The invention concerns a fluid conveyance system for a fluid, comprising a low-pressure conveyance system with a low-pressure pump and a high-pressure conveyance system with a high-pressure pump which are connected via a connecting line, and wherein the fluid conveyance system has a pressure damper. The invention furthermore concerns a method for operating such a fluid conveyance system.
Such a fluid conveyance system is known from DE 10 2011 087 957 A1. This fluid conveyance system is configured as a fuel delivery system of a common rail injection system for an internal combustion engine. The fuel delivery system has a low-pressure conveyance system with a low-pressure pump and a high-pressure conveyance system with a high-pressure pump. The two systems are connected together via a connecting line. Furthermore, the high-pressure conveyance system has a pressure damper connected to a stub line. This stub line is connected to the high-pressure pump.
The invention is based on the object of providing a fluid conveyance system with which a pulsation of the fluid is damped.
This object is achieved in that the pressure damper is arranged in the low-pressure conveyance system and is a hydraulic pressure damper.
The corresponding method for operating such a fluid conveyance system provides that bulk waves and/or pressure waves of the fluid occurring in the low-pressure conveyance system are compensated by a pressure damper formed as a hydraulic pressure damper. This embodiment and this method are based on the knowledge that high pulsations of fluid occur in particular in the low-pressure conveyance system, and greatly strain the components arranged in the low-pressure conveyance system. Also, the pulsations can excite lines in the region of the low-pressure conveyance system to oscillation, and thus provoke noise nuisance. By arranging the pressure damper in the low-pressure conveyance system, the pulsations produced by a high-pressure pump—configured for example as a piston pump—which propagate as bulk waves or pressure waves in particular in the low-pressure conveyance system, are effectively damped. These pulsations are produced by the high-frequency, discontinuous pumping behavior of the piston pump, wherein the pulsations propagate into the low-pressure lines, in particular the connecting lines in the form of a supply line and/or return line, and into the components, such as for example filters, installed in the connecting lines between the low-pressure conveyance system and the high-pressure conveyance system. These bulk waves become pressure waves due to flow resistances in the corresponding lines or choke points in the lines. These bulk waves and pressure waves load said components and disrupt the filling of the pumping element of the high-pressure pump. The hydraulic damper, which may be arranged in the supply line or the return line or in both the supply line and the return line, balances the bulk waves emitted by the high-pressure pump so that no pressure waves result. Depending on the configuration of the fluid conveyance system, a plurality of hydraulic pressure dampers may be arranged in both the supply line and the return line.
In a refinement of the invention, the hydraulic pressure damper has a piston arranged in a cylinder and subjected to the force of compression spring. This embodiment is structurally simple to implement. The piston and the cylinder may be made of a metallic or non-metallic material, for example plastic, while the compression spring is preferably made of spring steel.
In a further embodiment of the invention, the compression spring is arranged in a compression spring chamber, wherein a damper chamber lies opposite the compression spring chamber on the piston side. In a further embodiment of the invention, this damper chamber is connected via a damper supply line to the connecting line, which may be the supply line or the return line. This connection to the connecting line may take place at any arbitrary point on the connecting line, wherein this connection also includes the opening of the connecting line into the high-pressure pump. In particular, the connection and hence the hydraulic pressure damper may be integrated directly in the high-pressure pump.
In a further embodiment of the invention, the compression spring chamber is connected by a compression spring chamber line directly or indirectly to the connecting line downstream of the branch point into the damper supply line. In a refinement of the invention, a check valve or a choke is inserted in the compression spring chamber line, closing towards the compression spring chamber. Where applicable, it is also possible to insert both a check valve and a choke in the compression spring chamber line.
