JP6547885B2 - Fuel injection device - Google Patents

Description

  The present invention relates to a fuel injection device for injecting and supplying fuel to an internal combustion engine.

  In recent years, the need for a fuel injection device capable of injecting high pressure fuel is increasing. Therefore, when using the fuel injection device, the pressure of fuel in the fuel passage in the device tends to increase. In the fuel injection device described in Patent Document 1, the nozzle holder that constitutes a part of the housing is press-fit into the fixed core. The fixed core and the nozzle holder are joined by welding at a press-fit position. Further, a magnetic throttling portion having a thin portion is formed in the nozzle holder, and the magnetic throttling portion is press-fit into the fixed core and is joined to the fixed core by welding.

JP, 2014-227958, A

  In the fuel injection device of Patent Document 1, when the pressure of the fuel in the fuel passage in the device becomes high, the fixed core and the nozzle holder are axially arranged in the welded portion of the fixed core and the nozzle holder or in the thin magnetic throttle portion. A force in the direction of leaving acts. When the pressure of the fuel in the fuel passage in the device becomes excessive, stress may be concentrated on the welding portion or magnetic throttling portion between the fixed core and the nozzle holder, and the welding portion or magnetic throttling portion may be broken. If the welding portion or the magnetic throttling portion breaks, the fuel in the fuel passage may leak to the outside. Therefore, in the fuel injection device of Patent Document 1, it is difficult to inject high-pressure fuel due to its structure.

  Further, in the fuel injection device of Patent Document 1, when the pressure of the fuel in the fuel passage in the device becomes excessive, the position of the magnetic throttling portion with respect to the fixed core shifts in the axial direction, and occurs between the fixed core and the movable core. The magnitude of the magnetic attraction may vary. As a result, the fuel injection accuracy may be reduced.

  The present invention has been made in view of the above-mentioned problems, and an object thereof is to provide a fuel injection device capable of injecting high-pressure fuel with high accuracy while suppressing fuel leakage.

The fuel injection device (1) of the present invention comprises a nozzle, a housing, a needle, a movable core, a fixed core, a valve seat biasing member, a yoke, and a coil.
The nozzle (10) has an injection hole (13) into which fuel is injected, and a valve seat (14) annularly formed around the injection hole.

  The housing (20) has a first annular portion (21) whose one end is connected to the nozzle, one end is connected to the other end of the first annular portion, and a magnetic throttling portion (221) at least at a part in the axis (Ax1) direction. The second annular portion (22) to be formed, the third annular portion (23) having one end connected to the other end of the second annular portion, and the first annular portion, the second annular portion and the second portion communicating with the injection hole It has a fuel passage (100) formed inside the three annular portions and guiding the fuel to the injection hole.

The needle (30) has a rod-like needle body (31), and a seal portion (32) annularly formed at one end of the needle body so as to be able to abut the valve seat, and the seal portion is separated from the valve seat Or when it abuts on the valve seat, it opens and closes the injection hole.
The movable core (40) is provided to be reciprocally movable in the housing together with the needle.
The fixed core (50) is provided on the opposite side to the valve seat with respect to the movable core.
The valve seat side biasing member (71) can bias the needle and the movable core toward the valve seat.

  The yoke (90, 901, 902) is formed in a tubular shape, one end side is connected to the first annular portion, the other end side is connected to the third annular portion, and the first annular portion and the third annular portion are first annular A state in which an axial force (F1) is generated in a direction in which the second portion and the third annular portion approach each other, and a force in a direction in which the second annular portion contracts in the axial direction from the first annular portion and the third annular portion It is provided in the radial direction outer side of the 2nd annular part so that it may become.

  The coil (80) is provided between the second annular portion and the yoke, and when energized, forms a magnetic circuit in the first annular portion, the movable core, the fixed core, the third annular portion, and the yoke to form the movable core. It is possible to aspirate on the fixed core side and move the needle opposite to the valve seat.

  In the present invention, the yoke is provided such that an axial force in the direction in which the first annular portion and the third annular portion approach each other is generated in the first annular portion and the third annular portion. Therefore, a force in a direction in which the first annular portion and the third annular portion contract in the axial direction acts on the second annular portion forming the magnetic throttling portion. Thereby, even if the pressure of the fuel in the fuel passage becomes high, the connection between the second annular portion and the first annular portion, the connection between the second annular portion and the third annular portion, or the magnetic throttle portion It is possible to suppress the acting "force in the direction in which each member is separated in the axial direction". Therefore, it is possible to suppress stress concentration and breakage at the connection portion between the second annular portion and the first annular portion, the connection portion between the second annular portion and the third annular portion, or the magnetic throttling portion. Therefore, in the present invention, high pressure fuel can be injected while suppressing fuel leakage.

  Further, in the present invention, since the force in the direction in which the first annular portion and the third annular portion axially contract is applied to the second annular portion forming the magnetic throttle portion, the pressure of the fuel in the fuel passage Can be suppressed from being displaced in the axial direction with respect to the fixed core. Therefore, the magnitude of the magnetic attraction force generated between the fixed core and the movable core can be suppressed from fluctuating. Thereby, the fall of the injection accuracy of fuel can be controlled.

  As described above, in the fuel injection device of the present invention, high-pressure fuel can be injected with high accuracy while suppressing fuel leakage.

FIG. 1 is a cross-sectional view showing a fuel injection device according to a first embodiment of the present invention. Sectional drawing which shows the fuel inlet part of the fuel injection apparatus by 1st Embodiment of this invention, and its vicinity. Sectional drawing which shows the yoke of the fuel-injection apparatus by 1st Embodiment of this invention, and its vicinity. IV-IV sectional view taken on the line of FIG. Sectional drawing which shows the 3rd annular part protrusion part of the fuel-injection apparatus by 2nd Embodiment of this invention, and its vicinity. Sectional drawing which shows the 3rd annular part protrusion part of the fuel-injection apparatus by 3rd Embodiment of this invention, and its vicinity. Sectional drawing which shows the yoke of the fuel-injection apparatus by 4th Embodiment of this invention, and its vicinity. Sectional drawing which shows the yoke of the fuel-injection apparatus by 5th Embodiment of this invention, and its vicinity. Sectional drawing which shows the yoke of the fuel-injection apparatus by 6th Embodiment of this invention, and its vicinity. Sectional drawing which shows the yoke of the fuel-injection apparatus by 7th Embodiment of this invention, and its vicinity. Sectional drawing which shows the yoke of the fuel-injection apparatus by 8th Embodiment of this invention, and its vicinity.

Hereinafter, a plurality of embodiments of the present invention will be described based on the drawings. In addition, in several embodiment, the same code | symbol is attached | subjected to a substantially identical component, and description is abbreviate | omitted.
First Embodiment

  A fuel injection valve according to a first embodiment of the present invention is shown in FIG. The fuel injection device 1 is used, for example, in a direct injection gasoline engine (hereinafter, referred to as “engine”) 2 as an internal combustion engine, and injects and supplies gasoline as fuel to the engine 2.

  The fuel injection device 1 includes a nozzle 10, a housing 20, a needle 30, a movable core 40, a fixed core 50, a gap forming member 60, a spring 71 as a valve seat biasing member, a coil 80, a yoke 90, an inlet 24 and a filter. A cylindrical member 25 and a screw coupling member 26 are provided.

The nozzle 10 is made of, for example, a material having a relatively high hardness such as martensitic stainless steel. The nozzle 10 is subjected to hardening treatment so as to have a predetermined hardness. The nozzle 10 has a nozzle cylinder 11 and a nozzle bottom 12 that closes one end of the nozzle cylinder 11. A plurality of injection holes 13 connecting the surface on the nozzle cylinder 11 side and the surface on the opposite side of the nozzle cylinder 11 are formed in the nozzle bottom 12. Further, an annular valve seat 14 is formed around the injection hole 13 on the surface of the nozzle bottom 12 on the nozzle cylinder 11 side.
The housing 20 has a first cylindrical portion 21, a second cylindrical portion 22, a third cylindrical portion 23, and the like.

  The first cylindrical portion 21, the second cylindrical portion 22 and the third cylindrical portion 23 are all formed in a substantially cylindrical shape. The first cylindrical portion 21, the second cylindrical portion 22, and the third cylindrical portion 23 are arranged to be coaxial (shaft Ax1) in the order of the first cylindrical portion 21, the second cylindrical portion 22, and the third cylindrical portion 23, and Connected The second cylindrical portion 22 and the first cylindrical portion 21 and the third cylindrical portion 23 are connected, for example, by welding. In FIG. 1, a connecting portion between the second cylindrical portion 22 and the first cylindrical portion 21 is denoted by c1 and a connecting portion between the second cylindrical portion 22 and the third cylindrical portion 23 is denoted by c2. In the connection portion c1, a melted portion w1 is formed, in which a part of the second cylindrical part 22 and a part of the first cylindrical part 21 are melted and solidified by cooling. Further, in the connection portion c2, a melted portion w2 is formed, in which a part of the second cylindrical part 22 and a part of the third cylindrical part 23 are melted and solidified by cooling.

  The first cylindrical portion 21 and the third cylindrical portion 23 are made of, for example, a magnetic material such as ferritic stainless steel, and are subjected to a magnetic stabilization process. The first cylindrical portion 21 and the third cylindrical portion 23 have relatively low hardness. On the other hand, the second cylindrical portion 22 is formed of a nonmagnetic material such as austenitic stainless steel, for example. That is, the second cylindrical portion 22 forms the magnetic throttling portion 221 in the entire axial direction. The hardness of the second cylindrical portion 22 is higher than the hardness of the first cylindrical portion 21 and the third cylindrical portion 23.

  The end of the nozzle cylinder 11 opposite to the nozzle bottom 12 is joined to the inside of the end of the first cylinder 21 opposite to the second cylinder 22. The first cylindrical portion 21 and the nozzle 10 are connected, for example, by welding. In FIG. 1, a connecting portion between the first cylindrical portion 21 and the nozzle 10 is indicated by c3. In the connection portion c3, a melted portion w3 is formed in which a part of the first cylindrical portion 21 and a part of the nozzle 10 are melted, cooled and solidified by welding.

  The inlet portion 24 is formed in a tubular shape, for example, by a metal such as stainless steel. The inlet portion 24 is provided such that one end thereof is connected radially inward of an end portion of the third cylindrical portion 23 opposite to the second cylindrical portion 22. In the present embodiment, the inlet portion 24 and the third cylindrical portion 23 are integrally formed of the same material. In FIG. 1, the boundary between the inlet 24 and the third cylindrical portion 23 is indicated by a two-dot chain line.

