The invention relates to a fuel injection system, in particular a common rail injection system, according to the preamble of Claim 1.
Such a fuel injection system is known for example from WO 2004/036029 A1. In the known fuel injection system a damping device for damping pressure pulsations has a sintered metal insert.
DE 103 51 089 A1 discloses method for reducing pressure pulsations in a hydraulic system having a hydraulic flow which is fed to a pulsation damper. The pulsation damper has a plurality of flow channels for dividing the hydraulic flow into a plurality of sub-flows.
EP 1 741 925 A1 concerns an injector that has a damper provided with a number of bores.
JP 08261099 A discloses a pulsation damper in which balls having two different diameters are received in a housing.
DE 10 2006 016 937 A1 discloses a hydraulic pulsation damper in which a filter element formed from foamed polyethylene or sintered metal fabric or glass fibre fabric is received as damping means in a housing.
The damping devices known in accordance with the prior art require a relatively high production effort. Insofar as porous media can be used as damping means, there is a risk of obstruction by dirt particles. In the case of diesel vehicles, there is the further risk of a clogging of the filter medium by precipitated paraffin, in particular in winter at lower temperatures.
One object of the present invention is to overcome the disadvantages according to the prior art. In particular, a fuel injection system comprising a damping device that can be produced easily and cost-effectively is to be specified. In accordance with a further object of the invention, the damping device is to ensure continuous operation of the fuel injection system to the greatest possible extent.
This object is achieved by the features of Claim 1. Expedient embodiments of the invention will emerge from the features of Claims 2 to 13.
In accordance with the invention, it is proposed for the damping device to have a pipe, in which a core that is held at a distance via spacers so as to form an annular gap is provided. The proposed damping device can be produced easily and cost-effectively with use of few parts. The provision of an annular gap makes the damping device unsusceptible to clogging caused by impurities or paraffin contained in the fuel.
In the sense of the present invention, the term “annular gap” means a passage extending substantially over the entire axial length of the core, which is preferably cylindrical. The annular gap has a radial gap width that is substantially constant over the entire axial length of the core. The annular gap has substantially annular inlet and outlet openings. The annular gap can also be interrupted over the periphery thereof, for example by the spacers necessary to hold the core.
It has proven to be advantageous for an axial length l of the core to be 0.5 to 50 mm. A gap width δ given by the difference of an inner diameter d of the pipe and an outer diameter D of the core is expediently between 5 μm to 200 μm. Furthermore, it has proven to be expedient if the outer diameter D of the core is approximately 0.5 to 50 mm, preferably 2 to 20 mm. A damping device formed in this way is characterised in particular for common rail injection systems by excellent damping of pressure pulsations.
In accordance with an advantageous embodiment of the invention, the length l and the gap width δ are selected such that a pressure loss ΔP is between 3 and 12 bar, preferably between 6 and 9 bar, wherein the following is true:
ΔP=[const.*μ*{dot over (v)}*l]/[δ3*D], wherein
μ is a predefined viscosity of the liquid fuel,
{dot over (v)} is a set volume flow rate, and
D is the outer diameter of the core.
The value μ is the viscosity of the used liquid fuel, for example the viscosity of diesel fuel or petrol. The predefined volume flow rate is given in particular from the embodiment of the used injectors, the injection pressure and the injection times. As is clear from the above relationship, the pressure loss ΔP is expediently fixed to a value of 7 bar, for example. With given viscosity of the liquid fuel and also given volume flow rate, a suitable relationship between the length l, the outer diameter D of the core and also the gap width δ is given as a result. By way of example, a suitable gap width δ can be calculated at predefined length l or vice versa. The aforementioned pressure loss ΔP is true for μ=10−3 Ns/m2 and {dot over (v)}=0.25 l/min. For other viscosities μ and/or volume flow rates {dot over (v)}, a suitable pressure loss ΔP can be calculated in accordance with the above formula.
In accordance with an advantageous embodiment, the spacers are distributed uniformly over the outer periphery of the core. In particular, n spacers can be distributed over the outer periphery of the core, in each case distanced from one another by an angle of n/360°.
