DE10253721A1 - Fuel injection valve for internal combustion engines - Google Patents

Abstract

Fuel injection valve with a valve body (1) in which a bore (3) is formed, which is delimited at its combustion chamber end by a conical valve seat (12) from which at least one injection opening (16) leads, which opens into the combustion chamber of the internal combustion engine , A valve needle (5) is arranged in the bore (3) so as to be longitudinally displaceable and is guided in the bore (3) in a central guide section (205). A substantially conical valve sealing surface (14) with an annular seat edge (18) is formed on the valve needle (5) at the end on the combustion chamber side. A cylindrical section of the valve needle (105) is formed between the guide section (205) and the valve sealing surface (14) and adjoins the guide section (205). The cylindrical section (105) has a diameter (D¶Z¶) which is 1.0 to 1.5 times the diameter (D) of the seat edge (18) (Figure 1).

Description

The invention is based on a fuel injection valve for internal combustion engines, as is known from the prior art. For example, the DE 100 24 703 A1 a fuel injector having a valve body with a bore formed therein. At its end on the combustion chamber side, the bore is delimited by a conical valve seat, from which at least one injection opening extends, which opens into the combustion chamber of the internal combustion engine in the installed position of the fuel injection valve. A piston-shaped valve needle is arranged in the bore in a longitudinally displaceable manner and is guided in a central section in the bore. At its end on the combustion chamber side, the valve needle has an essentially conical valve sealing surface which interacts with the valve seat and has an annular seat edge at its end facing away from the combustion chamber. A cylindrical section is formed between the valve sealing surface and the guide section of the valve needle, between which fuel and the wall of the bore the at least one injection opening flows.

The well-known fuel injector However, this has the disadvantage that the nozzle needle represents quite rigid component. When opening the valve needle, So when the valve needle lifts off the valve seat and thereby the Releases fuel flow to the injection port and then again through a longitudinal movement interrupts in the opposite direction, it comes on by putting on the Valve needle on the valve seat to heavy mechanical loads the valve needle and the valve body. This favors the wear in Area of the valve seat, which changes over time the opening dynamics the valve needle can.

The fuel injection valve according to the invention with the characterizing features of claim 1, in contrast, the Advantage on that the fuel injector has better opening dynamics and the valve needle faster with otherwise unchanged components in their longitudinal direction is movable. For this purpose, the cylindrical section between the valve sealing surface and the guide section is formed, a diameter which is 1.0 to 1.5 times of the seat diameter is. The moving forces on the valve needle are determined, among other things, by the Seat diameter, as this determines the area that is covered by the hydraulic pressure in the pressure chamber and thereby a Longitudinal force generated, which is exerted on the cylindrical portion of the valve needle. By a suitable adjustment of the seat diameter to the diameter of the cylindrical section achieve that on the one hand the valve needle has a sufficiently high longitudinal elasticity, to the forces occurring at Put on the valve seat to reduce wear and tear to keep. On the other hand, such a diameter is cylindrical Section sufficient to ensure sufficient stability of the valve needle to ensure, so that there is no lateral buckling due to the hydraulic Force on the valve sealing surface comes.

Through the subclaims are advantageous developments of the subject of the inventions possible.

In a first advantageous embodiment on the guide section formed at least one bevel through which the fuel between the wall of the bore and the valve needle through to the injection ports stream can. The cross section of the at least one bevel is at least as big as the cross-section of the annular gap in the area of the cylindrical Section formed between the valve needle and the wall of the bore is. This throttles the guide section even with a relatively small diameter of the cylindrical section the fuel flow to the at least one injection opening.

In a further advantageous embodiment A circumferential groove is provided on the valve needle, facing away from the combustion chamber to the guide section is arranged and the diameter of which is at least approximately that Corresponds to the diameter of the cylindrical section. Through this Groove receives the valve needle has a certain bending elasticity in this area, so that there is a compensation within the valve needle in the event of incorrect positions can and no elevated Friction can occur between this and the wall of the bore.

Other advantages and beneficial Embodiments of the subject of the invention are the description and the drawings.

drawing

In the drawing is a fuel injection valve according to the invention shown. It shows

1 a fuel injector in longitudinal section and

2 an enlarged view of 1 in the area of the valve seat.