The cylindrical member 25 is provided on the opposite side of the third cylindrical portion 23 of the inlet portion 24. The cylindrical member 25 is formed in a cylindrical shape, for example, by a metal such as stainless steel. The cylindrical member 25 is provided such that one end is connected to the outside in the radial direction of the end of the inlet 24 opposite to the third cylindrical portion 23. In the present embodiment, the cylindrical member 25 and the inlet 24 are connected, for example, by welding. In FIG. 1, a connecting portion between the cylindrical member 25 and the inlet portion 24 is indicated by c4. In the connection portion c4, a melted portion w4 is formed in which a part of the cylindrical member 25 and a part of the inlet 24 are melted and cooled by welding.
A threaded portion 251 is formed on the outer wall of the end portion of the cylindrical member 25 opposite to the inlet portion 24.

  A fuel pipe 6 through which fuel from the outside flows is connected to an end of the cylindrical member 25 opposite to the inlet 24. At an end portion of the fuel pipe 6 on the cylinder member 25 side, a protruding portion 7 that protrudes annularly outward in the radial direction is formed. A locking surface 8 is formed on the end face of the protrusion 7 opposite to the cylindrical member 25.

  The screw coupling member 26 is formed in a tubular shape, for example, by a metal such as stainless steel. On an inner wall of one end of the screw coupling member 26, a screw portion 261 which can be screwed to the screw portion 251 is formed. The other end of the screw coupling member 26 is formed with a projection 262 projecting radially inward in an annular manner. A locking surface 263 is formed on the end surface of the protruding portion 262 on the side of the screw portion 261.

  The screw coupling member 26 is in a state where the end face of the cylindrical member 25 opposite to the inlet 24 abuts against the end face of the fuel pipe 6 on the cylindrical member 25 side, and the locking surface 263 and the locking surface 8 are in contact The screw portion 261 is screwed into the screw portion 251 so that At this time, axial force in the direction in which the cylinder member 25 and the fuel pipe 6 approach each other acts on the cylinder member 25 and the fuel pipe 6. As a result, the end surface of the cylindrical member 25 on the opposite side to the inlet 24 and the end surface of the fuel pipe 6 on the cylindrical member 25 side are in close contact with each other.

A fuel passage 100 is formed inside the housing 20 and the nozzle cylindrical portion 11. The fuel passage 100 is in communication with the injection hole 13. Thus, fuel from the outside such as a fuel supply source flows into the fuel passage 100 via the fuel pipe 6, the cylindrical member 25 and the inlet 24. The fuel passage 100 leads the fuel to the injection hole 13.
Here, the inlet 24 and the cylindrical member 25 correspond to the "fuel inlet" in the claims.
The filter 241 is provided inside the inlet portion 24. The filter 241 collects foreign matter in the fuel flowing into the fuel passage 100.

The needle 30 is made of, for example, a material having a relatively high hardness such as martensitic stainless steel. The needle 30 is subjected to hardening treatment so as to have a predetermined hardness. The hardness of the needle 30 is set to be substantially equal to the hardness of the nozzle 10.
The needle 30 is accommodated in the housing 20 so as to be reciprocally movable in the fuel passage 100 in the direction of the axis Ax 1 of the housing 20. The needle 30 has a needle body 31, a seal portion 32, a collar portion 33, and the like.
The needle body 31 is formed in a rod-like shape, more specifically, in a long cylindrical shape. The seal portion 32 is formed at one end of the needle main body 31, that is, the end on the valve seat 14 side, and can abut on the valve seat 14.

  The collar portion 33 is annularly formed, and is provided radially outward of the other end of the needle main body 31, that is, the end opposite to the valve seat 14. In the present embodiment, the collar portion 33 is integrally formed of the same material as the needle main body 31.

  As shown in FIG. 1, a large diameter portion 311 is formed in the vicinity of one end of the needle main body 31. The outer diameter at one end side of the needle main body 31 is smaller than the outer diameter at the other end side. The large diameter portion 311 has an outer diameter larger than the outer diameter at one end of the needle main body 31 and is equal to the outer diameter at the other end of the needle main body 31. The large diameter portion 311 is formed such that the outer wall slides with the inner wall of the nozzle tube portion 11 of the nozzle 10. Thus, the needle 30 is guided to reciprocate in the direction of the axis Ax1 of the end on the valve seat 14 side. A chamfered portion 312 is formed on the large diameter portion 311 such that a plurality of circumferential portions of the outer wall are chamfered. Thus, the fuel can flow between the chamfered portion 312 and the inner wall of the nozzle cylindrical portion 11 of the nozzle 10.

  At the other end of the needle body 31, an axial hole 313 extending along the axis Ax2 of the needle body 31 is formed. That is, the other end of the needle main body 31 is formed in a hollow cylindrical shape. Further, in the needle main body 31, a radial direction hole 314 extending in the radial direction of the needle main body 31 is formed so as to connect the end of the axial hole 313 on the valve seat 14 side and the space outside the needle main 31. ing. Thus, the fuel in the fuel passage 100 can flow through the axial holes 313 and the radial holes 314. Thus, the needle body 31 has an axial hole 313 communicating with the space on the outside of the needle body 31 extending in the direction of the axis Ax 2 from the end face opposite to the valve seat 14 via the radial hole 314. doing.

  The needle 30 opens and closes the injection hole 13 by the seal portion 32 moving away from the valve seat 14 (lifting) or abutting (seating) on the valve seat 14. Hereinafter, as appropriate, the direction in which the needle 30 separates from the valve seat 14 is referred to as a valve opening direction, and the direction in which the needle 30 abuts on the valve seat 14 is referred to as a valve closing direction.

  The movable core 40 has a movable core body 41. The movable core main body 41 is formed in a substantially cylindrical shape, for example, by a magnetic material such as ferritic stainless steel. The movable core main body 41 is subjected to magnetic stabilization processing. The hardness of the movable core body 41 is relatively low, and is substantially equal to the hardness of the first cylindrical portion 21 and the third cylindrical portion 23 of the housing 20.

The movable core 40 has a shaft hole 42, a recess 44, and the like. The axial hole portion 42 is formed to extend along the axis Ax3 of the movable core body 41. In the present embodiment, the inner wall of the shaft hole 42 is subjected to a hard processing such as Ni-P plating and a sliding resistance reduction processing, for example.
The recess 44 is formed at the center of the movable core body 41 so as to be circularly recessed from the surface on the valve seat 14 side of the movable core body 41 to the opposite side to the valve seat 14. Here, the shaft hole 42 is open at the bottom of the recess 44.

The movable core 40 is accommodated in the housing 20 in a state in which the needle body 31 of the needle 30 is inserted into the shaft hole 42. The inner diameter of the shaft hole portion 42 of the movable core 40 is set to be equal to the outer diameter of the needle main body 31 of the needle 30 or slightly larger than the outer diameter of the needle main body 31. Therefore, the movable core 40 can move relative to the needle 30 while the inner wall of the shaft hole 42 slides on the outer wall of the needle main body 31 of the needle 30. Further, the movable core 40 is accommodated in the housing 20 so as to be able to reciprocate in the fuel passage 100 in the direction of the axis Ax1 of the housing 20, similarly to the needle 30.
In the present embodiment, the surface on the opposite side of the movable core body 41 from the valve seat 14 is subjected to hard processing such as hard chromium plating and abrasion resistance.

  The outer diameter of the movable core body 41 is set smaller than the inner diameters of the first cylindrical portion 21 and the second cylindrical portion 22 of the housing 20. Therefore, when the movable core 40 reciprocates in the fuel passage 100, the outer wall of the movable core 40 and the inner walls of the first cylindrical portion 21 and the second cylindrical portion 22 do not slide.

  As shown in FIG. 3, the flange 33 of the needle 30 can contact the surface on the valve seat 14 side with the surface of the movable core main body 41 opposite to the valve seat 14. That is, the needle 30 has an abutting surface 34 that can abut on the surface of the movable core main body 41 opposite to the valve seat 14. Here, the contact surface 34 is formed on the surface on the valve seat 14 side of the flange portion 33. The movable core 40 is provided so as to be movable relative to the needle 30 so as to be able to abut on the abutment surface 34 or to be separated from the abutment surface 34.

  As shown in FIG. 1, the fixed core 50 is provided on the opposite side of the movable core 40 inside the housing 20 from the valve seat 14. The stationary core 50 has a stationary core body 51 and a bush 52. The fixed core main body 51 is formed in a substantially cylindrical shape, for example, by a magnetic material such as ferritic stainless steel. The stationary core body 51 is subjected to magnetic stabilization processing. The hardness of the fixed core main body 51 is relatively low, and is substantially equal to the hardness of the movable core main body 41.

  In the present embodiment, the fixed core main body 51, the third cylindrical portion 23, and the inlet portion 24 are integrally formed of the same material. In FIG. 1, boundaries between the fixed core main body 51, the third cylindrical portion 23, and the inlet portion 24 are indicated by two-dot chain lines.

  The bush 52 is formed in a substantially cylindrical shape, for example, of a material having a relatively high hardness such as martensitic stainless steel. The bush 52 is provided in a recess 511 formed so as to be recessed radially outward from the inner wall of the end on the valve seat 14 side of the fixed core main body 51. Here, the inner diameter of the bush 52 and the inner diameter of the fixed core body 51 are approximately equal. The end face of the bush 52 on the valve seat 14 side is located closer to the valve seat 14 than the end face of the fixed core main body 51 on the valve seat 14 side. Therefore, the surface of the movable core body 41 opposite to the valve seat 14 can abut on the end surface of the bush 52 on the valve seat 14 side.

The fixed core 50 is provided such that the collar 33 of the needle 30 with the seal 32 in contact with the valve seat 14 is located inside the bush 52. Inside the fixed core body 51, a cylindrical adjusting pipe 53 is press-fitted.
The gap forming member 60 is formed of, for example, a nonmagnetic material. The hardness of the gap forming member 60 is set to be substantially equal to the hardness of the needle 30 and the bush 52.

  The clearance forming member 60 is provided on the side opposite to the valve seat 14 with respect to the needle 30 and the movable core 40. As shown in FIG. 3, the gap forming member 60 has a plate portion 61 and an extending portion 62. The plate portion 61 is formed in a substantially disc shape. The plate portion 61 is provided on the side opposite to the valve seat 14 with respect to the needle 30 so that one end face can abut on the collar portion 33 and the needle main body 31.