The spacers may be separate parts which are formed in a rod-like or web-like manner, for example. The core can thus be held in the pipe with a friction fit so as to form an annular gap. The rod- or web-shaped spacers expediently extend over the entire axial length of the core. The core is preferably cylindrical. It may be pointed conically at least at one end.
In accordance with an advantageous embodiment of the invention, the core is formed in one piece with the spacers. Similarly, the pipe can also be formed in one piece with the spacers. The core and/or the pipe is/are expediently produced by means of extrusion. The pipe and/or the core are expediently produced from metal, preferably from high-grade steel.
In accordance with a particularly advantageous embodiment of the invention, the core is shrunk into the pipe. The process of the shrinking can be performed in a simple and cost-effective manner. Compared to the prior art, a damping device for damping pressure pulsations in a fuel injection system can thus be produced in a particularly simple and cost-effective manner.
In accordance with a further embodiment, the spacers are formed from pins that are inserted into bores provided in the core. The bores may be blind holes. The pins extend over the periphery of the core at a predefined spacing. The outer surface of said pins facing the pipe may have a radius that corresponds to the inner radius of the pipe, such that the pins rest against the inner wall of the pipe in a form-fitting manner in the assembled state. The bores run radially with respect to an axis of the core. At least three pins, preferably four pins, are advantageously distributed uniformly over the periphery in an axial plane of the core and act as spacers.
An exemplary embodiment of the invention will be explained in greater detail hereinafter with reference to drawings, in which:
Reference sign 11 denotes a control apparatus, by means of which the injectors 10 are controlled in accordance with a number of parameters. The control apparatus 10 is connected, inter alia, to a pressure limiter 12, a rail pressure sensor 13, a fuel temperature sensor 14 and also the pressure-regulating valve 5 for measurement and/or control purposes. Reference sign 14 denotes damping devices provided downstream on the distributor pipe 8.
The damping devices 14 are mounted here directly on the distributor pipe 8, in each case at an outlet provided for each of the second high-pressure lines 9. The second high-pressure lines 9 are connected to an outlet of the damping devices 14. However, it may also be that the damping devices 14 are arranged in the second high-pressure lines 9 or are fitted at an injector-side end of the second high-pressure lines 9.
The core 17 is expediently shrunk into the pipe 15. This ensures a secure and reliable retention of the core 17 in the pipe 15. Reference sign 18 denotes an annular gap remaining between the spacers 16, the core 17 and the pipe 15.
The annular gap 18 can be interrupted in particular by spacers 16. It can also be divided by the spacers 16 into annular gap portions that each form a separate passage for the fuel F flowing through.
The damping device can have a length from 2 to 50 mm, preferably 5 to 20 mm. The gap width is expediently 5 to 200 μm, preferably 80 to 120 μm. The damping device can be arranged in the region of the distributor pipe 8, in particular at the inlet of the distributor pipe 8 and/or in the second high-pressure lines 9.
In accordance with a particularly advantageous embodiment, the damping element is combined with a pressure measuring arrangement. The pressure upstream and downstream of the damping device can be measured using the pressure measuring arrangement. The momentary mass flow can be determined from the difference between the measured pressures.
The damping device can have a feed pipe upstream of the core and a discharge pipe downstream of the core. A diameter of the feed pipe and discharge pipe are expediently smaller than a diameter of the pipe surrounding the core. A feed pipe and discharge pipe can each be provided with a bore, preferably a threaded bore, for connection of the pressure measuring arrangement.
It can be seen in particular from the pressure profile at the common rail pipe (solid line) that the injector is opened in the time window between 1 ms and 5 ms. Pressure pulsations that have an initial maximum amplitude of approximately 10 bar and then decrease are produced at the injector (dashed line) from the moment 5 ms.
As can be seen from
In the case of the simulations shown in
The proposed damping device in a fuel injection system, in particular in a common rail injection system, thus results in excellent damping of pressure pulsations. It is thus possible to better control the combustion in an internal combustion engine and therefore to avoid an undesirable exhaust gas emission.
Number | Date | Country | Kind |
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10 2012 212 745.3 | Jul 2012 | DE | national |
Filing Document | Filing Date | Country | Kind |
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PCT/EP2013/065318 | 7/19/2013 | WO | 00 |