal portion 41. The passive piston portion 43 is formed so as to extend radially outward from an end portion of the main body 42 opposite to the seal portion 41.

  In this embodiment, the passive piston part 43 is formed in a substantially disk shape, and an annular passive surface 431 is formed on the nozzle part 20 side. In the case of this embodiment, the passive surface 431 is formed to be perpendicular to the axial direction of the passive piston portion 43. In the case of this embodiment, the passive piston portion 43 side of the needle 40 is formed in a hollow cylindrical shape and has a long hole 44. The inner wall 441 of the long hole 44 and the outer wall 421 of the main body 42 are connected by a hole 45.

  The needle 40 is accommodated in the housing 10 so as to be capable of reciprocating in the axial direction so that the seal portion 41 and the valve seat 212 can come into contact with each other. The needle 40 opens and closes the nozzle hole 211 when the seal portion 41 is separated (separated) from the valve seat 212 or abuts (sits) the valve seat 212. Hereinafter, the direction in which the needle 40 is separated from the valve seat 212 is referred to as the valve opening direction, and the direction in which the needle 40 contacts the valve seat 212 is referred to as the valve closing direction.

  As shown in FIG. 2, the movable core 50 is formed of a magnetic material such as ferritic stainless steel so that the cross section has a substantially “work” shape, and includes a force receiving portion 51, a drive piston portion 53, and a connecting portion 52. Have

  The force receiving portion 51 is formed to extend radially outward from one end of the connecting portion 52. A contact portion 512 is formed on the end surface of the force receiving portion 51 opposite to the connecting portion 52. A hard coating is formed on the contact portion 512 by a hard coating process.

  The drive piston 53 is formed to extend radially outward from the other end of the connecting portion 52. Therefore, the drive piston portion 53 is formed with a drive surface 531 facing the force receiving portion 51. In the case of this embodiment, the drive surface 531 is formed to be perpendicular to the axial direction of the connecting portion 52. Further, the area of the drive surface 531 is formed larger than the area of the passive surface 431.

  The movable core 50 is formed in a hollow cylindrical shape along the axial direction, and has a through hole 54. The inner wall 541 of the through hole 54 and the outer wall 521 of the connecting portion 52 are connected by a hole 55.

  In the case of this embodiment, the movable core 50 is provided in the housing 10 so as to be able to reciprocate so that the force receiving portion 51 is located on the fixed core 30 side and the drive piston portion 53 is located on the needle 40 side. Movement of the movable core 50 in the valve opening direction is restricted by the fixed core 30, and movement in the valve closing direction is restricted by the protrusion 111 provided on the inner wall of the first cylinder member 11. In addition, when power is not supplied to the coil 80, a gap G having a predetermined distance in the axial direction is formed between the movable core 50 and the fixed core 30.

The cylinder 60 has a bottomed cylindrical shape and includes a first bottom portion 61, a second bottom portion 62, and a cylindrical portion 63. The first bottom 61 has a first sliding hole 611 in the center, and the second bottom has a second sliding hole 621 in the center. The cylinder part 63 is formed so that the second bottom part 62 side is thicker than the first bottom part 61 side, and a step part 631 is formed on the inner wall.
The cylinder 60 has an accommodating oil chamber 64 surrounded by a cylindrical portion 63 between the first bottom portion 61 and the second bottom portion 62. The cylinder 60 is welded to the first cylinder member 11.

  Here, the drive piston portion 53 and the passive piston portion 43 are accommodated in the accommodation oil chamber 64 so as to be slidable with the inner wall surface of the cylindrical portion 63. Therefore, a first oil chamber 641 is formed between the drive piston portion 53 and the first bottom portion 61, and a second oil chamber 642 is formed between the passive piston portion 43 and the second bottom portion 62. An intermediate oil chamber 643 is formed between the drive piston portion 53 and the passive piston portion 43. In the case of this embodiment, the first oil chamber 641 and the second oil chamber 642 are communicated with each other by a communication path 632 formed in the cylindrical portion 63. The intermediate oil chamber 643 communicates with the space on the fixed core 30 side of the cylinder 60 through the through hole 54 and the hole 55, and communicates with the space on the nozzle portion 20 side of the cylinder 60 through the hole 44.