  The extension portion 62 is integrally formed with the plate portion 61 so as to extend cylindrically from the outer edge of one end face of the plate portion 61 toward the valve seat 14. That is, the gap forming member 60 is formed in a bottomed cylindrical shape in the present embodiment. The gap forming member 60 is provided such that the collar 33 of the needle 30 is located inside the extension 62. Further, the end of the extension portion 62 opposite to the plate portion 61 can be in contact with the surface of the movable core main body 41 on the stationary core 50 side.

  In the present embodiment, the length of the extension portion 62 in the axial direction is longer than the length of the collar portion 33 in the axial direction. Therefore, when the plate portion 61 is in contact with the needle 30 and the extension portion 62 is in contact with the movable core 40, the gap forming member 60 has the valve seat 14 side surface of the flange portion 33 and the valve seat 14 of the movable core 40. And an axial clearance CL1 which is a clearance in the direction of the axis Ax2 between the surface and the opposite surface.

  Here, the inner diameter of the extension portion 62 is set to be equal to the outer diameter of the collar portion 33 or slightly larger than the outer diameter of the collar portion 33. Therefore, in the gap forming member 60, the inner wall of the extension portion 62, that is, the wall surface facing the outer wall of the collar portion 33 can slide on the outer wall of the collar portion 33 and can move relative to the needle 30. The outer diameters of the plate portion 61 and the extending portion 62 are set to be equal to the inner diameter of the bush 52 of the fixed core 50 or slightly smaller than the inner diameter of the bush 52. Therefore, in the gap forming member 60, the outer wall of the plate portion 61 and the extending portion 62, that is, the wall surface facing the inner wall of the bush 52 can slide with the inner wall of the bush 52. Therefore, the needle 30 is guided by the fixed core 50 and the gap forming member 60 so that the end on the side of the collar 33 can reciprocate in the axial direction.

  In the present embodiment, the needle 30 is supported so as to reciprocate by the inner wall of the nozzle cylinder 11 of the nozzle 10 near the end on the valve seat 14 side, and the portion on the fixed core 50 is the fixed core 50 and the gap forming member 60 It is supported so as to be reciprocally movable. In this manner, the needle 30 is guided in axial reciprocation by the two portions in the direction of the axis Ax1 of the housing 20.

  In the present embodiment, since the extension portion 62 is formed in a cylindrical shape, when the extension portion 62 and the movable core 40 are in contact with each other, the contact surface 34 of the collar portion 33, the movable core 40 and the extension portion 62 An annular space S1, which is an annular space, is formed between the inner wall and the inner wall.

  The gap forming member 60 further has a hole 611. The hole portion 611 connects one end surface of the plate portion 61 and the other end surface, and can communicate with the axial hole portion 313 of the needle 30. As a result, the fuel on the opposite side of the valve seat 14 of the gap forming member 60 in the fuel passage 100 passes through the hole 611, the axial hole 313 of the needle 30, and the radial hole 314 of the movable core 40. It can be distributed to the valve seat 14 side.

  The spring 71 is, for example, a coil spring, and is provided on the opposite side of the gap forming member 60 to the valve seat 14. One end of the spring 71 is in contact with the end surface of the plate portion 61 of the gap forming member 60 on the opposite side to the extending portion 62. The other end of the spring 71 is in contact with the adjusting pipe 53. The spring 71 biases the gap forming member 60 toward the valve seat 14. The spring 71 can bias the needle 30 to the valve seat 14 side, that is, the valve closing direction via the gap forming member 60 when the plate portion 61 of the gap forming member 60 is in contact with the needle 30. Further, when the extension portion 62 of the gap forming member 60 is in contact with the movable core 40, the spring 71 can bias the movable core 40 toward the valve seat 14 via the gap forming member 60. That is, the spring 71 can bias the needle 30 and the movable core 40 toward the valve seat 14 via the gap forming member 60. The biasing force of the spring 71 is adjusted by the position of the adjusting pipe 53 with respect to the fixed core 50.

  The yoke 90 is cylindrically formed of a magnetic material such as ferrite stainless steel, for example, and is subjected to magnetic stabilization processing. The yoke 90 is provided so as to be located on the radially outer side of the second cylindrical portion 22 of the housing 20 in particular. The yoke 90 has a yoke lower projecting portion 91 which annularly protrudes radially inward from an end on the valve seat 14 side. A yoke lower locking surface 911 is formed on the end surface of the yoke lower protrusion 91 opposite to the valve seat 14. The yoke 90 has a yoke upper threaded portion 92 formed on the inner wall in the middle in the axial direction. The yoke upper screw portion 92 is formed over the entire circumferential direction of the yoke 90.

On the outer wall of the first cylindrical portion 21 of the housing 20, a first cylindrical portion engaging surface 211 facing the yoke lower engaging surface 911 is formed.
The third cylindrical portion 23 has a third cylindrical portion protruding portion 231 that annularly protrudes radially outward from the outer wall. A third cylindrical portion screw portion 232 which can be screwed to the yoke upper screw portion 92 is formed on the radial outer surface of the third cylindrical portion protrusion 231.

The yoke upper threaded portion 92 is screwed to the third cylindrical portion screw portion 232 such that the yoke lower locking surface 911 and the first cylindrical portion locking surface 211 are in contact with each other. Here, in the first cylindrical portion 21 and the third cylindrical portion 23, an axial force F1 is generated which is a force along the axis Ax1 in the direction in which the first cylindrical portion 21 and the third cylindrical portion 23 approach each other. ing. Therefore, a force in a direction in which the first cylindrical portion 21 and the third cylindrical portion 23 contract in the direction of the axis Ax1 acts on the second cylindrical portion 22 forming the magnetic throttling portion 221.
Further, the yoke lower locking surface 911 is locked to the first cylindrical portion locking surface 211 of the yoke 90, and relative movement of the housing 20 to the opposite side to the valve seat 14 is restricted.

Further, in the present embodiment, a portion of the third cylindrical portion protruding portion 231 opposite to the valve seat 14 with respect to the third cylindrical portion screw portion 232 and a yoke upper screw portion 92 of the yoke 90 are the valve seat 14 The opposite side is connected by welding. In FIG. 1, a connecting portion between the third cylindrical portion protruding portion 231 and the yoke 90 is indicated by c5. In the connection portion c5, a melted portion w5 is formed in which a portion of the third cylindrical portion protruding portion 231 and a portion of the yoke 90 are melted and cooled and solidified by welding. Thereby, the third cylindrical portion 23 and the yoke 90 are fixed so as not to be relatively rotatable. Therefore, it is possible to suppress "a decrease in axial force F1 due to relative rotation of the third cylindrical portion 23 and the yoke 90".
The third cylindrical portion projecting portion 231 forms a substantially cylindrical coil accommodation chamber 101 between the end face on the valve seat 14 side, the inner wall of the yoke 90 and the outer wall of the housing 20.

  As shown in FIG. 4, groove portions 233 and 234 are formed in the third cylindrical portion protruding portion 231. The groove portions 233 and 234 are formed so as to be cut radially inward from the outer edge portion of the third cylindrical portion protruding portion 231. The grooves 233 and 234 are formed to connect the end face on the valve seat 14 side of the third cylindrical portion protrusion 231 and the end face on the opposite side to the valve seat 14. In the present embodiment, five grooves 233 are formed. One groove 234 is formed. The groove 234 is formed larger than the groove 233. The grooves 233 and 234 are formed at substantially equal intervals in the circumferential direction of the third cylindrical portion protrusion 231. That is, the groove portions 233 and 234 are formed at intervals of about 60 degrees in the circumferential direction of the third cylindrical portion protruding portion 231. The groove portions 233 and 234 connect the space on the opposite side of the valve seat 14 of the third cylindrical portion protruding portion 231 to the coil accommodation chamber 101.

  As shown in FIGS. 1 and 2, the coil 80 is formed in a substantially cylindrical shape, and in particular, of the connection portions c 1 and c 2 of the second cylindrical portion 22 and the first cylindrical portion 21 and the third cylindrical portion 23 in the housing 20. It is provided in the coil storage chamber 101 so as to be located radially outward. That is, the coil 80 is provided between the housing 20 and the yoke 90.

  The coil 80 has a bobbin 81 and a winding 82. The bobbin 81 is formed in a cylindrical shape, for example, of resin. The winding 82 is made of, for example, a copper wire, and wound around a bobbin 81. Further, the bobbin 81 has a bobbin extension portion 811 extending in a direction parallel to the axis from a part of the circumferential direction. Inside the bobbin extension portion 811, a winding terminal 821 connected to the winding 82 is provided. The end of the winding terminal 821 on the opposite side to the winding 82 is in a state where it protrudes from the bobbin extension 811.

  The coil 80 is provided such that the bobbin extension 811 is positioned in the groove 234 of the third cylindrical portion 231. The coil accommodating chamber 101 is filled with a thermoplastic resin. Thus, the periphery of the coil 80 in the coil storage chamber 101 is covered with resin. Further, the groove 233 and the outer wall on the opposite side to the valve seat 14 with respect to the third cylindrical portion protruding portion 231 of the third cylindrical portion 23 are also covered with resin. As a result, a mold portion 83 made of resin is formed on the coil housing chamber 101, the groove portion 233, and the outer wall of the third cylindrical portion 23.

  The molded portion 83 is provided with a cable 27 for connection. The cable 27 has a cable terminal 271 and a conductor 272. The cable terminal 271 is electrically connected to the winding terminal 821 inside the molded portion 83 (see FIG. 1).

  A connector 28 is provided at the end of the cable 27 opposite to the mold portion 83 so as to be connected. Connector terminals 281 are insert-molded in the connector 28. The connector terminal 281 is electrically connected to the conducting wire 272 inside the connector 28 (see FIG. 2).