In 1 A fuel injection valve according to the invention is shown in longitudinal section. In a valve body 1 is a hole 3 formed, which has a conical valve seat at its combustion chamber end 12 having. From the valve seat 12 go multiple injection ports 16 from, in the installed position of the fuel injector in the combustion chamber Internal combustion engine open. In the hole 3 is a piston-shaped valve needle 5 arranged longitudinally displaceable, the valve needle 5 in a centrally arranged guide section 205 in the hole 3 is led. Starting from the management section 205 the valve needle tapers 5 the valve seat 12 closes and goes under a pressure shoulder 7 into a cylindrical section 105 about. Between the valve needle 5 and the wall of the hole 3 is a pressure room 10 formed by the fuel in the injection ports 16 can flow. The end of the valve needle on the combustion chamber side 5 is as a valve sealing surface 14 trained, being 2 an increase of 1 in the area of the valve sealing surface 14 shows. The valve sealing surface 14 comprises a first conical surface 21 and a second cone surface 22 , between which an annular groove 23 runs. The opening angle of the conical surfaces 21 . 22 and the opening angle of the conical valve seat 12 are coordinated so that when the valve needle is in place 5 on the conical valve seat 12 the boundary line at the transition of the first conical surface 21 to the ring groove 23 is formed as a sealing edge 18 at the valve seat 12 is applied. The valve needle 5 seals when seated on the valve seat 12 at the location of the sealing edge 18 the injection ports 16 against the pressure chamber 10 ,

The hole widens in the end area facing away from the combustion chamber 3 to a spring chamber 25 , in which the spring section facing away from the combustion chamber 305 the valve needle 5 is arranged. The end section of the valve needle facing away from the combustion chamber 5 is from a pressure sleeve 29 limited in which the valve needle 5 is led. The end of the valve needle facing away from the combustion chamber 5 and the pressure sleeve 29 delimit a control room 40 into which an inlet throttle 42 and a flow restrictor 44 lead. Via the inlet throttle 42 is the control room 40 connected to a high pressure chamber and via the outlet throttle 44 connectable with a leak oil chamber. By opening and closing the flow restrictor 44 the pressure in the control room 40 increase or decrease so that the hydraulic force is also applied to the end of the valve needle facing away from the combustion chamber 5 changes accordingly. Between the pressure sleeve 29 and a support ring 32 holding the valve needle 5 also surrounds and attaches itself to one, the valve needle 5 trained ring heel 34 is a spring section 305 the valve needle 5 surrounding closing spring 27 arranged under pressure, the closing spring 27 is designed as a screw pressure error. Because the pressure sleeve 29 to the to the valve body 1 adjacent valve support body is supported by the closing spring 27 a longitudinal force on the valve needle 5 exercised this towards the valve seat 12 applied.

Between the ring heel 34 and the guide section 205 is on the valve needle 5 a groove 37 trained so that the diameter of the valve needle 5 at least approximately the diameter D _{Z of} the cylindrical section at this point 105 equivalent. At the management section 205 are on the valve needle 5 several cuts 20 formed from de NEN in this embodiment, four are arranged distributed over the circumference. The cuts 20 allow fuel flow between the guide section 205 and the wall of the hole 3 and are designed so that the entire cross section of the bevels 20 at least approximately the cross section of the pressure chamber 10 corresponds to that in the region of the cylindrical section 105 is trained. The fuel supply for the pressure chamber 10 takes place via an inlet bore, not shown in the drawing, into the spring chamber 25 , from where the fuel through the bevels 20 in the pressure room 10 flows.

The fuel injector works as follows:
The spring chamber 25 and with it the pressure room 10 is constantly pressurized with fuel under high pressure. Initially, the valve needle 5 in its closed position, ie it lies with its valve sealing surface 14 at the valve seat 12 on. The valve needle 5 is caused by the pressure in the control room 40 which corresponds to the pressure in the pressure chamber 10 corresponds, held in this position and thus closes the injection openings 16 , By opening the flow restrictor 44 the pressure in the control room drops 40 and thus also the hydraulic force on the end of the valve needle facing away from the combustion chamber 5 , The hydraulic force on the valve needle now predominates 5 as caused by the pressure in the pressure room 10 on the valve needle 5 is exercised, especially on the pressure shoulder 7 and the first cone surface 21 , The valve needle is driven by the hydraulic force 5 from the valve seat 12 away and thus enables a fuel flow from the pressure chamber 10 between the valve sealing surface 14 and the valve seat 12 through to the injection ports 16 , By closing the flow restrictor 44 and the inflowing fuel through the inlet throttle 42 After the injection, a fuel pressure builds up again in the control room 40 on the the valve needle 5 pushes back into its closed position. The closing spring 27 plays only a subordinate role in this process, since the hydraulic forces due to the very high injection pressure of sometimes significantly more than 100 MPa compared to the force of the closing spring 27 clearly predominantly. The closing spring 27 mainly serves the valve needle 5 to keep in their closed position when the internal combustion engine is switched off.