  The coil 80 is formed in a substantially cylindrical shape and is provided so as to surround the radially outer sides of the second cylinder member 12 and the third cylinder member 13. Further, a resin mold portion 15 is filled between the second cylinder member 12, the third cylinder member 13, the outer peripheral member 14, and the coil 80. The resin mold portion 15 forms a connector portion 82 in which a part in the circumferential direction protrudes outward from the outer peripheral member 14 and an energization terminal 81 electrically connected to the coil 80 is disposed inside. The coil 80 generates a magnetic force when electric power is supplied through the connector portion 82.

  When a magnetic force is generated in the coil 80, a magnetic circuit is formed in the fixed core 30, the movable core 50, the first cylindrical member 11, the third cylindrical member 13, and the outer peripheral member 14. Thereby, the movable core 50 is attracted to the fixed core 30.

  The first spring 71 is provided such that one end is locked to the fixed core 30 and the other end is in contact with the contact portion 512 of the movable core 50. The first spring 71 has a force that extends in the axial direction. Thereby, the first spring 71 urges the movable core 50 in the valve closing direction.

  One end of the second spring 72 is in contact with the outer wall of the second bottom portion 62 of the cylinder 60, and the other end is in contact with the locking portion 46 of the needle 40. The second spring 72 urges the needle 40 in the valve closing direction by a force extending in the axial direction.

A substantially cylindrical fuel introduction pipe 16 is press-fitted and welded to the end of the third cylinder member 13 opposite to the second cylinder member 12.
The fuel that has flowed in from the inlet of the fuel introduction pipe 16 passes through the inside of the fixed core 30, the through hole 54 of the movable core 50, the intermediate oil chamber 643, the long hole 44, the hole 45, and between the first cylindrical member 11 and the needle 40. , And flows between the seal portion 41 of the needle 40 and the valve seat 212 of the nozzle portion 20, and is guided to the injection hole 211. That is, a fuel passage 101 through which fuel flows is formed inside the housing 10.

Next, the operation of the fuel injection valve 1 of the present embodiment will be described.
When power is supplied to the coil 80, the movable core 50 is attracted to the fixed core 30 by the magnetic force generated in the coil 80 and moves in the valve opening direction against the urging force of the first spring 71.
At this time, the volume of the first oil chamber 641 is reduced by the movement of the drive piston portion 53 in the valve opening direction, and a part of the fuel in the first oil chamber 641 flows out into the communication passage 632, and the inside of the communication passage 632. Part of the fuel enters the second oil chamber 642. Therefore, the fuel pressure in the second oil chamber 642 increases. Therefore, the needle 40 moves in the valve opening direction against the urging force of the second spring 72 due to the fuel pressure in the second oil chamber 642. When the seal portion 41 of the needle 40 is separated from the valve seat 212, the injection hole 211 is opened and fuel injection is started.

  When the power supply to the coil 80 is stopped, the suction force for sucking the movable core 50 disappears, and the movable core 50 is pushed in the valve closing direction by the urging force of the first spring 71 and moves in the valve closing direction. At this time, the volume of the first oil chamber 641 is expanded by the movement of the drive piston portion 53 in the valve closing direction. Therefore, a part of the fuel in the communication path 632 flows into the first oil chamber 641 and a part of the fuel in the second oil chamber 642 flows into the communication path 632. As a result, the pressure of the fuel in the second oil chamber 642 decreases, and the needle 40 moves in the valve closing direction by the urging force of the second spring 72. When the seal portion 41 of the needle 40 is seated on the valve seat 212, the nozzle 211 is closed and fuel injection is stopped.

