Patent Grant
12065995
The present invention relates to a fuel injection device.
Conventionally, a cylinder injection-type internal combustion engine that uses a fuel injection device to inject fuel directly into a cylinder is used as an internal combustion engine. Furthermore, in recent years, from the viewpoint of reducing exhaust gas, the ability to inject fuel in multiple stages at a high pressure and suppress variations in the fuel injection amount during low pulses is a requirement.
The technology disclosed in Patent Literature 1, for example, exists as technology relating to a conventional fuel injection device. Patent Literature 1 discloses technology that includes a magnetic core, an anchor attracted by the magnetism of the magnetic core, a first flange-shaped portion on which the anchor abuts, a valve body provided downstream of the first flange-shaped portion, and a projecting portion provided upstream of the first flange-shaped portion. Further, Patent Literature 1 discloses technology that includes a rod head provided upstream of the projecting portion, an intermediate member that forms a gap between the first flange-shaped portion and the anchor in a closed-valve state, and a winding spring disposed between the rod head and the intermediate member.
However, in the technology disclosed in Patent Literature 1, a dimensional error in the size of the gap formed between the valve body and the intermediate member arises between individual fuel injection devices. The dimensional error of the gap formed between the valve body and the intermediate member affects a valve opening operation of the valve body. Furthermore, in the technology disclosed in Patent Literature 1, a valve-body stepped portion and the intermediate member become stuck during the valve opening operation, which affects the valve opening operation of the valve body. As a result, in the technology disclosed in Patent Literature 1, variations arise in the fuel injection amount.
In view of the above problems, an object of the present invention is to provide a fuel injection device capable of suppressing variations in a fuel injection amount.
In order to solve the above problems and achieve the object of the present invention, a fuel injection device includes a nozzle holder; a fixed core; an anchor; and a valve member. The nozzle holder is provided with an injection hole-forming member. The fixed core is disposed in the nozzle holder. The anchor is disposed opposite the fixed core. The valve member is movably disposed in the nozzle holder.
The valve member has a plunger rod and a spacer. The plunger rod is provided with a shaft portion that opens and closes an injection hole provided in the injection hole-forming member, and an engaging portion that engages with the anchor during a valve opening operation. The spacer has an accommodating portion in which the engaging portion is accommodated and forms a predetermined gap between the engaging portion and the anchor when the valve is closed. Further, the accommodating portion and the engaging portion are in line contact or point contact.
The fuel injection device having the above configuration enables suppression of variations in a fuel injection amount.
Hereinafter, embodiments of a fuel injection device will be described with reference to
1-1. Configuration of Fuel Injection Device
First, a configuration of a fuel injection device according to a first embodiment (hereinafter referred to as “the present example”.) will be described with reference to
The fuel injection device illustrated in
As illustrated in
[Nozzle Holder]
The nozzle holder 102 is formed in a tubular shape. The injection hole-forming member 103 is attached, through insertion or press-fitting, to a distal end portion, which is one end portion of the nozzle holder 102 in an axial direction Da “hereinafter simply referred to as the “axial direction Da”” along a central axis 100a. An injection hole 112 for injecting fuel is formed in the injection hole-forming member 103.
A valve seat 103a, from/with which the distal end portion of a valve body 117 of the valve member 104 (described below) separates/makes contact, is formed in the injection hole-forming member 103, and the injection hole-forming member 103 seals the fuel when the valve body 117 is seated on the valve seat 103a. In addition, the valve body 117 seals the fuel by abutting on the valve seat 103a, and permits the passage of the fuel by separating from the valve seat 103a.
A guide member 105 is fixed to the distal end portion of the nozzle holder 102 through press-fitting or plastic coupling. The guide member 105 supports an outer peripheral surface of the valve body 117 in the valve member 104 and guides the movement of the valve body 117.
A large-diameter portion 102a having an outer diameter larger than that of the distal end portion is formed at a rear end portion, which is the other end portion of the nozzle holder 102 in the axial direction Da. An accommodating recess 102b is formed in the large-diameter portion 102a. The accommodating recess 102b communicates with the distal end portion by means of a communication hole 102c formed along the axial direction Da of the nozzle holder 102.