  The coil 80 generates a magnetic force when power is supplied (energized) to the winding 82 via the connector terminal 281, the conducting wire 272, and the winding terminal 821. When magnetic force is generated in the coil 80, the first cylindrical portion 21, the movable core 40, the fixed core 50, the third cylindrical portion 23, and the third cylindrical portion protruding portion are avoided so as to avoid the magnetic throttling portion 221 of the second cylindrical portion 22. A magnetic circuit is formed at 231 and the yoke 90. As a result, a magnetic attraction force is generated between the fixed core main body 51 and the movable core main body 41, and the movable core 40 is attracted to the fixed core 50 side. At this time, the movable core 40 moves in the valve opening direction while accelerating the axial gap CL1, and collides with the contact surface 34 of the collar portion 33 of the needle 30. As a result, the needle 30 moves in the valve opening direction, the seal portion 32 separates from the valve seat 14, and the valve opens. As a result, the injection hole 13 is opened. As described above, when energized, the coil 80 can cause the movable core 40 to be attracted to the fixed core 50 side and abut on the flange 33 to move the needle 30 to the opposite side to the valve seat 14 .

  As described above, in the present embodiment, since the gap forming member 60 forms the axial gap CL1 between the collar 33 and the movable core 40 in the valve closed state, the movable core 40 is energized when the coil 80 is energized. Can be accelerated by the axial clearance CL1 to collide with the collar portion 33. Thus, even when the pressure of the fuel in the fuel passage 100 is relatively high, the valve can be opened without increasing the power supplied to the coil 80.

When the movable core 40 is attracted to the fixed core 50 side (valve opening direction) by the magnetic attraction force, the surface of the movable core main body 41 on the fixed core 50 side collides with the end face of the bush 52 on the valve seat 14 side. . Thereby, the movement of the movable core 40 in the valve opening direction is restricted.
In the present embodiment, the fuel injection device 1 further includes a spring seat portion 291, a fixing portion 292, a cylindrical portion 293, and a spring 73.
In the present embodiment, the spring seat portion 291 and the fixing portion 292 are connected to each other by the cylindrical portion 293. The spring seat portion 291, the fixing portion 292 and the cylindrical portion 293 are integrally formed of, for example, a metal such as stainless steel.
The spring seat portion 291 is formed in an annular shape, and is located radially outside the needle main body 31 between the movable core 40 and the guide portion 28.

  The fixed portion 292 is formed in a tubular shape, and is located on the radially outer side of the needle main body 31 between the movable core 40 and the spring seat portion 291. The fixing portion 292 has an inner wall fitted to the outer wall of the needle main body 31 and is fixed to the needle main body 31.

  The cylindrical portion 293 is formed in a cylindrical shape, one end thereof is connected to the spring seat portion 291, and the other end is connected to the fixed portion 292. Thus, the spring seat portion 291 is fixed to the radially outer side of the needle body 31 between the movable core 40 and the guide portion 28.

  The spring 73 is, for example, a coil spring, and one end thereof is in contact with the spring seat 291 and the other end is in contact with the bottom of the recess 44 of the movable core 40. The spring 73 can bias the movable core 40 to the fixed core 50 side. The biasing force of the spring 73 is smaller than the biasing force of the spring 71.

  The spring 71 urges the gap forming member 60 toward the valve seat 14, whereby the plate portion 61 of the gap forming member 60 abuts on the needle 30, and the needle 30 presses the seal portion 32 against the valve seat 14. At this time, the spring 73 biases the movable core 40 to the fixed core 50 side, so that the extending portion 62 of the gap forming member 60 and the movable core 40 come into contact with each other so as to be pressed to each other. In this state, an axial gap CL1 is formed between the contact surface 34 of the collar 33 of the needle 30 and the movable core 40.

  The movable core 40 is provided so as to be capable of reciprocating in the axial direction between the collar 33 and the fixed portion 292 of the needle 30. The bottom of the recess 44 of the movable core 40 can abut on the end of the fixed portion 292 on the movable core 40 side. The fixed portion 292 can regulate the relative movement of the movable core 40 to the valve seat 14 side with respect to the needle 30 by abutting on the movable core 40.

  Further, in the present embodiment, a cylindrical space S2, which is a cylindrical space, is formed between the cylindrical portion 293 and the spring seat portion 291 and the needle main body 31. Here, the radial direction hole 314 of the needle 30 is in communication with the cylindrical space S2. Therefore, the fuel in the axial hole 313 can flow to the valve seat 14 side via the radial hole 314, the cylindrical space S2 and the flow passage 282.

  In the present embodiment, when energization of the coil 80 is stopped in a state where the movable core 40 is attracted to the fixed core 50 side, the needle 30 and the movable core 40 are biased by the spring 71 via the gap forming member 60. , Is biased toward the valve seat 14 side. As a result, the needle 30 moves in the valve closing direction, and the seal portion 32 abuts on the valve seat 14 to close the valve. As a result, the injection hole 13 is closed.

  After the seal portion 32 abuts on the valve seat 14, the movable core 40 moves relative to the needle 30 toward the valve seat 14 due to inertia. At this time, the fixed portion 292 can restrict excessive movement of the movable core 40 toward the valve seat 14 by abutting on the movable core 40. Thereby, the fall of the responsiveness at the time of the next valve opening can be controlled. Further, the biasing force of the spring 73 can reduce the impact when the movable core 40 abuts on the fixed portion 292, and can suppress the secondary valve opening due to the needle 30 bouncing off the valve seat 14. Further, the fixed portion 292 restricts the movement of the movable core 40 to the valve seat 14 side, so that the excessive compression of the spring 73 can be suppressed, and the movable core 40 is opened by the restoring force of the excessively compressed spring 73. It is possible to suppress the secondary valve opening by biasing in the direction and colliding with the flange portion 33 again.

  The fuel flowing from the cylindrical member 25 and the inlet portion 24 flows from the fixed core 50, the adjusting pipe 53, the hole 611 of the gap forming member 60, the axial hole 313 of the needle 30, the radial hole 314, and the cylindrical space S2. The fuel is circulated between the first cylindrical portion 21 and the needle 30 and between the nozzle 10 and the needle 30, that is, the fuel passage 100, and is led to the injection hole 13.

  As shown in FIGS. 1 and 2, in the present embodiment, the fuel injection device 1 is a mounting hole formed in the engine head 4 of the engine 2 so that the nozzle bottom 12 of the nozzle 10 is exposed to the combustion chamber 3 of the engine 2. It is attached to the part 5. Here, the fuel injection device 1 is mounted such that the surface on the opposite side of the yoke lower locking surface 91 of the yoke lower protrusion 91 of the yoke 90 is pressed against the step surface of the mounting hole 5. At this time, although an axial force in the direction in which the first cylinder portion 21 and the third cylinder portion 23 approach each other is generated in the first cylinder portion 21 and the third cylinder portion 23, this axial force is the third cylinder portion of the yoke 90. This is smaller than the axial force F1 generated by screwing with the shaft 23.

Next, a method of manufacturing the fuel injection device 1 of the present embodiment will be described.
In the present embodiment, the method of manufacturing the fuel injection device 1 includes the following steps.
(Housing welding process)
The second cylindrical portion 22 is welded to the first cylindrical portion 21 and the third cylindrical portion 23 in a state in which the needle 30, the movable core 40, and the like are accommodated inside the housing 20.
(Coil assembly process)
The coil 80 is assembled to the outside of the housing 20 so that the bobbin extension 811 is positioned in the groove 234.

(Yoke assembly process)
The first cylindrical portion 21 and the third cylindrical portion 23 are engaged with the first cylindrical portion so that an axial force F1 of a predetermined magnitude in the direction in which the first cylindrical portion 21 and the third cylindrical portion 23 approach each other is generated. The yoke lower locking surface 911 is brought into contact with the stop surface 211, the yoke upper screw portion 92 is screwed into the third cylindrical portion screw portion 232, and the yoke 90 is assembled to the housing 20.

(Yoke welding process)
The connecting portion c5 between the third cylindrical protrusion 231 and the yoke 90 is welded. At this time, a portion of the third cylindrical portion protruding portion 231 opposite to the valve seat 14 with respect to the third cylindrical portion screw portion 232, and a side opposite to the valve seat 14 with respect to the yoke upper screw portion 92 of the yoke 90. Since “the yoke 90 is extended in the axial direction at the time of welding, it is possible to suppress that the axial force F1 is reduced”.
(Mold process)
The heated thermoplastic resin is filled in the coil storage chamber 101 via the groove portion 233, and the outer wall of the third cylindrical portion 23 is covered with the heated thermoplastic resin to form a mold portion 83.

Next, the operation of the fuel injection device 1 of the present embodiment will be described.
As shown in FIGS. 1 and 3, when the coil 80 is not energized, the seal portion 32 of the needle 30 is in contact with the valve seat 14, and the plate portion 61 of the gap forming member 60 is in contact with the needle 30; The extension portion 62 is in contact with the movable core 40. At this time, an axial clearance CL <b> 1 is formed between the contact surface 34 of the collar 33 and the movable core 40.

  When the coil 80 is energized in the state shown in FIGS. 1 and 3, the movable core 40 is attracted to the fixed core 50 side, and is moved toward the fixed core 50 while accelerating with the axial gap CL1 while pushing up the gap forming member 60. Do. Then, the movable core 40 in a state in which kinetic energy is increased by acceleration in the axial direction clearance CL1 collides with the contact surface 34 of the collar portion 33. Thus, the seal portion 32 is separated from the valve seat 14 and is opened.

  When the movable core 40 collides with the collar portion 33 and moves further to the fixed core 50 side, the movable core 40 abuts on the bush 52. Thereby, the movement of the movable core 40 in the valve opening direction is restricted. At this time, the needle 30 further moves in the valve opening direction by inertia and abuts on the plate portion 61 of the gap forming member 60.

  When energization of the coil 80 is stopped, the movable core 40 and the needle 30 move in the valve closing direction by the biasing force of the spring 71 via the gap forming member 60. When the seal portion 32 of the needle 30 abuts on the valve seat 14 to close the valve, the movable core 40 further moves in the valve closing direction by inertia and abuts on the fixed portion 292. Thereby, the movement of the movable core 40 in the valve closing direction is restricted. At this time, the movable core 40 is separated from the extending portion 62 of the gap forming member 60. Thereafter, the movable core 40 is moved in the valve opening direction by the biasing force of the spring 73 and abuts on the extending portion 62 of the gap forming member 60 (see FIGS. 1 and 3).

As described above, (1) In the present embodiment, the nozzle 10 has the injection hole 13 into which the fuel is injected, and the valve seat 14 formed annularly around the injection hole 13.
The housing 20 has a first cylindrical portion 21 whose one end is connected to the nozzle 10, and a second cylindrical portion 22 whose one end is connected to the other end of the first cylindrical portion 21 and which forms a magnetic throttling portion 221 at least in part in the axial direction. The third cylindrical portion 23 whose one end is connected to the other end of the second cylindrical portion 22 and the first cylindrical portion 21, the second cylindrical portion 22 and the third cylindrical portion 23 communicate with the injection hole 13. The fuel passage 100 is formed and guides the fuel to the injection hole 13.

