WO2005119047A1 - Fuel injection valve - Google Patents

Abstract

A fuel injection valve (30) constructed such that a valve body (36), in which a valve piston (35) is slidably inserted, is provided in an injector housing (32) and that a high-pressure fuel is sent from the injector housing (32) into a control pressure chamber (364) in the valve body (36) in which one end of the valve piston (35) is exposed. An annular step section (321A) is provided in the injector housing (32), and an annular projection section (361A) corresponding to the annular step section (321A) is provided on the valve body (36). The annular projection section (361A) is seated on the annular step section (321A) with a seal plate (50), having an orifice (501), in between. A high-pressure fuel is sent from the injector housing (32) side through the orifice (501) into a control pressure chamber (364). Leakage of the high-pressure fuel between the injector housing (32) and the valve body (36) can be reliably prevented.

Description

 Description Fuel injector Technical field

 The present invention relates to a fuel injection valve. Background art

 FIG. 4 is a diagram for explaining a configuration of a conventional fuel injection valve. The fuel injection valve 1 is used for injecting and supplying high-pressure fuel stored in the common rail 12 to the cylinder of a diesel internal combustion engine (not shown). The fuel F in the fuel tank 10 is used for the fuel pump 11. The pressurized fuel is stored in the common rail 12 as high-pressure fuel. The fuel injection valve 1 has an injector housing 2, a nozzle body 3, a nozzle needle 4, a valve piston 5, a valve body 6, a back pressure control unit 7, and a connecting rod 8. A nozzle body 3 is attached to a tip of the injector housing 2 by a nozzle nut 9, and a connecting rod 8 is attached to an upper portion thereof.

 A fuel passage 13 extending from the connecting rod 8 through the injector housing 2 to the nozzle body 3 is formed, and a fuel storage chamber 14 is formed facing the pressure receiving portion 4A of the nozzle needle 4. ing. Further, in the injector housing 2, a fuel recirculation path 15 is formed near the connecting rod 8, which branches off from the fuel path 13 and communicates with the low fuel pressure section through the back pressure control section 7. In the nozzle body 3, the tip of the nozzle needle 4 is seated on the seat 17 connected to the injection hole 16 so that the injection hole 16 is closed and the nozzle needle 4 is lifted from the seat 17. Thus, the injection hole 16 is opened, thereby enabling the start and stop of fuel injection.

A nozzle spring 18 for urging the nozzle 21 in the direction of seating the seat 17 on the nozzle 21 is provided above the nozzle 21. The pin 5 is slidably inserted into the sliding hole 2A of the injector housing 2 and the sliding hole 6A of the valve body 6.

 FIG. 5 is an enlarged sectional view of a main part of the valve body 6 and the back pressure control unit 7. A control pressure chamber 19 is formed in the valve body 6, and a distal end portion ′ of the valve piston 5 faces the control pressure chamber 19 from below.

 The control pressure chamber 19 communicates with an introduction orifice 20 formed in the valve body 6. The introduction side orifice 20 is communicated with the fuel passage 13 via a pressure introduction chamber 21 formed between the valve body 6 and the injector housing 2, and the introduction pressure from the common rail 12 is provided. Is supplied to the control pressure chamber 19. At the lower end of the pressure introduction chamber 21, a sealing member 22 made of a resin material, rubber material, copper material, or other soft material is provided, and the pressure introduction chamber 21 on the high pressure side and the fuel low pressure side are provided. The gap 28 between the injector housing 2 and the valve body 6 is blocked.

 The control pressure chamber 19 is also connected to an opening / closing orifice 23, and the opening / closing orifice 23 can be opened and closed by a valve ball 24 of the back pressure control section 7. The pressure receiving area of the top 5A of the valve piston 5 in the control pressure chamber 19 is larger than the pressure receiving area of the pressure receiving section 4A of the nozzle needle 4 (FIG. 4).

 As shown in FIG. 4, the back pressure control unit includes a magnet 25, an armature 27, a valve ball 24 integral with the armature 27, and a control pressure chamber 19. . By supplying a drive signal to the magnet 25, the magnet 25 sucks the armature 27 against the urging force of the valve spring 26 and moves the valve ball 24 from the opening / closing orifice 23. The control is released, and the pressure in the control pressure chamber 19 can be released to the fuel recirculation path 15 side.