The accommodating recess 102b is a bottomed recess that is open on the rear end side of the large-diameter portion 102a and recessed toward the distal end side in the axial direction Da. The anchor 110 (described below) and a portion of the fixed core 101 are arranged in the accommodating recess 102b. One end portion of the second spring 124 is accommodated in the central portion of the bottom portion of the accommodating recess 102b. The accommodating recess 102b slidably supports, on an inner wall surface thereof, the anchor 110 (described below) along the axial direction Da.
A groove 115 is formed in a downstream outer peripheral portion (a radially outer side) of the nozzle holder 102, and a seal member 116 typified by a resin-made chip seal is fitted into the groove 115.
[Valve Member]
The valve member 104 is disposed inside the nozzle holder 102 so as to be movable along the axial direction Da. The valve member 104 includes a plunger rod 113, a spacer 125, the third spring 126, and a rod head 127. Note that a detailed configuration of the valve member 104 will be described below.
[Anchor]
Next, the anchor 110 will be described. The anchor 110 is disposed between the spacer 125 of the valve member 104 and the bottom portion of the accommodating recess 102b in the accommodating recess 102b of the nozzle holder 102. In addition, a minute gap is formed between the outer peripheral surface of the anchor 110 and the inner peripheral surface of the accommodating recess 102b. Therefore, the anchor 110 is arranged to be movable along the axial direction Da in the accommodating recess 102b.
The anchor 110 is formed in a cylindrical shape. An insertion hole 110c (see
The eccentric through-hole 110d is formed in a position eccentric from the central axis of the anchor 110. The eccentric through-hole 110d communicates with a flow path formed by a through-hole 101a of the fixed core 101. The eccentric through-hole 110d forms a flow path through which the fuel passes.
The rear end portion of the second spring 124 abuts on the end surface of the anchor 110 on the distal end side in the axial direction Da. Therefore, the second spring 124 is interposed between the anchor 110 and the accommodating recess 102b of the nozzle holder 102. The fixed core 101 is disposed on the rear end side of the anchor 110 in the axial direction Da.
[Fixed Core]
The fixed core 101 is a member that attracts the anchor 110 by using a magnetic attraction force. The fixed core 101 is formed in a substantially cylindrical shape having irregularities on an outer peripheral surface thereof. The distal end portion of the fixed core 101 in the axial direction Da is press-fitted inside the large-diameter portion 102a of the nozzle holder 102, that is, into the accommodating recess 102b. The nozzle holder 102 and the fixed core 101 are joined by welding. Thus, a gap between the nozzle holder 102 and the fixed core 101 is sealed, and the space inside the nozzle holder 102 is sealed.
In addition, the distal end portion 101b of the fixed core 101 lies opposite an end surface (upper end surface 110a) on the other end side in the axial direction Da of the anchor 110 arranged in the accommodating recess 102b. Note that the rear end side of the fixed core 101 in the axial direction Da protrudes from the accommodating recess 102b of the nozzle holder 102 toward the rear end in the axial direction Da.
The through-hole 101a is formed in the fixed core 101. The through-hole 101a is formed coaxially with the central axis 100a. The through-hole 101a forms a flow path through which fuel passes. A fuel supply port 111, which communicates with the through-hole 101a, is formed at the rear end of the fixed core 101 in the axial direction Da. Fuel is introduced from the fuel supply port 111 toward the through-hole 101a.
Furthermore, a first spring 118 and an adjustment member 119 are arranged on the distal end portion side of the through-hole 101a in the axial direction Da. The first spring 118 is disposed on the distal end portion side of the through-hole 101a with respect to the adjustment member 119. The adjustment member 119 is press-fitted into the through-hole 101a and fixed inside the fixed core 101. The rod head 127, the third spring 126, and the spacer 125 of the valve member 104 are inserted into the through-hole 101a. The through-hole 101a slidably supports the rod head 127 of the valve member 104 (described below) along the axial direction Da.
The first spring 118 is interposed between the adjustment member 119 and the rod head 127 of the valve member 104. The first spring 118 biases the valve member 104 in the axial direction Da toward the distal end portion of the nozzle holder 102.