Here, if the area of the drive surface 531 of the drive piston portion 53 is S1, and the area of the passive surface 431 of the passive piston portion 43 is S2, S1> S2 Formula 1
It is.
Further, when the needle 40 is opened, the moving distance when the movable core 50 moves in the valve opening direction is L1, and the moving distance when the needle 40 is moved in the valve opening direction is L2, the first oil chamber 641. The volume V1 of the fuel flowing out from the fuel and the volume V2 of the fuel flowing into the second oil chamber 642 are expressed by the following formulas 1 and 2.
V1 = S1 × L1 Formula 2
V2 = S2 × L2 Equation 3

In the present embodiment, since the first oil chamber 641 and the second oil chamber 642 communicate with each other through the communication path 632, V1 = V2. Therefore,
S1 × L1 = S2 × L2 Equation 4
It is.
From the above formulas 1 and 4, the moving distance L1 in which the movable core 50 moves in the valve opening direction is smaller than the moving distance L2 in which the needle 40 moves in the valve opening direction. Therefore, even if the axial distance G between the movable core 50 and the fixed core 30 is set to be smaller than the lift amount of the needle 40, the distance between the valve seat 212 and the seal portion 41 when the valve is opened can be secured. it can. Further, by reducing the axial distance G between the movable core 50 and the fixed core 30, the responsiveness of the movable core 50 can be improved and the accuracy of the valve opening / closing cycle of the needle 40 can be increased. Further, by reducing the lift amount of the movable core 50, an increase in inrush current can be suppressed and the cost of the circuit can be reduced.

(Second Embodiment)
The fuel injection valve of 2nd Embodiment is shown in FIG. Constituent parts that are substantially the same as in the above embodiment are given the same reference numerals, and descriptions thereof are omitted.
As shown in FIG. 3, in the present embodiment, the force receiving portion 51 side of the movable core 56 is formed in a hollow cylindrical shape and has a passage 57. The passage 57 has a hole 55 between the force receiving portion 51 and the drive piston portion 53.

The needle 47 has a solid cylindrical shape. In the present embodiment, the area of the end surface 432 on the intermediate oil chamber 644 side of the passive piston portion 43 is formed smaller than the area of the end surface 532 on the intermediate oil chamber 644 side of the drive piston portion 53 of the movable core 56.
The cylinder 65 has a cylindrical shape, and a stepped portion 631 is formed on the inner wall. The cylinder 65 has a communication path 633.

  Here, an intermediate oil chamber 644 surrounded by a cylinder 65 is formed between the drive piston portion 53 of the movable core 56 and the passive piston portion 43 of the needle 47. The intermediate oil chamber 644 is a sealed space surrounded by the drive piston portion 53, the passive piston portion 43, and the cylinder 65. The volume of the intermediate oil chamber 644 can be increased or decreased by the movement of the drive piston portion 53 or the passive piston portion 43.

  The fuel that has flowed from the introduction port of the fuel introduction pipe 16 flows between the fixed core 30, the passage 57 of the movable core 56, the communication passage 633, between the first cylinder member 11 and the needle 47, and between the seal portion 41 and the nozzle of the needle 47. It circulates between the valve seat 212 of the part 20 and is guided to the nozzle hole 211. That is, a fuel passage 102 through which fuel flows is formed inside the housing 10.

  Here, one end of the communication passage 633 of the cylinder 65 is opened to the side opposite to the intermediate oil chamber 644 of the drive piston portion 53, and the other end is opened to the side opposite to the intermediate oil chamber 644 of the passive piston portion 43. Yes. The communication passage 633 communicates the side of the fuel passage 102 opposite to the intermediate oil chamber 644 of the drive piston portion 53 and the side of the passive piston portion 43 opposite to the intermediate oil chamber 644.

Next, the operation of the fuel injection valve 2 of the present embodiment will be described.
When power is supplied to the coil 80, the movable core 56 is attracted to the fixed core 30 by the magnetic force generated in the coil 80 and moves in the valve opening direction against the urging force of the first spring 71.
At this time, when the pressure of the fuel in the intermediate oil chamber 644 decreases due to the expansion of the volume of the intermediate oil chamber 644, the needle 47 resists the urging force of the second spring 72 by the fuel pressure in the fuel passage 102. Move in the valve opening direction. As a result, the seal portion 41 of the needle 47 is separated from the valve seat 212, whereby the injection hole 211 is opened and fuel injection is started.