 Therefore, by operating the valve ball 24 as described above, the pressure in the control pressure chamber 19 is controlled, and by controlling the back pressure of the nozzle needle 4 via the valve piston 5, the seat portion of the nozzle needle 4 is controlled. The seat to 17 and the lift from the seat section 17 can be controlled.

In the fuel injection valve 1, the high-pressure fuel from the common rail 12 is connected to the connection rail. It acts on the pressure receiving portion 4A of the nozzle 21 in the fuel reservoir 14 from the groove 8 via the fuel passage 13 and the control pressure via the pressure introduction chamber 21 and the introduction orifice 20. It also acts on the top 5 A of valve piston 5 in chamber 19.

 Therefore, when the control pressure chamber 19 is isolated from the low fuel pressure side by the valve ball 24, the nozzle needle 4 receives the back pressure of the control pressure chamber 19 via the valve piston 5 and the nozzle spring 18 Along with the urging force, the nozzle body 3 is seated on the seat 17 and the injection hole 16 is closed.

 The armature 27 is sucked by supplying a drive signal to the magnet 25 at a predetermined timing, and when the valve ball 24 opens the opening / closing orifice 23, the high pressure in the control pressure chamber 19 increases the opening / closing orifice. Since the fuel is returned to the fuel tank 10 through the fuel recirculation path 15 through 23, the high pressure acting on the top 5A of the valve piston 5 in the control pressure chamber 19 is released, and the nozzle needle 4 is The high pressure acting on the pressure receiving portion 4A lifts the sheet 17 from the sheet portion 17 against the urging force of the nozzle spring 18 and opens the injection hole 16 to inject fuel.

 When the valve ball 24 closes the opening / closing orifice 23 by demagnetizing the magnet 25, the pressure in the control pressure chamber 19 moves the nozzle needle 4 via the valve piston 5 to its seat position (sheet position). Seat to section 17), close injection hole 16 and terminate fuel injection.

 Since the pressure introduction chamber 21 is located at the inlet to the control pressure chamber 19 that controls the fuel injection amount and the injection pressure from the injection hole 16, the fuel pressure in the pressure introduction chamber 21 is equal to the injection pressure. Therefore, a high pressure equivalent to the injection pressure is applied to the seal member 22.

As shown in FIG. 5, a clearance is required between the valve piston 5 and the valve body 6 to allow the valve piston 5 that moves integrally with the nozzle needle 4 to slide in the axial direction. If the valve body 6 is press-fitted into the injector housing 2, the valve body 6 may be slightly deformed inward and hinder the sliding of the valve piston 5. A gap 28 is also provided between 2 and the valve body 6 as a slight clearance. Because the seal structure of the conventional fuel injection valve is as described above, the seal member is pushed toward the gap (low-pressure part) between the engine housing and the valve body by the high pressure in the pressure introduction chamber. It may be deformed and its sealing function may be reduced.

 In order to avoid this problem, JP-A-2003-28021 discloses that a metal back-up ring is installed on the low-pressure side (gap side) of the seal member so that the seal member has a low-pressure side. There is disclosed a configuration for preventing extrusion to the outside. However, according to this configuration, there is a tendency that a failure occurs due to collapse or the like caused by a high pressure load in the pressure release passage of the back coupling. If such a rise of the seal ring occurs, the sealing performance may be degraded.

 In addition, as can be seen from Fig. 5, the control pressure chamber is formed in the small diameter portion below the valve body, so that the valve body is easily deformed, which hinders the smoothness of the sliding movement of the valve piston. There is a problem in that the

 An object of the present invention is to provide a fuel injection valve that can solve the above-described problems in the related art. Disclosure of the invention

 A feature of the present invention for solving the above problem is that a valve body in which a valve piston is slidably inserted is provided in an injector housing, and a valve body in which one end of the valve piston faces one end. A fuel injection valve configured to send high-pressure fuel from the injector housing into the control pressure chamber of the fuel injection valve, wherein an annular step is provided in the injector X. A corresponding annular projection is provided, the annular projection is seated on the annular step portion via a seal plate with an orifice, and high-pressure fuel enters the control pressure chamber from the injector housing side via the orifice. The point is to send.