In addition, the biasing force exerted by the first spring 118 on the valve member 104 can be adjusted by adjusting the fixing position of the adjustment member 119 with respect to the fixed core 101. Thus, it is possible to adjust an initial load with which the valve body 117, which is the distal end portion of the plunger rod 113 in the valve member 104, presses against the valve seat 103a provided to the injection hole-forming member 103 of the nozzle holder 102.
Here, the biasing force by which the first spring 118 biases the valve member 104 toward the distal end portion of the nozzle holder 102 is set larger than the biasing force by which the second spring 124 biases the anchor 110 toward the fixed core 101.
A fuel filter (not illustrated) is provided to an upstream inner peripheral portion (a radially inner side) of the fixed core 101. A seal member 106 represented by an O-ring is attached to an upstream outer peripheral portion (radially outer side) 114 of the fixed core 101, and a protective member 107 for protecting the seal member 106 is attached to a downstream side thereof. The seal member 106 seals a gap between the inner peripheral surface of the fuel pipe (not illustrated) and the upstream outer peripheral portion 114 of the fixed core 101, and prevents leakage of fuel flowing through the fuel pipe.
[Coil]
Next, an electromagnetic coil 108 will be described. The electromagnetic coil 108 is wound around a cylindrical coil bobbin. Further, the electromagnetic coil 108 is wound around a coil bobbin and arranged so as to cover a portion of the outer peripheral surface of the large-diameter portion 102a of the nozzle holder 102 and a portion of the outer peripheral surface of the distal end portion of the fixed core 101. The end portion at the start of winding and the end portion at the end of winding of the electromagnetic coil 108 are connected to a power supply terminal of a connector 136 of the connecting portion 135 described below via wiring (not illustrated). The housing 109 is fixed to the outer periphery of the electromagnetic coil 108.
[Housing]
The housing 109 is formed in a bottomed cylindrical shape. A fitting hole is formed in the bottom portion, which is the distal end portion of the housing 109 in the axial direction Da. The fitting hole is formed in a central portion of the bottom portion. The nozzle holder 102 is inserted into the fitting hole. The open edge of the fitting hole and the outer peripheral surface of the nozzle holder 102 are welded together, for example, over the entire circumference. Thus, the nozzle holder 102 is fixed to the housing 109.
The housing 109 is disposed so as to surround the distal end portion side of the fixed core 101, the coil bobbin, and the outer periphery of the electromagnetic coil 108. The inner peripheral surface of the housing 109 lies opposite the nozzle holder 102 and the electromagnetic coil 108 to form an outer peripheral yoke portion. As described above, a magnetic circuit that includes the fixed core 101, the anchor 110, the nozzle holder 102, and the housing 109 is formed around the electromagnetic coil 108.
[Connecting Portion]
The connecting portion 135 is formed of resin. The connecting portion 135 fills the space between the fixed core 101 and the housing 109. Further, the connecting portion 135 covers the outer peripheral surface excluding the rear end portion of the fixed core 101 on the rear end side in the axial direction Da with respect to the housing 109. The connecting portion 135 is molded so as to form the connector 136, which has a power supply terminal. The terminal is connected to a connection terminal of a plug (not illustrated). Thus, the fuel injection device 100 is connected to a high-voltage power supply or a battery power supply. Energization of the electromagnetic coil 108 is controlled by an engine control unit (ECU).
1-2. Detailed Configuration of Valve Member
Next, a detailed configuration of the valve member 104 will be described with reference to
As illustrated in
As illustrated in
An engaging portion 128 is formed on the rear end portion side in the axial direction Da with respect to the shaft portion 113a. The diameter of the engaging portion 128 is formed larger than the diameter of the shaft portion 113a and the inner diameter of the insertion hole 110c. The engaging portion 128 protrudes outward in the radial direction from the outer peripheral surface of the shaft portion 113a.
