The present disclosure relates to fuel injectors and, more specifically, to fuel injectors for use with a combustion engine in a motor vehicle.
A fuel injector for injecting fuel into a combustion engine usually comprises a valve opened by means of an electrically driven actuator against the force of a spring. Different constructions are known in the art, comprising electromagnetic or piezo actuators, digital or servo models and actuators for different fuel types such as gasoline or diesel.
US 2006/0255185 A1 describes a fuel injector with an electromagnetic actuator in which the valve comprises a needle and the valve opens when the needle is moved in a direction of a nozzle of the injector.
EP 2011995 A2 relates to a common-rail injector with an outward opening valve element and a servo valve. The servo valve reduces the fuel pressure in a control volume for opening the valve element.
DE 4340874 A1 1995A discloses a fuel injection nozzle for preinjection and main injection which has a nozzle holder in which two closing springs are arranged coaxially, one spring acts continuously on the valve needle via a central pressure bolt and the other spring acts on the valve needle, via a pressure ring surrounding the pressure bolt, once the valve needle has passed through a pretravel. In order to prevent the connection between the low pressure space at the valve needle and the pressure-relieved spring chamber being interrupted in the pretravel position when an intermediate pressure disk—being arranged between the valve needle and the pressure bolt and the pressure ring—comes into axial contact with the pressure ring which is supported on the shoulder of the intermediate disk, bridging channels are arranged at least in the intermediate pressure disk.
An injector is usually designed to work with fuel in a certain range of pressure only. Should there be a defect in the fuel system so that the pressure of the fuel that arrives at the injector is lower, the injector may exhibit reduced performance. In some cases, it may be hard to operate the combustion engine properly if fuel pressure falls lower than a predetermined threshold. However, it is desirable to operate the combustion engine even if fuel pressure is low so that a “limp home” functionality can be implemented which may allow a driver to move the motor vehicle to a service location in case of a problem in the fuel pressurisation system.
It is therefore useful to provide a fuel injector that shows good performance under both normal and reduced fuel pressure conditions.
According to the teachings of the present disclosure, a fuel injector for injecting fuel into a combustion engine may comprise a valve with a movable needle for opening and closing the valve, an actuator for moving the needle into an open position and two springs mounted in parallel to move the needle into a closed position, wherein there is a play between the second spring and the needle when the needle is in the closed position.
That there is a play between the second spring and the needle when the needle is in the closed position means in particular that the needle has a spring seat and the second spring has an end face which comes in mechanical contact with the spring seat when the valve needle is displaced away from the closed position towards the open position and which is spaced apart from the spring seat when the needle is in the closed position.
In particular, the first spring, and only the first spring, may be preloaded when the needle is in the closed position to retain the needle in the closed position while the actuator is de-energized.
The second spring may expediently be unstressed while the needle is in the closed position.
When the actuator is operated, it initially moves the needle against the force of the first spring and further along the travel of the needle against the force of both springs. This allows achieving a sufficient opening of the valve under both standard operating conditions and reduced fuel pressure. This way, a sufficient throughput of fuel through the injector can be ensured.
In some embodiments, the second spring is stiffer than the first spring. This allows reducing the force necessary to open the valve to a small value as long as only the first spring engages with the needle and increase the operating force steplike when the second spring also engages. Through this, safe operation under both reduced and normal fuel pressures may be achieved.
In some embodiments, there is also a needle stopper to confine needle movement to a predetermined travel position in which both springs are engaged. Depending on the design of the injector, the fuel pressure may take influence on the distance the needle is travelled. The needle stopper may make sure that the valve is not opened excessively, even when fuel pressure is high.
In some embodiments, the needle stopper is integrated with the second spring. To this ends, the second spring may be configured such that it will not compress more than a certain travel.
Different types of spring may be used to accomplish the integrated needle stopping functionality.
In some embodiments, the needle stopper is integrated in a valve body of the fuel injector. For example, the needle is received in a cavity of the valve body. The needle and the valve body may be shaped such that the needle comes into engagement with the needle stopper when it reaches the predetermined travel position and the needle stopper blocks further displacement of the needle with respect to the valve body away from the closed position.
In some embodiments, the first spring comprises a helical spring. The helical spring may implement soft spring characteristics so that operation force does not vary much over the travel of the needle. This is especially helpful when the first spring is softer than the second spring.
The second spring may also comprise a helical spring. However, in some embodiments the second spring comprises a cylindrical body with radial recesses. In particular the cylindrical body is a cylinder shell wherein the cylinder shell is perforated by the radial recesses. In this, the second spring may have a high stiffness and it may also implement the above mentioned needle stopper functionality.