According to the present invention, since the high-pressure fuel is sent from the injector housing to the control pressure chamber of the valve body through the orifice of the seal plate, the high-pressure fuel leaks into the gap between the injector housing and the valve body. What is sealed Rate is effectively prevented. Brief Description of Drawings

 FIG. 1 is a partially sectional view showing an embodiment of a fuel injection valve according to the present invention. FIG. 2 is an enlarged view of a main part of FIG.

 FIG. 3 is an enlarged plan view of the seal plate of FIG.

 FIG. 4 is a view for explaining the configuration of a conventional fuel injection valve.

 FIG. 5 is an enlarged sectional view showing a main part of the valve body and the back pressure control unit shown in FIG. 4 in an enlarged manner. BEST MODE FOR CARRYING OUT THE INVENTION

 The present invention will be described in more detail with reference to the accompanying drawings. FIG. 1 is a view showing one embodiment of a fuel injection valve according to the present invention, and FIG. 2 is an enlarged view of a main part of FIG. Referring to FIG. 1 and FIG. 2, the fuel injection valve 30 includes an injector housing 32, a nozzle body 33, a nozzle needle 34, a valve piston 35, a valve body 36, and a back. It has a pressure control section 37 and an inlet connector 38. A nozzle body 33 is attached to a tip end of the injector housing 32 by a nozzle nut 39, and an inlet connector 38 is attached to an upper portion thereof. Similarly to the fuel injection valve 1 shown in FIGS. 4 and 5, the fuel injection valve 30 also supplies high-pressure fuel accumulated in the common rail into the cylinder of a diesel internal combustion engine (not shown). It is used for

A fuel passage 38 A extending from the inlet connector 38 to the nozzle body 33 is formed in the injector housing 32, and faces the pressure receiving portion 34 A of the nozzle needle 34. Thus, a fuel reservoir 33A is formed. Since the configuration of this nozzle portion is a known configuration similar to that shown in FIG. 4, detailed description thereof will be omitted. The valve body 36 is a generally cylindrical member having a large diameter portion 36 1 and a small diameter portion 36 2. The valve body 36 has a valve body storage chamber 3 in the injector housing 32. In 21, the valve body 36 is coaxial with the injector housing 32. It is housed so. The valve body 36 has a sliding hole 3 63 opening on the small-diameter portion 36 2 side, and the rear end 3 51 of the valve piston 35 is oiled in the sliding hole 36 3. It is inserted so as to be slidable in the axial direction while maintaining a tight state.

 The sliding hole 3 6 3 extends into the large diameter portion 3 6 1, and one end of the valve screw 3 5 is inserted into the large diameter portion 3 6 1 opposite to the open end of the sliding hole 3 6 3. A control pressure chamber 3 6 4 is formed. The control pressure chamber 364 also communicates with an opening / closing orifice 365, and the opening / closing orifice 365 can be opened and closed by a valve ball 371 of the back pressure control section 37. . The pressure receiving area of the top 35 A of the valve piston 35 in the control pressure chamber 365 is larger than the pressure receiving area of the pressure receiving section 34 A of the nozzle needle 34 (FIG. 1).

 The back pressure control unit 37 includes a magnet 372, an armature 373, and a valve ball 371 integrated with the armature 373, and supplies a drive signal to the magnet 372. As a result, the magnet 372 sucks the armature 373 against the urging force of the valve spring 374, and lifts the valve ball 371 from the opening / closing orifice 365 to control the control chamber. The pressure of 364 can be released to the low-pressure side of the fuel via a fuel recirculation path (not shown). Therefore, by operating the valve ball 371, as described above, the pressure of the control pressure chamber 3664 is controlled, and by controlling the back pressure of the nozzle 21-4 via the valve piston 35, The lift of the nozzle needle 34 can be controlled. Since the configuration of the back pressure control for the fuel injection control described above is known per se, a detailed description thereof will be omitted. Next, a configuration for sending the high-pressure fuel supplied from the inlet connector 38 to the control pressure chamber 364 in the valve body 36 through the injector housing 32 will be described.

 The valve body housing chamber 3 2 1 for housing the valve body 36 is a space having a size and shape corresponding to the valve body 36. The annular projection 3 61 A of the large diameter portion 36 1 is seated on the annular step 3 21 A via the seal plate 50 so that the vane rep body 36 is attached to the valve body storage chamber 3 2. Housed in one.