The engaging portion 128 lies opposite the upper end surface 110a of the anchor 110. In the closed valve state of the plunger rod 113, a gap G1 is formed between a lower end surface 128b, which is an end surface on one end portion side in the axial direction Da of the engaging portion 128, and the distal end portion 101b of the fixed core 101. Further, the lower end surface 128b of the engaging portion 128 lies opposite the upper end surface 110a at a gap G2 formed by the spacer 125 (described below). A length (G1+G2) obtained by adding together a gap G2 and a gap G1 becomes a gap between the distal end portion 101b of the fixed core 101 and the upper end surface 110a of the anchor 110, that is, a so-called magnetic attraction gap.
In addition, at the time of the valve opening operation, that is, when the positions of the anchor 110 and the plunger rod 113 are displaced relative to each other, the upper end surface 110a of the anchor 110 abuts on the lower end surface 128b of the engaging portion 128, and the anchor 110 and the engaging portion 128 engage with each other (see
An upper shaft portion 129 is formed on the rear end portion side in the axial direction Da with respect to the engaging portion 128. The upper shaft portion 129 protrudes from an upper end surface 128a, which is an end surface on the other end portion side in the axial direction Da of the engaging portion 128, toward the rear end in the axial direction Da. The diameter of the upper shaft portion 129 is formed smaller than the diameter of the engaging portion 128. A connection recess 113b is formed on a rear end surface in the axial direction Da of the upper shaft portion 129. A connection protrusion 127a of the rod head 127 is fitted into a connection recess 113b.
The rod head 127 is formed in a substantially disk shape. The rod head 127 slides in the through-hole 101a of the fixed core 101. The connection protrusion 127a protruding toward a distal end in the axial direction Da is formed at an end portion on one end portion side in the axial direction of the rod head 127, that is, the distal end portion in the axial direction Da. The connection protrusion 127a is fitted into the connection recess 113b of the upper shaft portion 129. As a result, the rod head 127 is connected to the plunger rod 113.
The first spring 118 abuts on the upper end surface on the rear end side in the axial direction Da of the rod head 127. The third spring 126 abuts on the lower end surface on the distal end side in the axial direction Da of the rod head 127. The third spring 126 is interposed between the rod head 127 and a spacer 125 (described below), and biases the spacer 125 toward the anchor 110.
A detailed configuration of the engaging portion 128 and the spacer 125 will be described with reference to
As illustrated in
A small-diameter hole 18 is formed in a small-diameter portion 12. The small-diameter hole 18 penetrates from an upper end surface 15, which is an end surface on the rear end side in the axial direction Da of the spacer 125, to an accommodating portion 16 to be described below. The small-diameter hole 18 communicates with the accommodating portion 16. The upper shaft portion 129 of the plunger rod 113 is inserted into the small-diameter hole 18. The inner diameter of the small-diameter hole 18 is set larger than the diameter of the upper shaft portion 129. The spacer 125 is slidably supported by the upper shaft portion 129.
Further, a stepped surface 13 is formed at a point of the spacer 125 where the large-diameter portion 11 and the small-diameter portion 12 are connected. The stepped surface 13 protrudes substantially vertically outward in the radial direction from the outer peripheral surface of the small-diameter portion 12. The distal end portion side of the third spring 126 in the axial direction Da abuts on the stepped surface 13. The third spring 126 biases the spacer 125 toward the anchor 110. Therefore, the lower end surface 14, which is the end surface on the distal end portion side in the axial direction Da of the spacer 125, abuts on the upper end surface 110a of the anchor 110.
Note that, in the present example, an example in which the third spring 126 is provided has been described, but the present invention is not limited thereto, and the third spring 126 need not be provided.
The accommodating portion 16 is formed in the large-diameter portion 11. The accommodating portion 16 is a recess recessed from the lower end surface 14 of the spacer 125 toward the stepped surface 13. The engaging portion 128 of the plunger rod 113 is accommodated in the accommodating portion 16.
The inner diameter of the accommodating portion 16 is set larger than the diameter of the engaging portion 128 of the plunger rod 113. Therefore, a gap is formed between the outer peripheral surface on the outer side in the radial direction of the engaging portion 128 and an inner wall surface 16a of the accommodating portion 16. A gap between the inner wall surface 16a of the accommodating portion 16 and the outer peripheral surface of the engaging portion 128 is preferably formed larger than a gap between the inner wall surface 19 of the small-diameter hole 18 of the small-diameter portion 12 and the upper shaft portion 129.