Since in modern, high-speed internal combustion engines the speeds of up to 4500 revolutions per minute require very quick successive injections, the valve needle must be used 5 can be moved from their closed position to the open position in a very short time. The longitudinal movement of the valve needle 5 To accelerate, either the forces increase or the mass of the valve needle 5 be humiliated. In addition, must be taken into account that with a very fast movement of the valve needle 5 and correspondingly violent placement on the valve seat 12 strong deformations and vibrations in the valve needle 5 occur, which leads to increased wear between the valve sealing surface 14 and valve seat 12 to lead. For these reasons, the cylindrical section is in the fuel injection valve according to the invention 105 tapered to such an extent that the diameter D _Z corresponds to 1.0 to 1.5 times the diameter of the seat diameter, that is to say the diameter D of the annular seat edge 18 , The resulting increased longitudinal elasticity reduces dynamic force injections when the valve needle is attached 5 on the valve seat 12 and thus reduces wear.

This ratio of the diameter D _{Z of} the cylindrical section 105 to the seat diameter D of the seat edge 18 has proven to be particularly advantageous because the longitudinal elasticity of the cylindrical section 105 for a given hydraulic force on the valve sealing surface 14 is optimal in a certain range, in that the longitudinal elasticity must not be too high or too low, on the one hand to achieve good vibration damping and on the other hand to destabilize the valve needle 5 to avoid by too small a diameter.

By tapering the cylindrical section 105 the valve needle 5 however, the transverse stiffness is inevitably reduced. The groove serves as a compensating element 37 that specifically target the bending stiffness of the valve needle at this point 5 reduced. There should be a slight misalignment of the valve needle 5 in the area of the cylindrical section 105 can come because of the grooving 37 come to a compensation and thus not to increased friction in the spring sleeve 29 , This also reduces the lateral forces in the area of the guide section 205 and thus the friction in this area.

Deviating from the representation in 2 it can also be provided that on the valve sealing surface 14 the ring groove 21 omitted and the first conical surface 21 directly to the second cone surface 22 borders. The sealing edge 18 is in this case at the transition of the two cone surfaces 21 . 22 educated. In addition, it can also be provided that the valve sealing surface 14 is formed by a single, continuous conical surface. The sealing edge 18 is then at the transition of the cylindrical section 105 to the valve sealing surface 14 formed, which requires that the opening angle of the valve sealing surface 14 larger than the opening angle of the conical valve seat 12 have to be.

Claims (6)

Fuel injection valve for internal combustion engines with a valve body ( 1 ) in which a hole ( 3 ) which is formed at its combustion chamber end by a conical valve seat ( 12 ) is limited and at which end at least one injection opening ( 16 ) is provided, which opens into the combustion chamber of the internal combustion engines, and with a valve needle ( 5 ) in the hole ( 3 ) is arranged to be longitudinally displaceable and which in a central guide section ( 205 ) in the hole ( 3 ) is guided with an end of the valve needle on the combustion chamber side ( 5 ) formed, essentially conical valve sealing surface ( 14 ), where on the valve sealing surface ( 14 ) an annular seat edge ( 18 ) is formed, and with a cylindrical portion of the valve needle ( 105 ) between the guide section ( 205 ) and the valve sealing surface ( 14 ) is formed, characterized in that the cylindrical section ( 105 ) has a diameter (D _Z ) that is 1.0 to 1.5 times the diameter (D) of the seat edge ( 18 ) is. Fuel injection valve according to Claim 1, characterized in that in the region of the guide section ( 205 ) at least one bevel ( 20 ) on the valve needle ( 5 ) is provided by the fuel between the wall of the bore ( 3 ) and the valve needle ( 5 ) through the at least one injection opening ( 16 ) can flow in, the buzzer of the cross sections of all bevels being at least as large as the cross section of the pressure chamber ( 10 ) in the area of the cylindrical section ( 105 ). Fuel injection valve according to claim 1, characterized characterized that the seat diameter (D) is 1.9 mm to 2.1 mm. Fuel injection valve according to claim 1, characterized in that facing away from the combustion chamber to the guide section ( 205 ) in the valve needle ( 5 ) a circumferential groove ( 37 ) is provided, the diameter of which is at least approximately the diameter (D _Z ) of the cylindrical section ( 105 ) corresponds. Fuel injection valve according to Claim 1, characterized in that the cylindrical section ( 105 ) directly to the valve sealing surface ( 12 ) borders. Fuel injection valve according to claim 5, characterized in that the sealing edge ( 18 ) at the transition between the cylindrical section ( 105 ) and the valve sealing surface ( 14 ) is arranged.