In some embodiments, the needle and the springs are mounted coaxially. This may help save installation space so that the injector may be compact or slender.
In some embodiments, the needle is configured to open the valve when the needle is moved towards a nozzle end of the injector. This configuration of an injector is also known as outward opening configuration. The outward opening injector may help to operate the two different springs in accordance with different fuel pressures.
In some embodiments, the actuator comprises a solenoid. The solenoid may be advantageous over a piezo type actuator in that it provides a larger travel of the needle.
In some embodiments, the valve is of the servo type.
In some embodiments, the needle is received in a fuel reservoir of a valve body of the fuel injector. The actuator may supply pressurized fuel to the fuel reservoir so that the fuel pressure forces the needle away from the closed position against the spring force of the first spring or the first and second springs, respectively. The actuator may comprise a second valve for supplying pressurized fuel to the fuel reservoir.
The teachings of the present disclosure will now be described in more detail with reference to the enclosed drawings, in which:
In some embodiments, the injector 100 is of the servo type and that the needle 120 may also be actuated into other positions between the open and the closed position. Injector 100 and valve 110, respectively, may be of the outward opening type where the needle is in the closed position when its upstream end is furthest away from nozzle 115 and the needle 120 must be moved towards the nozzle 115 for opening the valve 110. In other words, the needle 120 is displaceable in flow direction for opening the valve 110.
The actuator 105 is configured to move the needle 120 towards the open position against the force of a first spring 130 and a second spring 135 which are mounted in parallel, wherein each spring 130, 135 drives the needle 120 towards the closed position.
The springs 130, 135 are supported by the valve body 140. In other words, the valve body 140 comprises a spring seat for each of the first and second springs 130, 135.
As shown in
The actuator 105 comprises a second valve 150 for supplying pressurized fuel to the fuel reservoir 141. The pressurized fuel in the fuel reservoir 141 forces the needle 120 away from the closed position against the spring force of the first spring 130 or the first and second springs 130, 135, respectively for opening the valve.
While the first spring 130 engages axially with the valve body 140 and the needle 120 independent of the position of the needle 120, the second spring 135 is configured to leave a play 305 towards the needle 120 when the needle 120 is in the closed position. That is, the second spring 135 does not engage with the needle 120 and does not exert a force between the valve body 140 and the needle 120 when the needle 120 is in the closed position.
Specifically, the needle comprises a seat element 121 which laterally overlaps the first and second springs 130, 135 to provide spring seats for the first and second spring 130, 135, respectively. In the present embodiment, the seat element 121 is fixed to a shaft of the needle 120 which extends axially through the first and second springs 130, 135. When the needle is in the closed position, there is an axial gap—the play 305—between the second spring 135 and the seat element 121. The seat element 121 is in particular positioned upstream of the spring seats of the valve body 140 for the first and second springs 130, 135.
The needle is in the closed position when the actuator 105 is not energized. By energizing the actuator 105, pressurized fuel is supplied to the fuel reservoir 141 via the second valve 150 so that the needle 120 is driven from the closed position towards the open position by the fuel pressure of the pressurized fuel in the fuel reservoir 141. Firstly, as long as the length of the axial gap 305 is non-zero, only the first spring 130 works against the fuel pressure. After the needle 120 has moved far enough to close the axial gap 305 between the seat element 121 and the second spring 135, it may be moved even further along a length 310 on which both the first spring 130 and the second spring 135 engage between the body 140 and the needle 120—both the first spring 130 and the second spring 135 abut the seat element 121—and together work against said opening force effected by the fuel pressure in the fuel reservoir 141.
In some embodiments, the first spring 130 has softer spring characteristics than the second spring 135. The first spring 130 may be of the helical type. The first spring 130 may be preloaded when the needle 120 is in the closed position.
The second spring 135 may be configured to restrict the travel of the needle 120 towards the open position to a certain amount. In this, the second spring 135 also acts as a needle stopper 145.
Number | Date | Country | Kind |
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13187337.4 | Oct 2013 | EP | regional |
This application is a U.S. National Stage Application of International Application No. PCT/EP2014/070828 filed Sep. 29, 2014, which designates the United States of America, and claims priority to EP Application No. 13187337.4 filed Oct. 4, 2013, the contents of which are hereby incorporated by reference in their entirety.
Filing Document | Filing Date | Country | Kind |
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PCT/EP2014/070828 | 9/29/2014 | WO | 00 |