When the power supply to the coil 80 is stopped, the suction force for sucking the movable core 56 disappears, and the movable core 56 is pushed in the valve closing direction by the urging force of the first spring 71 and moves in the valve closing direction.
At this time, when the pressure of the fuel in the intermediate oil chamber 644 increases due to the volume of the intermediate oil chamber 644 being reduced, the needle 47 is caused by the fuel pressure in the intermediate oil chamber 644 and the biasing force of the second spring 72. Move in the valve closing direction. When the seal portion 41 of the needle 47 is seated on the valve seat 212, the injection port 211 is closed and fuel injection is stopped.

Here, assuming that the area of the end surface 532 on the intermediate oil chamber 644 side of the drive piston 53 is S3 and the area of the end surface 432 on the intermediate oil chamber 644 side of the passive piston portion 43 of the needle 47 is S4, S3> S4. Formula 5
It is.
When the needle 47 is opened, the moving distance when the movable core 56 moves in the valve opening direction is L3, and the moving distance when the needle 47 moves in the valve opening direction is L4. Of the volumes, the volume V3 that changes due to the movement of the drive piston portion 53 and the volume V4 that changes due to the movement of the passive piston portion 43 are expressed by the following equations 6 and 7.
S3 × L3 = V3 Expression 6
S4 × L4 = V4 Expression 7

In the present embodiment, since the intermediate oil chamber 644 is a sealed space, V3 = V4. Therefore,
S3 × L3 = S4 × L4 Equation 8
It is.
From the above formulas 5 and 6, the moving distance L3 in which the movable core 56 moves in the valve opening direction is smaller than the moving distance L4 in which the needle 47 moves in the valve opening direction. Therefore, the axial distance G between the movable core 56 and the fixed core 30 can be set smaller than the lift amount of the needle 47.

  In the present embodiment, the same effects as in the first embodiment can be achieved. Furthermore, in this embodiment, compared with the said 1st Embodiment, component cost can be reduced by providing the cylinder 65 of a simpler structure.

(Third embodiment)
The fuel injection valve of 3rd Embodiment is shown in FIG. Components that are substantially the same as those in the first embodiment are given the same reference numerals, and descriptions thereof are omitted. In the present embodiment, a cylindrical outer piston 90 is provided between the cylinder 66 and the needle 48.

As shown in FIG. 4, the cylinder 66 includes a first bottom portion 61, a second bottom portion 62, and a cylindrical portion 63 that are the same as those in the first embodiment. A first restricting portion 634 is formed on the inner wall of the cylinder portion 63 of the cylinder 66 so as to protrude radially inward. The first restricting portion 634 is formed closer to the nozzle portion 20 side in the axial direction than the first bottom portion 61. Here, the outer piston 90 is provided on the nozzle part 20 side of the first restricting part 634. The outer piston 90 has an outer wall that can slide with the inner wall of the cylinder 66, and an inner wall that is slidable with the outer wall of the passive piston 43.
The needle 48 has a second restricting portion 433 that is formed to extend radially outward from the end of the passive piston portion 43 opposite to the main body 42.

Next, the operation of the fuel injection valve 3 of the present embodiment will be described based on FIGS. 4 and 5.
If the sectional area of the outer piston 90 is Sa and the resultant force acting on the needle 40 in the valve closing direction is Fc, the fuel pressure in the first oil chamber 641 and the second oil chamber 642 (hereinafter referred to as “actuation”). P) (referred to as “hydraulic pressure”) satisfies the following formula 9. Here, the force in the valve opening direction that the drive hydraulic pressure P acts on the needle 40 is defined as Fp.
P × (S2 + Sa) = Fp <Fc Equation 9

  FIG. 5 shows a graph in which the lift amount of the needle 48 of the present embodiment changes with time. As shown in FIG. 5, when the command value is turned ON and the inrush current command value and the constant current control command value are turned ON, the inrush current and the constant current are supplied to the coil 80. The movable core 50 is attracted by the fixed core 30 and starts moving in the valve opening direction against the biasing force of the spring 71 at time T0.