A tapered portion 16b is formed at a point where the inner wall surface 19 of the small-diameter hole 18 and the inner wall surface of the accommodating portion 16 are connected. That is, the inner diameter of the accommodating portion 16 on the small-diameter portion 12 side is continuously formed larger toward the distal end portion side in the axial direction Da. The tapered portion 16b lies opposite the upper end surface 128a of the engaging portion 128. Here, a corner portion of the engaging portion 128 on the upper end surface 128a side is formed having a curved R-surface portion 128c. The tapered portion 16b of the accommodating portion 16 abuts on the R-surface portion 128c of the engaging portion 128.
In this manner, by providing the tapered portion 16b formed in a tapered shape at the corner portion of the inner wall of the accommodating portion 16 and providing the R-surface portion 128c formed by rounding the corner portion of the engaging portion 128, the abutment positions 16c and 128d in which the engaging portion 128 and the accommodating portion 16 abut on each other make line contact. Thus, the surface area over which the engaging portion 128 and the accommodating portion 16 abut on each other can be reduced.
The length from the lower end surface 14 of the accommodating portion 16 to the abutment position 16c where the tapered portion 16b abuts on the R-surface portion 128c of the engaging portion 128 is formed larger than the length from the abutment position 128d where the R-surface portion 128c of the engaging portion 128 abuts on the tapered portion 16b to the lower end surface 128b.
Note that, in the present example, an example in which the tapered portion 16b is provided to the accommodating portion 16 and the R-surface portion 128c is provided to the engaging portion 128 has been described, but the present invention is not limited thereto. For example, an R surface portion of which corner portions of the inner wall of the accommodating portion 16 are rounded may be provided, and the corner portions of the engaging portion 128 may be formed in a tapered shape.
Here, the anchor 110 is biased toward the fixed core 101 by the biasing force of the second spring 124. Therefore, the upper end surface 110a of the anchor 110 abuts on the lower end surface 14 of the spacer 125. Note that the biasing force of the second spring 124 is set smaller than the biasing force of the third spring 126. Hence, the anchor 110 is biased toward the distal end side in the axial direction Da by the third spring 126 via the spacer 125. Thus, the movement of the anchor 110 toward the rear end side in the axial direction Da, that is, the movement in the valve opening direction, is restricted by the spacer 125 and the third spring 126.
In the closed valve state, the tapered portion 16b of the accommodating portion 16 abuts on the R-surface portion 128c of the engaging portion 128 of the plunger rod 113, and thus the spacer 125 is disposed in a predetermined position (reference position). In a state where the spacer 125 is disposed at the reference position, the lower end surface 14 of the spacer 125 abuts on the upper end surface 110a of the anchor 110. Thus, a gap G2, a so-called preliminary stroke, can be provided between the lower end surface 128b of the plunger rod 113 and the upper end surface 110a of the anchor 110. That is, the spacer 125 forms a predetermined gap G2 serving as a preliminary stroke between the anchor 110 and the engaging portion 128 of the plunger rod 113.
As described above, when the plunger rod 113 is in the closed valve state, the gap G1 is formed between the lower end surface 128b of the engaging portion 128 and the distal end portion 101b of the fixed core 101. A length (G1+G2) obtained by adding together a gap G2 and a gap G1 becomes a gap between the distal end portion 101b of the fixed core 101 and the upper end surface 110a of the anchor 110, that is, a so-called magnetic attraction gap.
In the closed valve state, a first region A and a second region B are formed between the engaging portion 128 and the spacer 125 so as to have the abutment positions 16c and 128d interposed therebetween. The first region A is a space surrounded by the upper shaft portion 129, the upper end surface 128a of the engaging portion 128, the R-surface portion 128c, and the tapered portion 16b of the accommodating portion 16. The second region B is a space surrounded by the inner wall surface 16a of the accommodating portion 16, the outer peripheral surface of the engaging portion 128, the lower end surface 128b, and the upper end surface 110a of the anchor 110. The first region A and the second region B become substantially closed spaces due to the closed valve state. The first region A and the second region B are preferably set larger than a gap between the upper shaft portion 129 of the plunger rod 113 and the inner wall surface 19 of the small-diameter hole 18.