The needle 30 has a rod-like needle main body 31 and a seal portion 32 formed annularly at one end of the needle main body 31 so as to be able to abut the valve seat 14, and the seal portion 32 separates from the valve seat 14 or When the seat 14 is abutted, the injection hole 13 is opened and closed.
The movable core 40 is provided so as to be reciprocally movable in the housing 20 together with the needle 30.
The fixed core 50 is provided on the opposite side of the movable core 40 inside the second cylindrical portion 22 and the third cylindrical portion 23 to the valve seat 14.
The spring 71 can bias the needle 30 and the movable core 40 toward the valve seat 14.

  The yoke 90 is formed in a tubular shape, one end side is connected to the first tubular portion 21, the other end side is connected to the third tubular portion 23, and the first tubular portion 21 and the third tubular portion 23 are connected to the first tubular portion 21. And the third cylindrical portion 23 are provided on the radially outer side of the housing 20 such that an axial force F1 in a direction in which they approach each other is generated.

  The coil 80 is provided between the housing 20 and the yoke 90, and when energized, forms a magnetic circuit in the first cylindrical portion 21, the movable core 40, the fixed core 50, the third cylindrical portion 23 and the yoke 90, and is movable It is possible to suck the core 40 toward the fixed core 50 and move the needle 30 to the opposite side to the valve seat 14.

  In the present embodiment, the yoke 90 is provided so that an axial force F1 in a direction in which the first cylinder portion 21 and the third cylinder portion 23 approach each other is generated in the first cylinder portion 21 and the third cylinder portion 23. Therefore, a force in a direction in which the first cylindrical portion 21 and the third cylindrical portion 23 contract in the direction of the axis Ax1 acts on the second cylindrical portion 22 forming the magnetic throttling portion 221. Thereby, even if the pressure of the fuel in the fuel passage 100 becomes high, the connection portion c1 between the second cylindrical portion 22 and the first cylindrical portion 21 and the connection portion c2 between the second cylindrical portion 22 and the third cylindrical portion 23 Alternatively, it is possible to suppress the “force in the direction in which each member separates in the direction of the axis Ax1” acting on the magnetic throttling portion 221. Therefore, stress concentrates on the connection c1 of the second cylindrical portion 22 and the first cylindrical portion 21, the connection c2 of the second cylindrical portion 22 and the third cylindrical portion 23, or the magnetic throttling portion 221 and ruptures. Can be suppressed. Therefore, in the present embodiment, high-pressure fuel can be injected while suppressing fuel leakage.

Further, in the present embodiment, since the force in the direction in which the first cylindrical portion 21 and the third cylindrical portion 23 contract in the direction of the axis Ax1 acts on the second cylindrical portion 22 forming the magnetic throttle portion 221, the fuel Even if the pressure of the fuel in the passage 100 becomes high, the displacement of the position of the magnetic throttle portion 221 with respect to the fixed core 50 in the direction of the axis Ax1 can be suppressed. Therefore, the magnitude of the magnetic attraction force generated between the fixed core 50 and the movable core 40 can be suppressed from fluctuating. Thereby, the fall of the injection accuracy of fuel can be controlled.
As described above, in the fuel injection device 1 of the present embodiment, high-pressure fuel can be injected with high accuracy while suppressing fuel leakage.

(2) In the present embodiment, the first tubular portion 21 has the first tubular portion engagement surface 211.
The third cylindrical portion 23 has a third cylindrical portion screw portion 232.
A yoke lower locking surface 911, which is locked to the first tubular portion locking surface 211 and whose relative movement to the opposite side to the valve seat 14 with respect to the housing 20 is restricted, and a third tubular portion screw portion A yoke upper screw portion 92 screwed to 232 is provided.
(3) In the present embodiment, the third cylindrical portion 23 and the yoke 90 are fixed so as not to be relatively rotatable. Therefore, it is possible to suppress "a decrease in axial force F1 due to relative rotation of the third cylindrical portion 23 and the yoke 90".

(4) In the present embodiment, the third cylindrical portion 23 annularly protrudes radially outward from the outer wall on the side opposite to the valve seat 14 with respect to the coil 80, and the third cylindrical portion screw portion It has the 3rd cylinder part projection part 231 in which 232 is formed.
(12) In the present embodiment, the third cylindrical portion 23 is integrally formed with the fixed core 50. Therefore, the number of members and the number of assembling steps can be reduced.

(13) In the present embodiment, the needle 30 has the contact surface 34 that can contact the surface of the movable core 40 on the fixed core 50 side.
The movable core 40 is provided so as to be movable relative to the needle 30 so as to be able to abut on the abutment surface 34 or to be separated from the abutment surface 34.
A gap forming member 60 capable of forming an axial gap CL1 which is an axial gap between the contact surface 34 and the movable core 40 is provided. As a result, when the coil 80 is energized, the movable core 40 can be accelerated by the axial gap CL1 to collide with the collar portion 33. Thus, even when the pressure of the fuel in the fuel passage 100 is relatively high, the valve can be opened without increasing the power supplied to the coil 80.

(14) The present embodiment is the fuel injection device 1 in which fuel is supplied from the outside via the fuel pipe 6.
The inlet 24 and the cylinder 25 as a fuel inlet are formed in a cylindrical shape, the inlet 24 at one end is connected to the other end of the third cylinder 23, and the cylinder 25 at the other end is a fuel pipe 6 To introduce fuel from the outside into the fuel passage 100.

  The screw coupling member 26 is screwed to the cylindrical member 25 so that the cylindrical member 25 and the fuel pipe 6 are in close contact with each other. Thus, high-pressure fuel can be supplied to the fuel passage 100 via the cylindrical member 25 and the inlet 24.

Second Embodiment
A portion of a fuel injection device according to a second embodiment of the present invention is shown in FIG. The second embodiment differs from the first embodiment in the configuration of the third cylindrical portion protrusion 231.

In the second embodiment, the third cylindrical protrusion 231 has holes 235 and 236 instead of the grooves 233 and 234 shown in the first embodiment. The holes 235 and 236 are formed so as to connect the end face on the valve seat 14 side and the end face on the opposite side of the valve seat 14 in the radial direction inner side of the third tube part screw part 232 of the third tube part projection 231 It is done. In the present embodiment, five hole portions 235 are formed in the circumferential direction of the third cylindrical portion protruding portion 231 so as to be circular when viewed from the direction of the axis Ax1. One hole 236 is formed to have an oval shape along the arc when viewed from the direction of the axis Ax1. The hole 236 is formed larger than the hole 235. The holes 235 and 236 are formed at substantially equal intervals in the circumferential direction of the third cylindrical portion protrusion 231. That is, the holes 235 and 236 are formed at intervals of about 60 degrees in the circumferential direction of the third cylindrical portion protrusion 231. The holes 235 and 236 connect the space on the opposite side of the valve seat 14 of the third cylindrical protrusion 231 to the coil accommodating chamber 101.
The bobbin extension portion 811 is inserted into the hole 236.

Next, a method of manufacturing the fuel injection device of the present embodiment will be described.
In the present embodiment, the method of manufacturing the fuel injection device differs from the first embodiment in the coil assembling step and the molding step as follows.
(Coil assembly process)
The coil 80 is assembled to the outside of the housing 20 so that the bobbin extension 811 is inserted into the hole 236.
(Mold process)
The heated thermoplastic resin is filled in the coil storage chamber 101 via the hole portion 235, and the outer wall of the third cylindrical portion 23 is covered with the heated thermoplastic resin to form a mold portion 83.

  As described above, (5) In the present embodiment, the third cylindrical portion protrusion 231 accommodates the coil 80 between the end face on the valve seat 14 side, the inner wall of the yoke 90 and the outer wall of the housing 20. A chamber 101 is formed, and has holes 235 and 236 connecting the end face on the valve seat 14 side and the end face on the opposite side to the valve seat 14 at the radially inner side of the third cylindrical portion screw portion 232. The periphery of the coil 80 in the coil storage chamber 101 is covered with resin.

In the present embodiment, the holes 235 and 236 are formed on the radially inner side of the third cylindrical portion screw portion 232 of the third cylindrical portion protrusion 231. Therefore, the third cylindrical portion screw portion 232 is formed so as to be continuous over the entire range in the circumferential direction of the third cylindrical portion projecting portion 231 without cutting out a part in the circumferential direction as in the first embodiment. It is done. Therefore, the axial force F1 in the direction in which the first cylindrical portion 21 and the third cylindrical portion 23 approach each other can be made uniform over the entire range in the circumferential direction of the third cylindrical portion screw portion 232.
Further, in the present embodiment, the hole portion 235 is formed in a circular shape, and the hole portion 236 is formed in an oval shape. Therefore, the holes 235 and 236 can be easily formed by, for example, a drill or the like.

Third Embodiment
A portion of a fuel injection system according to a third embodiment of the present invention is shown in FIG. The third embodiment differs from the second embodiment in the configuration of the third cylindrical portion protrusion 231.

  In the third embodiment, the third cylindrical protrusion 231 has a hole 237 instead of the holes 235 and 236 shown in the second embodiment. The hole 237 is formed so as to connect the end face on the valve seat 14 side and the end face on the opposite side of the valve seat 14 in the radial direction inner side of the third tube part screw part 232 of the third tube part protrusion 231 There is. In the present embodiment, four holes 237 are formed in the circumferential direction of the third cylindrical portion protrusion 231 so as to have a shape in which the sector of the radius r2 is removed from the sector of the radius r1 when viewed from the direction of the axis Ax1. ing. Here, r1 is smaller than the radius of the 3rd cylinder part projection part 231, and larger than r2 (refer to Drawing 6). Further, r2 is equal to half of the outer diameter of the cylindrical third cylindrical portion 23.

The holes 237 are formed at substantially equal intervals in the circumferential direction of the third cylindrical portion protrusion 231. That is, the holes 237 are formed at intervals of about 90 degrees in the circumferential direction of the third cylindrical portion protrusion 231. The hole 237 connects the space on the opposite side of the valve seat 14 of the third cylindrical portion protrusion 231 to the coil accommodation chamber 101.
The bobbin extension portion 811 is inserted into one of the four hole portions 237.