At this time, the volume of the first oil chamber 641 is reduced by the drive piston 53 moving in the valve opening direction. Accordingly, the hydraulic pressure P increases, and the passive piston 43 and the outer piston 90 are urged in the valve opening direction by the pressure of the fuel in the second oil chamber 642. When the operating oil pressure P satisfies the following expression 10, the needle 40 moves in the valve opening direction against the urging force of the second spring 72 at time T1 due to the pressure of the fuel in the second oil chamber 642.
P × (S2 + Sa) = Fp>Fc> Fo Formula 10

When the seal portion 41 of the needle 40 is separated from the valve seat 212, the injection hole 211 is opened and fuel injection is started. Here, since the working oil pressure P satisfies the following expression 11, when the outer piston 90 comes into contact with the first restricting portion 634 of the cylinder 66, the needle 48 and the outer piston 90 are temporarily stopped at time T2. Here, Fo is a resultant force that acts on the needle 40 in the valve closing direction when the valve is opened.
P × S2 = Fp <Fo Formula 11
When the hydraulic pressure P satisfies the following expression 12 due to the movement of the movable core 50 in the valve opening direction, the needle 48 starts moving again in the valve opening direction at time T3.
P × S2 = Fp> Fo Equation 12
When the movable core 50 and the fixed core 30 come into contact with each other, the needle 48 is lifted to the maximum lift amount at time T4.

  When the command value is turned off and the constant current control command value is turned off, the power supply to the coil 80 is stopped. Therefore, the suction force for sucking the movable core 50 disappears, and the movable core 50 is pushed in the valve closing direction and moved in the valve closing direction by the urging force of the first spring 71 at time T5.

  At this time, the drive piston portion 53 moves in the valve closing direction, whereby the volume of the first oil chamber 641 increases and the hydraulic pressure P decreases. Therefore, the passive piston 43 is urged in the valve closing direction by the fuel pressure in the intermediate oil chamber 643 and the urging force of the second spring 72. When the operating oil pressure P satisfies the above expression 11, the needle 40 moves in the valve closing direction at time T6. When the second restricting portion 433 of the passive piston portion 43 comes into contact with the outer piston 90 at time T7, the outer piston 90 moves together with the needle 48 in the valve closing direction. When the seal portion 41 of the needle 48 is seated on the valve seat 212 at time T8, the nozzle hole 211 is closed.

  In the present embodiment, an outer piston 90 is provided between the needle 48 and the cylinder 66. Thereby, the lift amount of the needle 48 can be controlled stepwise. As shown in FIG. 5, the needle begins to lift at T1, and stops once at T2. Then, the needle starts to lift again at T3 and lifts to the maximum lift amount at T4. As described above, the fuel injection valve 3 of the present embodiment can perform minute injection by temporarily stopping the needle between T2 and T3.

  FIG. 6 shows a graph in which the lift amount of the needle 48 changes with time when the lift amount of the needle 48 is controlled by reducing the ON time of the command value. As shown in FIG. 6, when the ON time of the command value is shortened, the needle 48 starts to lift at time T11 and temporarily stops at time T12. Then, the needle 48 starts to drop at time T13. That is, in this example, the needle 48 is temporarily stopped between time T12 and time T13, and is closed without reaching the maximum lift amount. Thereby, the micro injection of fuel can be performed.

  FIG. 7 shows a graph in which the lift amount of the needle 48 changes with time when the lift amount of the needle 48 is controlled by increasing the inrush current. As shown in FIG. 7, when the inrush current is increased, the needle 48 starts to lift at time T21, temporarily stops at time T22, starts to lift again at time T23, and lifts to the maximum lift amount at time T24. . In this example, the needle 48 is temporarily stopped between time T22 and time T23, and the time for which the needle 48 is temporarily stopped is shortened as compared with the case where the inrush current is not increased. Therefore, by increasing the inrush current, the time during which the needle 48 is lifted to the maximum lift amount can be shortened.