The abutment positions 16c and 128d, which are boundaries between the first region A and the second region B, are tapered portions 16b in which the accommodating portion 16 is formed in a tapered shape as described above, and the engaging portion 128 is an R-surface portion 128c formed in an R-surface shape. Therefore, the abutment surface areas of the abutment positions 16c and 128d can be made extremely small. Further, the shapes of the accommodating portion 16 and the engaging portion 128 are formed smooth toward the abutment positions 16c and 128d. Thus, the inlet loss of the fluid toward the abutment positions 16c and 128d can be reduced, and the fluid can efficiently flow into the abutment positions 16c and 128d.
A point of the engaging portion 128 connected to the shaft portion 113a is formed having a reduced diameter portion 128f of a reduced diameter. Further, an end portion 110e of the insertion hole 110c of the anchor 110 on the upper end surface 110a (see
1-3. Operation Example of Fuel Injection Device
Next, an operation example of the fuel injection device 100 having the above-described configuration will be described with reference to
When the electromagnetic coil 108 is energized by the ECU, a magnetic flux flows through a magnetic circuit formed by the fixed core 101, the anchor 110, the nozzle holder 102, and the housing 109. A magnetic attraction force for attracting the anchor 110 is then generated in the fixed core 101. When the magnetic attraction force of the fixed core 101 exceeds the biasing force of the third spring 126, the anchor 110 presses the spacer 125 and moves toward the fixed core 101. Therefore, both the anchor 110 and the spacer 125 move toward the rear end side in the axial direction Da. During this time, the distal end portion of the plunger rod 113 abuts on the valve seat 103a of the injection hole-forming member 103.
When the anchor 110 moves to the rear end side in the axial direction Da, the upper end surface 110a of the anchor 110 engages with the engaging portion 128 of the plunger rod 113 as illustrated in
In addition, the size of the gap (magnetic attraction gap) between the anchor 110 and the fixed core 101 decreases by the amount of movement of the anchor 110 to the rear end side in the axial direction Da, and in the example illustrated in
Further, immediately before starting the valve opening operation, a gap G2 is formed between the anchor 110 and the engaging portion 128. Therefore, the anchor 110 abuts on the engaging portion 128 after moving through the gap G2. Thus, the anchor 110 accelerates until same abuts on the engaging portion 128, that is, while moving in the gap G2. As a result, the anchor 110 can made to abut on the engaging portion 128 in a state where the anchor 110 is accelerated.
In this manner, the force applied to the plunger rod 113 from the anchor 110 via the engaging portion 128 can be increased, and the movement of the plunger rod 113 toward the rear end side in the axial direction Da can be promptly started. As a result, the valve opening operation of the plunger rod 113 can be promptly started.
As illustrated in
In addition, because the upper end surface 110a of the anchor 110 abuts on the distal end portion 101b of the fixed core 101, the movement of the anchor 110 toward the rear end side in the axial direction Da is restricted. Note that the plunger rod 113 moves to the rear end side in the axial direction Da under an inertial force, but is pushed back by the biasing force of the first spring 118. Therefore, as illustrated in
In the open valve stationary state, the anchor 110 is attracted to the fixed core 101 by the magnetic attraction force, and the valve member 104 is biased in the valve closing direction by the biasing force of the first spring 118. Therefore, the anchor 110 and the plunger rod 113 abut on each other and become integrated. That is, the lower end surface 128b of the engaging portion 128 of the plunger rod 113 abuts on the upper end surface 110a of the anchor 110, and the size of the gap G2 becomes zero.
Furthermore, because the biasing force of the third spring 126 is smaller than the magnetic attraction force, the third spring 126 cannot push back the anchor 110 to the distal end side in the axial direction Da via the spacer 125. Therefore, the lower end surface 14 of the spacer 125 abuts on the upper end surface 110a of the anchor 110. The gap G3 formed between the abutment position 128d of the R-surface portion 128c of the engaging portion 128 and the abutment position 16c of the tapered portion 16b of the accommodating portion 16 in the spacer 125 is then maintained. Furthermore, because the anchor 110 abuts on the fixed core 101, the size of the gap G1 between the upper end surface 110a of the anchor 110 and the distal end portion 101b of the fixed core 101 becomes zero.