Next, a method of manufacturing the fuel injection device of the present embodiment will be described.
In the present embodiment, the method for manufacturing a fuel injection device differs from the second embodiment in the coil assembling step and the molding step as follows.
(Coil assembly process)
The coil 80 is assembled to the outside of the housing 20 so that the bobbin extension 811 is inserted into the hole 237.
(Mold process)
The heated thermoplastic resin is filled in the coil storage chamber 101 via the hole 237, and the outer wall of the third cylindrical portion 23 is covered with the heated thermoplastic resin to form a mold portion 83.

  As described above, (5) In the present embodiment, the third cylindrical portion protrusion 231 accommodates the coil 80 between the end face on the valve seat 14 side, the inner wall of the yoke 90 and the outer wall of the housing 20. A chamber 101 is formed, and has a hole 237 connecting the end face on the valve seat 14 side and the end face on the opposite side to the valve seat 14 at the radially inner side of the third cylindrical portion screw portion 232. The periphery of the coil 80 in the coil storage chamber 101 is covered with resin.

  In the present embodiment, the hole 237 is formed on the radially inner side of the third cylindrical portion screw portion 232 of the third cylindrical portion protrusion 231. Therefore, the third cylindrical portion screw portion 232 is formed so as to be continuous over the entire range in the circumferential direction of the third cylindrical portion projecting portion 231 without cutting out a part in the circumferential direction as in the first embodiment. It is done. Therefore, as in the second embodiment, the axial force F1 in the direction in which the first cylindrical portion 21 and the third cylindrical portion 23 approach each other is made uniform over the entire range in the circumferential direction of the third cylindrical portion screw portion 232. Can.

  In the present embodiment, the four hole portions 237 have the same shape and are formed at equal intervals in the circumferential direction of the third cylindrical portion protruding portion 231. Therefore, the balance in the circumferential direction of the third cylindrical portion protruding portion 231 of the magnetic circuit formed in the yoke 90 when the coil 80 is energized can be improved.

Fourth Embodiment
A portion of a fuel injection system according to a fourth embodiment of the present invention is shown in FIG. The fourth embodiment is different from the third embodiment in the configurations of the first cylindrical portion 21, the third cylindrical portion 23, and the yoke 90, in particular.
In the fourth embodiment, the first cylindrical portion 21 has a first cylindrical portion protruding portion 212 that annularly protrudes radially outward from the outer wall. A first cylindrical portion screw portion 213 is formed on the radially outer surface of the first cylindrical portion protruding portion 212.

  The third cylindrical portion protruding portion 231 does not have the third cylindrical portion screw portion 232 described in the third embodiment. The third cylindrical portion protruding portion 231 has a third cylindrical portion locking surface 238 at the outer edge portion of the end surface opposite to the valve seat 14. The hole 237 is formed on the inner side in the radial direction of the third cylindrical portion engagement surface 238.

The yoke 90 has a yoke upper projecting portion 93 which annularly protrudes radially inward from an inner wall in the axial direction. A yoke upper locking surface 931 facing the third cylindrical portion locking surface 238 is formed on the surface of the yoke upper protrusion 93 on the valve seat 14 side.
The yoke 90 has a yoke lower screw portion 94 which is formed on the inner wall of the end portion on the valve seat 14 side and can be screwed to the first cylindrical portion screw portion 213.

The yoke lower screw portion 94 is screwed with the first cylindrical portion screw portion 213 such that the yoke upper locking surface 931 and the third cylindrical portion locking surface 238 are in contact with each other. Here, in the first cylindrical portion 21 and the third cylindrical portion 23, an axial force F1 is generated which is a force along the axis Ax1 in the direction in which the first cylindrical portion 21 and the third cylindrical portion 23 approach each other. ing. Therefore, a force in a direction in which the first cylindrical portion 21 and the third cylindrical portion 23 contract in the direction of the axis Ax1 acts on the second cylindrical portion 22 forming the magnetic throttling portion 221.
Further, the yoke upper locking surface 931 of the yoke 90 is locked to the third cylindrical portion locking surface 238, and the relative movement of the housing 20 to the valve seat 14 side is restricted.

  Further, in the present embodiment, a portion on the valve seat 14 side with respect to the first cylindrical portion screw portion 213 of the first cylindrical portion protrusion 212 and a portion on the valve seat 14 side with respect to the yoke lower screw portion 94 of the yoke 90 , Connected by welding. In FIG. 7, a connecting portion between the first cylindrical protrusion 212 and the yoke 90 is indicated by c6. The connection portion c6 is formed with a melted portion w6 in which a portion of the first cylindrical portion protruding portion 212 and a portion of the yoke 90 are melted and cooled and solidified by welding. Thus, the first cylindrical portion 21 and the yoke 90 are fixed so as not to be relatively rotatable. Therefore, "the fall of the axial force F1 due to the relative rotation between the first cylindrical portion 21 and the yoke 90" can be suppressed.

Next, a method of manufacturing the fuel injection device of the present embodiment will be described.
In the present embodiment, the method of manufacturing a fuel injection device differs from the third embodiment in the yoke assembling step and the yoke welding step as follows.
(Yoke assembly process)
The third cylindrical portion is engaged so that an axial force F1 of a predetermined magnitude in a direction in which the first cylindrical portion 21 and the third cylindrical portion 23 approach each other is generated in the first cylindrical portion 21 and the third cylindrical portion 23. The yoke upper locking surface 931 is brought into contact with the stop surface 238, and the yoke lower screw portion 94 is screwed into the first cylindrical portion screw portion 213, and the yoke 90 is assembled to the housing 20.

(Yoke welding process)
The connection portion c6 between the first cylindrical protrusion 212 and the yoke 90 is welded. At this time, a portion on the valve seat 14 side with respect to the first cylindrical portion screw portion 213 of the first cylindrical portion protrusion 212 and a portion on the valve seat 14 side with respect to the yoke lower screw portion 94 of the yoke 90 are welded. Therefore, it can be suppressed that "the yoke 90 extends in the axial direction at the time of welding and the axial force F1 is reduced".

As described above, (6) in the present embodiment, the first tubular portion 21 has the first tubular portion screw portion 213. The third cylindrical portion 23 has a third cylindrical portion engagement surface 238. The yoke 90 is screwed to the yoke upper engagement surface 931 which is locked to the third cylindrical portion engagement surface 238 and whose relative movement toward the valve seat 14 with respect to the housing 20 is restricted, and to the first cylindrical portion screw portion 213. It has a yoke lower thread 94 that is engaged.
(7) The first cylindrical portion 21 and the yoke 90 are fixed so as not to be relatively rotatable. Therefore, "the fall of the axial force F1 due to the relative rotation between the first cylindrical portion 21 and the yoke 90" can be suppressed.

  (8) In the present embodiment, the third cylindrical portion 23 annularly protrudes radially outward from the outer wall on the side opposite to the valve seat 14 with respect to the coil 80, and the third cylindrical portion 23 is formed on the end face opposite to the valve seat 14 It has the 3rd cylinder part projection part 231 in which the cylinder part latching surface 238 is formed. The third cylindrical portion projecting portion 231 forms a coil accommodation chamber 101 for accommodating the coil 80 between the end face on the valve seat 14 side, the inner wall of the yoke 90, and the outer wall of the housing 20. The hole portion 237 connecting the end face on the valve seat 14 side and the end face on the opposite side to the valve seat 14 on the inner side in the radial direction of FIG. The periphery of the coil 80 in the coil storage chamber 101 is covered with resin.

  In the present embodiment, the hole 237 is formed on the radially inner side of the third cylindrical portion engagement surface 238 of the third cylindrical portion protrusion 231. Therefore, the third cylindrical portion engagement surface 238 is formed so as to be continuous over the entire range in the circumferential direction of the third cylindrical portion protruding portion 231 without a part of the circumferential direction being cut away. Therefore, the axial force F1 in the direction in which the first cylindrical portion 21 and the third cylindrical portion 23 approach each other can be made uniform over the entire range in the circumferential direction of the third cylindrical portion engagement surface 238.

Fifth Embodiment
A portion of a fuel injection system according to a fifth embodiment of the present invention is shown in FIG. The fifth embodiment is different from the fourth embodiment particularly in the configuration of the first cylindrical portion 21 and the yoke 90.
In the fifth embodiment, on the outer wall of the first cylindrical portion 21 of the housing 20, the first cylindrical portion engaging surface 211 is formed as in the first embodiment.
The yoke 90 is composed of a first yoke 901 and a second yoke 902. The first yoke 901 and the second yoke 902 are formed in a tubular shape and provided coaxially.
The first yoke 901 has a yoke lower locking surface 911 which is locked to the first cylindrical portion locking surface 211 so that relative movement to the opposite side to the valve seat 14 with respect to the housing 20 is restricted. .

  The second yoke 902 is provided on the side opposite to the valve seat 14 with respect to the first yoke 901, and is locked to the third cylindrical portion engagement surface 238 of the third cylindrical portion protrusion 231 so that the valve relative to the housing 20 is obtained. It has a yoke upper locking surface 931 whose relative movement to the seat 14 side is restricted.

  In addition, the first yoke 901 has a first yoke screw portion 903 on the inner wall of the end opposite to the valve seat 14. The second yoke 902 has a second yoke screw portion 904 which can be screwed to the first yoke screw portion 903 on the outer wall of the end portion on the valve seat 14 side.

  The yoke 90 is configured such that the yoke lower locking surface 911 and the first cylindrical portion locking surface 211 are in contact with each other, and the yoke upper locking surface 931 and the third cylindrical portion locking surface 238 are in contact with each other. The yoke screw portion 903 and the second yoke screw portion 904 are screwed together. Here, in the first cylindrical portion 21 and the third cylindrical portion 23, an axial force F1 is generated which is a force along the axis Ax1 in the direction in which the first cylindrical portion 21 and the third cylindrical portion 23 approach each other. ing. Therefore, a force in a direction in which the first cylindrical portion 21 and the third cylindrical portion 23 contract in the direction of the axis Ax1 acts on the second cylindrical portion 22 forming the magnetic throttling portion 221.

  Further, the yoke lower locking surface 911 is locked to the first cylindrical portion locking surface 211 of the yoke 90, and relative movement of the housing 20 to the opposite side to the valve seat 14 is restricted. Further, the yoke upper locking surface 931 of the yoke 90 is locked to the third cylindrical portion locking surface 238, and the relative movement of the housing 20 to the valve seat 14 side is restricted.