  Thus, in this embodiment, the lift amount of the needle 48 can be adjusted by adjusting the ON time of the command value and the magnitude of the inrush current. Therefore, by adjusting the command value and the solenoid current, it is possible to give different variations in the manner of injection of the fuel injection valve 3.

(Fourth embodiment)
The fuel injection valve of 4th Embodiment is shown in FIG. Constituent parts that are substantially the same as those of the second and third embodiments are given the same reference numerals, and descriptions thereof are omitted. As shown in FIG. 8, in the present embodiment, a cylindrical outer piston 90 is provided between the cylinder 67 and the needle 47.

  The cylinder 67 has a substantially cylindrical shape, and a first restricting portion 634 is formed on the inner wall. The outer piston 90 is provided on the nozzle part 20 side of the first restriction part 634 in the axial direction so as to be slidable with the cylinder 67 and the needle 47.

  A spring stop member 73 is provided between the end portion of the cylinder 67 on the nozzle portion 20 side and the first cylinder member 11. The second spring 72 is provided between the spring stopping member 73 and the locking portion 46 and biases the needle 47 in the valve closing direction.

Next, the operation of the fuel injection valve 4 of this embodiment will be described.
When electric power is supplied to the coil 80, the movable core 56 is attracted by the fixed core 30 and moves in the valve opening direction against the urging force of the first spring 71.

  At this time, the volume of the intermediate oil chamber 644 increases, so that the pressure of the fuel in the intermediate oil chamber 644 decreases. The needle 47 moves in the valve opening direction together with the outer piston 90 against the urging force of the second spring 72 by the fuel pressure in the fuel passage 102. Accordingly, when the seal portion 41 of the needle 48 is separated from the valve seat 212, the injection hole 211 is opened, and fuel injection is started. Here, when the outer piston 90 comes into contact with the first restricting portion 634 of the cylinder 67, the needle 47 and the outer piston 90 are temporarily stopped. When the pressure of the fuel in the intermediate oil chamber 644 further decreases, only the needle 47 starts to move again in the valve opening direction due to the fuel pressure in the fuel passage 102.

When the power supply to the coil 80 is stopped, the suction force for sucking the movable core 56 disappears, and the movable core 56 is pushed in the valve closing direction by the urging force of the first spring 71 and moves in the valve closing direction.
At this time, when the pressure of the fuel in the intermediate oil chamber 644 increases due to the volume of the intermediate oil chamber 644 being reduced, the needle 47 is caused by the fuel pressure in the intermediate oil chamber 644 and the biasing force of the second spring 72. Move in the valve closing direction. When the second restricting portion 433 of the passive piston portion 43 contacts the outer piston 90, the outer piston 90 moves together with the needle 47 in the valve closing direction. When the seal portion 41 of the needle 47 is seated on the valve seat 212, the injection port 211 is closed and fuel injection is stopped.

In the present embodiment, as in the second embodiment, the component cost can be reduced by providing the cylinder 67 having a simpler structure as compared with the first embodiment.
Further, in the present embodiment, as in the third embodiment, by adjusting the ON time of the command value and the magnitude of the inrush current, it is possible to have different variations in the injection method of the fuel injection valve 4. .

  The present invention described above is not limited to the above-described embodiment, and can be applied to various embodiments without departing from the gist thereof.

DESCRIPTION OF SYMBOLS 1 ... Fuel injection valve 10 ... Housing 20 ... Nozzle part 30 ... Fixed core 40 ... Needle 41 ... Seal part 42 ... Main body 43 ... Passive piston part 50 ...・ Movable core 60 ・ ・ ・ Cylinder 71 ・ ・ ・ First spring 72 ・ ・ ・ Second spring 80 ・ ・ ・ Coil 101 ・ ・ ・ Fuel passage 211 ・ ・ ・ Injection hole 212 ・ ・ ・ Valve seat 643 ・ ・ ・ Intermediate Oil chamber 641 ... 1st oil chamber 642 ... 2nd oil chamber 632 ... Communication path

Claims (3)