The valve body 36 housed in the valve body housing chamber 3 21 as described above is The sealing nut 50 is pushed into the valve body chamber 31 by the tightening nut 40, so that the seal plate 50 has an upper surface 321Aa of the annular step 321A and a lower surface of the annular protrusion 361A. It is in close contact with 36 1 A a, and is in a state where the oil-tight state between the upper surface 3 21 A a and the lower surface 36 1 A a can be kept good.

 As shown in FIG. 3, the seal plate 50 is an annular member having an orifice 501, and is here made of a chromium-containing iron-based metal material. Further, in order to stabilize the sealing performance, the seal plate 50 is counterbored on the upper and lower surfaces of the plate, leaving the periphery of the orifice 501 and a part of the inner and outer peripheral portions of the plate. Reference numerals 502 and 503 indicate positioning holes, and by using these holes 502 and 503, the orifice 501 communicates with the fuel passage 38A. In this manner, the seal plate 50 can be easily arranged between the injector housing 32 and the valve body 36.

 As shown in FIG. 2, a high-pressure fuel supply chamber 41 is formed in the annular step portion 3 21 A in the injector housing 32 so as to face the orifice 501. The high-pressure fuel supplied from the inlet connector 38 is guided to the high-pressure fuel supply chamber 41 through the fuel passage 38A. On the other hand, one end communicates with the control pressure chamber 364 in the large diameter portion 361 of the valve body, and the other end faces the orifice 501 on the lower surface 361 Aa. There is provided a passage 42 that is open. As a result, the high-pressure fuel sent from the fuel passage 38 A enters the passage 42 via the orifice 501 and is sent to the control pressure chamber 364. As described above, since the high-pressure fuel from the inlet connector 38 is sent to the control pressure chamber 364 through the orifice 501 of the seal plate 50, the performance can be easily adjusted. .

As described above, the seal plate 50 is in close contact with the upper surface 3 2 1 A a of the annular step 3 2 1 A and the lower surface 3 6 1 A a of the annular protrusion 3 6 1 A, and the upper surface 3 2 1 A a and the lower surface 3 6 1 A Since the oil-tight state between the a and the lower surface is maintained in a good condition, the high-pressure fuel in the high-pressure fuel supply chamber 41 is supplied to the valve body 36 and the injector housing 3. It is sent into the control pressure chamber 364 without leaking between it and 2. Since the control pressure chamber 3 6 4 is formed in the large diameter portion 3 6 1 of the valve body 36, the control pressure chamber 3 6 Even when the high-pressure fuel is filled in 4, the large thickness of the large-diameter portion 361 reduces deformation to a small extent. As a result, the deformation of the entire valve body 36 can be reduced, and the valve piston 35 can be slid smoothly in the sliding hole 365. Industrial applicability

 ADVANTAGE OF THE INVENTION According to this invention, high pressure fuel leakage between an injector housing and a valve body can be reliably prevented, and it contributes to improvement of a fuel injection valve.

Claims

The scope of the claims 1. A valve body in which a valve piston is slidably inserted is provided in an injector housing, and high-pressure fuel is injected into a control pressure chamber in a valve body that faces one end of the valve piston. In a fuel injection valve configured to be fed from a housing, an annular step is provided in the injector housing, and an annular protrusion corresponding to the annular step is provided in the valve body, and the annular protrusion is provided with an orifice. A fuel injection valve which is seated on the annular step portion via the seal plate, and sends high-pressure fuel from the injector housing side into the control pressure chamber via the orifice. 2. The fuel injection valve according to claim 1, wherein the control pressure chamber is formed in the annular protrusion. 3. A fuel passage through which the high-pressure fuel is inserted from the outside and a high-pressure fuel chamber facing the orifice of the seal plate are formed in the injector housing, and the high-pressure fuel in the fuel passage is formed therein. 3. The fuel injection valve according to claim 2, wherein the fuel is supplied to the orifice via the high-pressure fuel chamber. 4. The fuel injection valve according to claim 3, wherein a passage for communicating the control pressure chamber and the orifice is formed in the annular protrusion. 5. The upper and lower surfaces of the seal plate are subjected to a counterboring process except for a periphery of the orifice and a part of an inner peripheral portion and an outer peripheral portion of the seal plate. Item 5. The fuel injection valve according to item 3 or 4. 6. The fuel injection valve according to claim 1, wherein a positioning hole is provided in the seal plate.