Next, a method of manufacturing the fuel injection device of the present embodiment will be described.
In the present embodiment, the method of manufacturing the fuel injection device differs from the fourth embodiment in the yoke assembling step as follows. Further, in the present embodiment, the method of manufacturing the fuel injection device does not include the yoke welding step shown in the fourth embodiment.

(Yoke assembly process)
The first cylindrical portion 21 and the third cylindrical portion 23 are engaged with the first cylindrical portion so that an axial force F1 of a predetermined magnitude in the direction in which the first cylindrical portion 21 and the third cylindrical portion 23 approach each other is generated. The yoke lower locking surface 911 of the first yoke 901 is in contact with the stop surface 211, and the yoke upper locking surface 931 of the second yoke 902 is in contact with the third cylindrical portion locking surface 238. The yoke 90 is assembled to the housing 20 by screwing 903 and the second yoke screw portion 904.

  As described above, (9) in the present embodiment, the first tubular portion 21 has the first tubular portion engagement surface 211. The third cylindrical portion 23 has a third cylindrical portion engagement surface 238. The yoke 90 is locked to the first cylindrical portion locking surface 211 so that the relative movement of the housing 20 to the opposite side to the valve seat 14 is restricted, and the third cylindrical portion The yoke locking surface 931 is configured such that the relative movement of the housing 20 to the valve seat 14 side is restricted by being locked to the locking surface 238.

  (10) In the present embodiment, the yoke 90 includes a first yoke 901 in which the yoke lower locking surface 911 is formed, and a second yoke 902 in which the yoke upper locking surface 931 is formed. The first yoke 901 has a first yoke screw portion 903 on the inner wall. The second yoke 902 has a second yoke screw portion 904 screwed to the first yoke screw portion 903 in the outer wall.

Sixth Embodiment
A portion of a fuel injection system according to a sixth embodiment of the present invention is shown in FIG. The sixth embodiment differs from the fifth embodiment in the configuration of the yoke 90 in particular.

  In the sixth embodiment, the yoke 90 is formed in a tubular shape, and includes a yoke-over-crimped portion 95 that annularly protrudes radially inward from an inner wall in the axial direction. A yoke upper locking surface 931 facing the third cylindrical portion locking surface 238 is formed on the surface on the valve seat 14 side of the yoke upper caulking portion 95.

  The yoke 90 is placed on the yoke so that the yoke lower locking surface 911 and the first cylindrical portion locking surface 211 are in contact with each other, and the yoke upper locking surface 931 and the third cylindrical portion locking surface 238 are in contact with each other. The caulking portion 95 is caulked to the third cylindrical portion protruding portion 231. Here, in the first cylindrical portion 21 and the third cylindrical portion 23, an axial force F1 is generated which is a force along the axis Ax1 in the direction in which the first cylindrical portion 21 and the third cylindrical portion 23 approach each other. ing. Therefore, a force in a direction in which the first cylindrical portion 21 and the third cylindrical portion 23 contract in the direction of the axis Ax1 acts on the second cylindrical portion 22 forming the magnetic throttling portion 221.

  Further, the yoke lower locking surface 911 is locked to the first cylindrical portion locking surface 211 of the yoke 90, and relative movement of the housing 20 to the opposite side to the valve seat 14 is restricted. Further, the yoke upper locking surface 931 of the yoke 90 is locked to the third cylindrical portion locking surface 238, and the relative movement of the housing 20 to the valve seat 14 side is restricted.

Next, a method of manufacturing the fuel injection device of the present embodiment will be described.
In the present embodiment, the manufacturing method of the fuel injection device is different from that of the fifth embodiment in the yoke assembling process as follows.
(Yoke assembly process)
The first cylindrical portion 21 and the third cylindrical portion 23 are engaged with the first cylindrical portion so that an axial force F1 of a predetermined magnitude in the direction in which the first cylindrical portion 21 and the third cylindrical portion 23 approach each other is generated. The yoke lower locking surface 911 is brought into contact with the stop surface 211. For example, a jig is pressed from the radially outer side of the yoke 90 so that the yoke upper locking surface 931 contacts the third cylindrical portion locking surface 238. The caulking portion 95 is formed, and the yoke 90 is caulked to the third cylindrical portion protruding portion 231.

As described above, (9) in the present embodiment, the first tubular portion 21 has the first tubular portion engagement surface 211. The third cylindrical portion 23 has a third cylindrical portion engagement surface 238. The yoke 90 is locked to the first cylindrical portion locking surface 211 so that the relative movement of the housing 20 to the opposite side to the valve seat 14 is restricted, and the third cylindrical portion The yoke locking surface 931 is configured such that the relative movement of the housing 20 to the valve seat 14 side is restricted by being locked to the locking surface 238.
In the present embodiment, the yoke 90 is assembled to the housing 20 by being crimped to the third cylindrical portion projecting portion 231. Therefore, the yoke 90 can be relatively easily assembled to the housing 20.

Seventh Embodiment
A portion of a fuel injection system according to a seventh embodiment of the present invention is shown in FIG. The seventh embodiment is different from the fifth embodiment in the configuration of the yoke 90 in particular.

  In the seventh embodiment, the first tubular portion 21 has a first tubular portion engagement surface 211. In addition, the yoke 90 is formed in a tubular shape, and has a yoke lower caulking portion 96 that annularly protrudes radially inward from an end on the valve seat 14 side. A yoke lower engagement surface 911 facing the first cylindrical portion engagement surface 211 of the first cylindrical portion 21 is formed on the surface of the yoke lower caulking portion 96 opposite to the valve seat 14.

  The lower surface of the yoke 90 is brought into contact with the yoke upper locking surface 931 and the third cylindrical portion locking surface 238 while the yoke lower locking surface 911 and the first cylindrical portion locking surface 211 are in contact with each other. The first cylindrical portion 21 is caulked at the caulking portion 96. Here, in the first cylindrical portion 21 and the third cylindrical portion 23, an axial force F1 is generated which is a force along the axis Ax1 in the direction in which the first cylindrical portion 21 and the third cylindrical portion 23 approach each other. ing. Therefore, a force in a direction in which the first cylindrical portion 21 and the third cylindrical portion 23 contract in the direction of the axis Ax1 acts on the second cylindrical portion 22 forming the magnetic throttling portion 221.

  Further, the yoke lower locking surface 911 is locked to the first cylindrical portion locking surface 211 of the yoke 90, and relative movement of the housing 20 to the opposite side to the valve seat 14 is restricted. Further, the yoke upper locking surface 931 of the yoke 90 is locked to the third cylindrical portion locking surface 238, and the relative movement of the housing 20 to the valve seat 14 side is restricted.

Next, a method of manufacturing the fuel injection device of the present embodiment will be described.
In the present embodiment, the manufacturing method of the fuel injection device is different from that of the fifth embodiment in the yoke assembling process as follows.
(Yoke assembly process)
The third cylindrical portion is engaged so that an axial force F1 of a predetermined magnitude in a direction in which the first cylindrical portion 21 and the third cylindrical portion 23 approach each other is generated in the first cylindrical portion 21 and the third cylindrical portion 23. The yoke upper locking surface 931 is brought into contact with the stop surface 238, and a jig is pressed from the outside in the radial direction of the end of the yoke 90 on the valve seat 14 side, for example. A yoke lower caulking portion 96 is formed to abut on the surface 211, and the yoke 90 is caulked to the first cylindrical portion 21.

As described above, (9) in the present embodiment, the first tubular portion 21 has the first tubular portion engagement surface 211. The third cylindrical portion 23 has a third cylindrical portion engagement surface 238. The yoke 90 is locked to the first cylindrical portion locking surface 211 so that the relative movement of the housing 20 to the opposite side to the valve seat 14 is restricted, and the third cylindrical portion The yoke locking surface 931 is configured such that the relative movement of the housing 20 to the valve seat 14 side is restricted by being locked to the locking surface 238.
In the present embodiment, the yoke 90 is assembled to the housing 20 by being crimped to the first cylindrical portion 21. Therefore, the yoke 90 can be relatively easily assembled to the housing 20.

Eighth Embodiment
A portion of a fuel injection system according to an eighth embodiment of the present invention is shown in FIG. The eighth embodiment differs from the first embodiment particularly in the configurations of the first cylindrical portion 21, the second cylindrical portion 22, the third cylindrical portion 23, and the yoke 90.

In the eighth embodiment, the first cylindrical portion 21 and the second cylindrical portion 22 are integrally formed of, for example, a magnetic material such as ferritic stainless steel. That is, the first cylindrical portion 21 and the second cylindrical portion 22 are integrally formed of the same material.
The second cylindrical portion 22 has a magnetic throttling portion 221 in a part in the axial direction. The magnetic throttle portion 221 is thinner than other portions in the axial direction of the second cylindrical portion 22.
An end of the second cylindrical portion 22 on the third cylindrical portion 23 side is welded to the third cylindrical portion 23.
The third cylindrical portion 23 is formed separately from the fixed core main body 51 of the fixed core 50 by a separate member. The fixed core main body 51 is provided inside the third cylindrical portion 23 by press fitting, for example.
The third cylindrical portion screw portion 232 is formed over the entire range in the axial direction of the third cylindrical portion protruding portion 231. On the inner wall in the middle of the yoke 90 in the axial direction, a yoke upper screw portion 92 which can be screwed to the third cylindrical portion screw portion 232 is formed.

Next, a method of manufacturing the fuel injection device of the present embodiment will be described.
In the present embodiment, the method of manufacturing the fuel injection device is different from the first embodiment in the housing welding process as follows. Further, in the present embodiment, the method of manufacturing the fuel injection device includes the fixed core press-in step and does not include the yoke welding step described in the first embodiment.
(Fixed core press-in process)
The fixed core body 51 is press-fitted into the third cylindrical portion 23.
(Housing welding process)
The second cylindrical portion 22 and the third cylindrical portion 23 are welded in a state in which the needle 30, the movable core 40, and the like are accommodated inside the housing 20.
(Coil assembly process)
The coil 80 is assembled to the outside of the housing 20 so that the bobbin extension 811 is positioned in the groove 234.