When the drive pulse is turned off in the opened valve state (full lift state) illustrated in
When the spacer 125 moves during the valve opening operation and the valve closing operation of the fuel injection device 100, the volumes of the first region A and the second region B change. Therefore, a force generated by a pressure fluctuation in the first region A and the second region B acts on the spacer 125. Note that, not only the pressure in the first region A and the second region B but also a force generated by shearing of the fuel (fluid) flowing around the spacer 125 act on the spacer 125. Here, the pressure and the shearing force of the fluid are collectively referred to as a fluid force. However, the fluid force acting on the spacer 125 is dominated by the pressure of the low pressure portion rather than the shearing force of the fluid.
Here, at the time of the valve opening operation, the engaging portion 128 may stick to the inner wall surface of the accommodating portion 16 of the spacer 125 due to the pressure fluctuation in the first region A and the second region B, which may affect the movement of the spacer 125. In contrast, in the fuel injection device 100 of this example, as described above, the tapered portion 16b is provided to the accommodating portion 16, the R-surface portion 128c is provided to the engaging portion 128, and the abutment positions 16c and 128d of the accommodating portion 16 and the engaging portion 128 are brought into line contact with each other. Thus, the contact surface areas of the abutment positions 16c and 128d where the sticking phenomenon occurs can be reduced, and the force with which the engaging portion 128 sticks to the accommodating portion 16 caused by the fluid force can be reduced.
Furthermore, the size of the low pressure portion and the dimension of the sliding portion, for example, the gap between the upper shaft portion 129 and the small-diameter hole 18 are different for each individual device, that is, for each fuel injection device, due to variations at the time the fuel injection device is manufactured. For this reason, the fluid force, that is, the amount of change in pressure of the low pressure portion and the dimension of the gap of the sliding portion vary between individual devices, and variations in the valve opening timing and the valve opening speed of the plunger rod 113 also arise. As a result, in the conventional fuel injection device, the injection amount varies for each fuel injection device.
In contrast, in the case of the first region A and the second region B, the first region A and the second region B are formed larger than the gap between the upper shaft portion 129 of the plunger rod 113 and the inner wall surface 19 of the small-diameter hole 18, and it is thus possible to reduce variations between individual devices in the fluid force caused by variations at the time of manufacturing.
As described above, the accommodating portion 16 and the engaging portion 128 are formed smooth toward the abutment positions 16c and 128d. Thus, the inlet loss of the fluid toward the abutment positions 16c and 128d can be reduced, and the fluid can be made to flow efficiently into the abutment positions 16c and 128d.
As described above, because the fluid force acting on the spacer 125 can be reduced, even in a case where the volume of the first region A and the second region B varies for each individual device, variations in the valve opening timing and the valve opening speed of the plunger rod 113 and the spacer 125 can be suppressed. As a result, variations in the injection amounts of the fuel injection device 100 can be suppressed.
Next, a fuel injection device according to a second embodiment will be described with reference to
The fuel injection device according to the second embodiment is different from the fuel injection device 100 according to the first embodiment with regard to the shape of the large-diameter portion 11A of a spacer 125A. Therefore, here, the same reference signs are assigned to portions common to those of the fuel injection device 100 according to the first embodiment, and redundant descriptions will be omitted.
As illustrated in
The large-diameter portion 11A is formed in a substantially cylindrical shape. An accommodating portion 16 that accommodates the engaging portion 128 is formed in the large-diameter portion 11A. In addition, an intermediate portion of the large-diameter portion 11A in the axial direction bulges outward in the radial direction. Therefore, in the accommodating portion 16 formed in the large-diameter portion 11A, the diameter of the intermediate portion is formed larger than the opening diameter on the rear end side in the axial direction Da.
Thus, according to the fuel injection device according to the second embodiment, the volume of a second region B′ can be made larger than that of the fuel injection device 100 according to the first embodiment. Thus, it is possible to suppress pressure fluctuations in the second region B′ during the valve opening operation and the valve closing operation. As described above, the fluid force acting on the spacer 125A is dominated by the fluid pressure rather than the fluid shearing force. As a result, the fuel injection device according to the second embodiment enables the fluid force acting on the spacer 125A to be reduced more than the fuel injection device 100 according to the first embodiment.