A cylindrical housing having a fuel passage;
A nozzle portion provided at one end of the housing and having a nozzle hole and a valve seat communicating with the fuel passage;
A cylindrical fixed core provided on the opposite side to the nozzle portion in the housing;
A rod-shaped main body that is accommodated in the housing so as to be reciprocally movable and can be seated on the valve seat is formed at one end, and is formed to extend radially outward from the other end of the main body. A needle that opens and closes the nozzle hole when the seal portion is separated from the valve seat or seated on the valve seat;
A movable core having a drive piston portion that is provided so as to be reciprocally movable between the fixed core and the needle in the housing and is formed to extend radially outward from an end portion on the nozzle portion side;
It is formed in the inside which can accommodate the drive piston part and the passive piston part inside, and is formed between the drive piston part and the passive piston part, and the fixed core side of the fuel passage and the nozzle part An intermediate oil chamber communicating with the side, a first oil chamber formed on the opposite side of the drive piston portion from the intermediate oil chamber, and a second oil formed on the opposite side of the passive piston portion from the intermediate oil chamber. A cylinder, and a cylinder having a communication passage communicating the first oil chamber and the second oil chamber;
A first biasing member that is provided between the fixed core and the movable core and biases the movable core in the valve closing direction of the needle;
A second urging member for urging the needle in the valve closing direction;
A magnetic force is generated when electric power is supplied, and a coil for attracting the movable core to the fixed core side is provided.
The area of the end surface on the first oil chamber side of the drive piston is formed larger than the area of the end surface on the second oil chamber side of the passive piston,
When the movable core moves in the valve opening direction of the needle, the fuel in the first oil chamber flows into the second oil chamber through the communication path, so that the needle moves in the valve opening direction,
When the movable core moves in the valve closing direction of the needle, the fuel in the second oil chamber flows into the first oil chamber through the communication path, so that the needle moves in the valve closing direction. Fuel injection valve. A cylindrical housing having a fuel passage;
A nozzle portion provided at one end of the housing and having a nozzle hole and a valve seat communicating with the fuel passage;
A cylindrical fixed core provided on the opposite side to the nozzle portion in the housing;
A rod-shaped main body that is accommodated in the housing so as to be reciprocally movable and can be seated on the valve seat is formed at one end, and is formed to extend radially outward from the other end of the main body. A needle that opens and closes the nozzle hole when the seal portion is separated from the valve seat or seated on the valve seat;
A movable core having a drive piston portion that is provided so as to be reciprocally movable between the fixed core and the needle in the housing and is formed to extend radially outward from an end portion on the nozzle portion side;
An intermediate oil chamber formed between the drive piston portion and the passive piston portion, formed in a cylindrical shape capable of accommodating the drive piston portion and the passive piston portion on the inside, and the middle of the drive piston portion A cylinder having a communication passage communicating the fuel passage on the side opposite to the oil chamber and the fuel passage on the side opposite to the intermediate oil chamber of the passive piston portion;
A first biasing member that is provided between the fixed core and the movable core and biases the movable core in the valve closing direction of the needle;
A second urging member for urging the needle in the valve closing direction;
A magnetic force is generated when electric power is supplied, and a coil for attracting the movable core to the fixed core side is provided.
The drive piston part is formed such that the area of the end face on the intermediate oil chamber side is larger than the area of the end face on the intermediate oil chamber side of the passive piston part,
When the movable core moves in the valve opening direction of the needle, the needle moves in the valve opening direction as the pressure in the intermediate oil chamber decreases,
The fuel injection valve according to claim 1, wherein when the movable core moves in the valve closing direction of the needle, the needle moves in the valve closing direction due to an increase in pressure in the intermediate oil chamber. A cylindrical outer piston provided to be reciprocally movable between the passive piston and the cylinder;
The inner wall of the cylinder has a first restricting portion that restricts relative movement of the outer piston relative to the cylinder,
3. The fuel injection valve according to claim 1, wherein an outer wall of the passive piston has a second restricting portion that restricts relative movement of the outer piston in the valve opening direction with respect to the passive piston.

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