(Yoke assembly process)
The first cylindrical portion 21 and the third cylindrical portion 23 are engaged with the first cylindrical portion so that an axial force F1 of a predetermined magnitude in the direction in which the first cylindrical portion 21 and the third cylindrical portion 23 approach each other is generated. The yoke lower locking surface 911 is brought into contact with the stop surface 211, the yoke upper screw portion 92 is screwed into the third cylindrical portion screw portion 232, and the yoke 90 is assembled to the housing 20.

As described above, (11) the second cylindrical portion 22 is integrally formed with the first cylindrical portion 21. Therefore, the number of members and the number of assembling steps can be reduced.
Also in the present embodiment, the yoke 90 is provided so that an axial force F1 in a direction in which the first cylinder portion 21 and the third cylinder portion 23 approach each other is generated in the first cylinder portion 21 and the third cylinder portion 23. Therefore, a force in a direction in which the first cylindrical portion 21 and the third cylindrical portion 23 contract in the direction of the axis Ax1 acts on the second cylindrical portion 22 forming the magnetic throttling portion 221. Thereby, even if the pressure of the fuel in the fuel passage 100 becomes high, “each member acts on the connecting portion c2 between the second cylindrical portion 22 and the third cylindrical portion 23 or the magnetic throttle portion 221. Force in the direction away from the Therefore, it is possible to suppress stress concentration and breakage at the connection portion c2 between the second cylindrical portion 22 and the third cylindrical portion 23 or the magnetic narrowed portion 221. Therefore, in the present embodiment, as in the first embodiment, high-pressure fuel can be injected while suppressing fuel leakage.

(Other embodiments)
The above-described eighth embodiment shows an example in which the second cylindrical portion 22 and the first cylindrical portion 21 are integrally formed. On the other hand, in the other embodiment of the present invention, the second cylindrical portion 22 may be formed integrally with the third cylindrical portion 23 as long as the magnetic throttling portion 221 is formed, for example, by thinning. Good. In addition, the second cylindrical portion 22 may be integrally formed with the first cylindrical portion 21 and the third cylindrical portion 23.

In the fifth embodiment described above, the first yoke screw portion 903 is formed on the inner wall of the first yoke 901, and the second yoke screw portion 904 is formed on the outer wall of the second yoke 902. On the other hand, in another embodiment of the present invention, the first yoke screw portion 903 is formed on the outer wall of the first yoke 901, and the second yoke screw portion 904 is formed on the inner wall of the second yoke 902. Good.
Further, in another embodiment of the present invention, the housing 20 may be made of metal other than stainless steel, such as iron, aluminum or the like.
Moreover, in the above-mentioned embodiment, the example in which the nozzle 10 and the 1st cylinder part 21 were separately formed was shown. On the other hand, in another embodiment of the present invention, the nozzle 10 and the first cylindrical portion 21 may be integrally formed.

  In addition, in another embodiment of the present invention, the gap forming member 60 may not be provided. In this case, no axial clearance is formed between the contact surface 34 of the collar 33 and the movable core 40 when the valve is in the closed state. In addition, in another embodiment of the present invention, the movable core 40 may be integrally formed with the needle 30. In addition, in another embodiment of the present invention, at least one of the spring seat portion 291, the fixing portion 292, the cylindrical portion 293, and the spring 73 may not be provided.

Moreover, in the above-mentioned embodiment, the example in which the screw coupling member 26 is screwed with the cylindrical member 25 which comprises a fuel inlet part with the inlet part 24 was shown. On the other hand, in another embodiment of the present invention, the screw connection member 26 may be screwed to the fuel pipe 6 so that the cylindrical member 25 and the fuel pipe 6 are in close contact with each other.
In addition, in another embodiment of the present invention, the cylindrical member 25 and the screw coupling member 26 may not be provided.
Further, in another embodiment of the present invention, the fuel injection device may be attached to the engine 2 so as to be pressed against the step surface or the like of the attachment hole 5 with a predetermined force by, for example, a distribution pipe of the fuel rail. .

In addition, in the other embodiments of the present invention, the above-described embodiments can be combined as appropriate as long as there is no constructive inhibiting factor.
The present invention is not limited to a direct injection gasoline engine, and may be applied to, for example, a port injection gasoline engine or a diesel engine.
Thus, this invention is not limited to the said embodiment, It can implement with various forms in the range which does not deviate from the summary.

DESCRIPTION OF SYMBOLS 1 fuel injection device, 10 nozzle, 13 injection hole, 14 valve seat, 20 housing, 21 1st cylinder part, 22 2nd cylinder part, 221 magnetic throttle part, 23 3rd cylinder part, 30 needle, 31 needle main body, 32 Seal part, 40 movable core, 50 fixed core, 71 spring (valve seat side biasing member), 90 yoke, 901 first yoke (Yoke), 902 second yoke (yoke), 80 coil, 100 fuel passage

Claims (14)

An injection hole (13) into which fuel is injected, and a nozzle (10) having a valve seat (14) annularly formed around the injection hole;
The first annular portion (21) having one end connected to the nozzle, and the second end having the other end connected to the other end of the first annular portion to form a magnetic throttling portion (221) in at least a part in the axial (Ax1) direction. An annular portion (22), a third annular portion (23) having one end connected to the other end of the second annular portion, and the first annular portion, the second annular portion, and the first annular portion communicating with the injection hole A housing (20) having a fuel passage (100) formed inside the third annular portion and guiding fuel to the injection hole;
A rod-shaped needle body (31), and a seal portion (32) annularly formed at one end of the needle body so as to be able to abut the valve seat, the seal portion being separated from the valve seat or A needle (30) that opens and closes the injection hole when coming into contact with the valve seat;
A movable core (40) provided to be reciprocally movable in the housing together with the needle;
A fixed core (50) provided opposite to the valve seat with respect to the movable core;
A valve seat side biasing member (71) capable of biasing the needle and the movable core toward the valve seat;
One end side is connected to the first annular portion, the other end side is connected to the third annular portion, and the first annular portion and the third annular portion approach each other to the first annular portion and the third annular portion Axial force (F1) is generated in the second direction so that a force in the direction in which the first annular portion and the third annular portion contract in the axial direction is applied to the second annular portion. A cylindrical yoke (90, 901, 902) provided radially outward of the
A magnetic circuit is provided between the second annular portion and the yoke and forms a magnetic circuit on the first annular portion, the movable core, the fixed core, the third annular portion, and the yoke when energized. A coil (80) capable of sucking a core toward the fixed core and moving the needle opposite to the valve seat;
A fuel injection device (1) comprising: The first annular portion has a first annular portion locking surface (211),
The third annular portion has a third annular portion screw portion (232),
The yoke lower locking surface (911) which is locked to the first annular portion locking surface and whose relative movement to the opposite side to the valve seat with respect to the housing is restricted, and the third annular The fuel injection device according to claim 1, further comprising a yoke upper screw portion (92) screwed to the portion screw portion.   The fuel injection device according to claim 2, wherein the third annular portion and the yoke are fixed so as not to be relatively rotatable.   The third annular portion is a third annular portion in which the third annular portion screw portion is formed on an outer surface in the radial direction from the outer wall on the side opposite to the valve seat with respect to the coil. The fuel injection device according to claim 2 or 3, further comprising a projection (231). The third annular portion projecting portion forms a coil accommodating chamber (101) for accommodating the coil between an end face on the valve seat side, an inner wall of the yoke and an outer wall of the housing, and the third annular portion screw And a hole (235, 236, 237) connecting the end face on the valve seat side and the end face on the opposite side of the valve seat on the radially inner side of the part;
The fuel injection device according to claim 4, wherein a periphery of the coil in the coil storage chamber is covered with a resin. The first annular portion has a first annular portion screw portion (213),
The third annular portion has a third annular portion locking surface (238),
The yoke upper locking surface (931) which is locked to the third annular portion locking surface and whose relative movement to the valve seat with respect to the housing is restricted, and the first annular portion screw portion 2. A fuel injection system according to claim 1, further comprising a yoke lower screw portion (94) screwed into the.   The fuel injection device according to claim 6, wherein the first annular portion and the yoke are fixed so as not to be relatively rotatable. The third annular portion annularly protrudes radially outward from the outer wall on the side opposite to the valve seat with respect to the coil, and the third annular portion locking surface is formed on the end face on the opposite side of the valve seat With a third annular projection (231),
The third annular portion projecting portion forms a coil accommodating chamber (101) for accommodating the coil between an end face on the valve seat side, an inner wall of the yoke, and an outer wall of the housing, and the third annular portion engaging portion It has a hole (237) connecting the end face on the valve seat side and the end face on the opposite side of the valve seat on the radially inner side of the stop face,
The fuel injection device according to claim 6, wherein a periphery of the coil in the coil storage chamber is covered with a resin. The first annular portion has a first annular portion locking surface (211),
The third annular portion has a third annular portion locking surface (238),
A yoke lower locking surface (911) whose relative movement to the opposite side to the valve seat relative to the housing is restricted by locking the yoke to the first annular portion locking surface; The fuel injection device according to claim 1, further comprising: a yoke upper locking surface (931) whose relative movement toward the valve seat relative to the housing is restricted by being locked to the three annular portion locking surfaces. . The yoke includes a first yoke (901) in which the yoke lower locking surface is formed, and a second yoke (902) in which the yoke upper locking surface is formed.
The first yoke has a first yoke screw portion (903) on an inner wall or an outer wall,
The fuel injection device according to claim 9, wherein the second yoke has a second yoke screw portion (904) screwed to the first yoke screw portion on an outer wall or an inner wall.   The fuel injection device according to any one of claims 1 to 10, wherein the second annular portion is integrally formed with at least one of the first annular portion or the third annular portion.   The fuel injection device according to any one of claims 1 to 11, wherein the third annular portion is integrally formed with the fixed core. The needle has an abutment surface (94) that can abut the surface of the movable core on the stationary core side,
The movable core is provided so as to be movable relative to the needle so as to be in contact with the contact surface or separated from the contact surface.
The gap forming member (60) according to any one of claims 1 to 12, further comprising a gap forming member (60) capable of forming an axial gap (CL1), which is an axial gap, between the contact surface and the movable core. Fuel injection device. A fuel injection system in which fuel is supplied from the outside via a fuel pipe (6),
A cylindrical fuel inlet (24, 25) having one end connected to the other end of the third annular portion and the other end connected to the fuel pipe and guiding fuel from the outside to the fuel passage;
A screw connection member (26) screwed to the fuel inlet or the fuel pipe such that the fuel inlet and the fuel pipe are in close contact with each other;
The fuel injection device according to any one of claims 1 to 13, further comprising:

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