Furthermore, by making the diameter of the intermediate portion in the axial direction of the large-diameter portion 11A larger than that on the rear end side, the volume of the second region B′ can be increased without reducing the gap from the through-hole 101a of the fixed core 101 in the open valve state. Thus, it is possible to suppress an increase in the pressure loss of the fluid flowing through the through-hole 101a of the fixed core 101 and the outer peripheral portion of the spacer 125A.
Because the other configurations are similar to those of the fuel injection device 100 according to the first embodiment, descriptions thereof will be omitted. Such a fuel injection device including the spacer 125A also affords the same actions and effects as those of the fuel injection device 100 according to the first embodiment described above.
Note that, in the fuel injection device according to the second embodiment, an example has been described in which, in order to increase the second region B′, a bulging portion expanding radially outward is formed in a portion of the large-diameter portion 11A of the spacer 125A, but the present invention is not limited thereto. For example, the second region B′ may be enlarged by recessing, inward in the radial direction, a portion of a radially outer lateral surface portion of the engaging portion 128. Alternatively, a portion of the large-diameter portion 11A of the spacer 125A may bulge outward, and a portion of the lateral surface portion of the engaging portion 128 may be recessed inward.
Next, a fuel injection device according to a third embodiment will be described with reference to
The fuel injection device according to the third embodiment is different from the fuel injection device 100 according to the first embodiment with regard to the shape of the large-diameter portion of the spacer. Therefore, here, the same reference signs are assigned to portions common to those of the fuel injection device 100 according to the first embodiment, and redundant descriptions will be omitted.
As illustrated in
In addition, the large-diameter portion 11B is formed such that the diameter thereof increases continuously from the rear end portion toward the distal end portion side in the axial direction Da. Note that the largest outer diameter of the large-diameter portion 11B is formed smaller than the inner diameter of the through-hole 101a of the fixed core 101. Thus, the spacer 125B and the valve member 104 can be inserted from the fuel supply port 111 of the fixed core 101, and the assembly work of the fuel injection device 100 can be easily performed.
Similarly to the fuel injection device according to the second embodiment, such a fuel injection device including the spacer 125B also enables the volume of the second region B′ to be increased.
Because the other configurations are similar to those of the fuel injection device 100 according to the first embodiment, descriptions thereof will be omitted. Such a fuel injection device including the spacer 125B also affords the same actions and effects as those of the fuel injection device 100 according to the first embodiment described above.
Note that the present invention is not limited to the embodiments described above and illustrated in the drawings, and various modifications can be made without departing from the spirit of the invention disclosed in the claims.
In the above-described embodiments, examples were described in which the position where the accommodating portion and the engaging portion abut on each other is formed in a tapered shape or a curved surface shape, and the accommodating portion and the engaging portion are in line contact with each other, but the present invention is not limited to such examples. A projection may be provided at any one of the corner portions where the accommodating portion and the engaging portion lie opposite each other, and thus the accommodating portion and the engaging portion may be brought into point contact with each other. Accordingly, the contact surface area between the accommodating portion and the engaging portion can be further reduced, and the accommodating portion and the engaging portion can be prevented from sticking during the valve opening operation.
Note that, in the present specification, words such as “parallel” and “orthogonal” are used, but these words do not strictly mean only “parallel” and “orthogonal”, and may denote “substantially parallel” or “substantially orthogonal” states that include “parallel” and “orthogonal”, within a scope enabling the corresponding functions to be afforded.
| Number | Date | Country | Kind |
|---|---|---|---|
| 2021-080913 | May 2021 | JP | national |
| Filing Document | Filing Date | Country | Kind |
|---|---|---|---|
| PCT/JP2022/004025 | 2/2/2022 | WO |
| Publishing Document | Publishing Date | Country | Kind |
|---|---|---|---|
| WO2022/239329 | 11/17/2022 | WO | A |
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| Number | Date | Country | |
|---|---|---|---|
| 20240151199 A1 | May 2024 | US |