As a result of the bulk waves and/or pressure waves, due to the fluid flowing into the damper chamber, the piston is displaced against the force of the compression spring in the direction of the compression spring chamber, whereby a damping of the bulk wave or pressure wave occurs in the damper chamber and hence also in the connecting line and the components installed in the connecting line. Following the bulk wave or pressure wave, the compression spring and the (fluid) pressure predominating in the compression spring chamber move the piston in the direction of the damper chamber, while the pressure in the enlarging compression spring chamber falls to the constant vapor pressure, which for example may correspond at least approximately to atmospheric pressure. Due to this expansion, by separation out of the fluid, vapor occurs which has a different compression behavior from the fluid and which effectively damps the bulk waves or pressure waves. When the system is set up, the compression spring is configured such that this (together with the pressure predominating in the compression spring chamber) presses the piston back more quickly in the direction of the damper chamber than the bulk wave of the fluid can reach the damper chamber and press the piston back in the direction of the compression spring chamber. This expansion in the compression spring chamber leads to vapor in the compression spring chamber which achieves the desired damping behavior on the next bulk wave. A leakage flowing past the piston in the compression spring chamber is small in comparison with the volume in the compression spring chamber and not therefore relevant for the vapor formation. A bulk wave speeding through the connecting line causes, due to line losses or an optional choke, a differential pressure ΔP=P1−P2. Due to this pressure P1 in the damper chamber, the piston in the hydraulic damper is pressed back against the compression spring and the atmospheric pressure, against the force direction of the compression spring, until the vapor produced by the preceding expansion in the compression spring chamber again transforms into fluid. Due to compression of the fluid, the pressure in the compression spring chamber rises so that the check valve opens and the fluid, essentially the leakage, is pressed into the compression spring chamber line. The same effect occurs on the presence of an outflow choke in the compression spring chamber line. This dynamic process ensures that the compression chamber is not gradually filled completely by leakage. An outflow choke may be used in particular if the return pressure is low and very close to the vapor pressure of the fluid, and if the pressure pulsations, i.e. the bulk waves and/or pressure waves, have a very high frequency.
In a refinement of the invention, the connecting line has a choke between the damper supply line and the compression spring chamber line. This choke is optional and ensures that the above-mentioned pressure difference ΔP is set.
In a refinement of the invention, the fluid conveyance system is a fuel delivery system and the fluid is fuel. Although the subject of the present invention may be used in an arbitrary fluid conveyance system, the preferred application is in a fuel delivery system. This fuel delivery system is for example a common rail injection system, in which fuel supplied by the low-pressure conveyance system to the high-pressure conveyance system is delivered by the high-pressure pump into a high-pressure accumulator. From this high-pressure accumulator, fuel injectors extract the stored fuel for controlled injection into assigned combustion chambers of an internal combustion engine to which the fuel delivery system is fitted.
Further advantageous embodiments of the invention are disclosed in the description of the drawing, which describes in more detail the exemplary embodiments of the invention shown in the figures.
The drawings show:
The fuel fed into the camshaft chamber 10 is introduced, controlled by a metering unit 17, into the pump working chamber 14, while fuel which is not supplied to the pump working chamber 14 by the metering unit 17 or on idling of the internal combustion engine is discharged via a dump valve 18 into the return line 7. The bearings 11a, 11b are also connected to the return line 7, and a constant fuel quantity is conducted from the camshaft chamber 10 through the bearings 11a, 11b in particular for lubrication thereof.
A hydraulic pressure damper 19 is installed in the supply line 6 and/or the return line 7. The pressure damper 19 may be installed directly in the supply line 6 or the return line 7, or also may be integrated in the pump housing 9 of the high-pressure pump 8 in the region of the connection of the supply line 6 or the return line 7. In the context of the invention, it is expressly possible to install an independent hydraulic pressure damper in both the supply line 6 and in the return line 7, or to arrange a hydraulic pressure damper 19 either in the supply line 6 or in the return line 7.
The compression spring chamber 22 is limited opposite the piston 21 by a spring holder 27 on which the compression spring 23 rests and which contains a compression spring chamber line 28. The compression spring chamber line 28 consists of various line portions and opens downstream of the branch point 26 into the connecting line again in the form of a supply line 6 or return line 7. A check valve 29 is placed in the compression spring chamber line 28, which blocks the compression spring chamber line 28 in the direction towards the compression spring chamber 22. The check valve 29 opens at a predefined pressure in the compression spring chamber 22, and fluid present in the compression spring chamber 22 is discharged into the connecting line via the continued compression spring chamber line 28. Between the branch point 26 and the opening of the compression spring chamber line 28, a choke 30 is inserted in the connecting line which creates a differential pressure ΔP=P1−P2 at the branch point 26 or the opening of the compression spring chamber line 28. The pressure P1 is present in the damper chamber 24 via the damper supply line 25, and in stable state presses the piston 21 against the compression spring 23. In unstable state, periodic bulk waves or pressure waves of fuel which are generated in particular by the high-pressure pump 8, enter the damper chamber 24 via the damper supply line 25 and press the piston 21 in the direction of the damper chamber 24 against the force of the compression spring 23 and the pressure predominating in the damper chamber 24, which in rest state preferably corresponds at least approximately to atmospheric pressure. This state is achieved by the upward movement of the pump piston 13. On the subsequent downward movement of the pump piston 13, because the bulk wave is then no longer present, the piston 21 is moved by the compression spring 23 in the direction of the damper chamber 24 and the fuel compressed in the damper chamber 24 expands, forming or separating out vapor. This vapor, together with the fuel, with the involvement of the compression spring 23, provides the desirable damping behavior of the hydraulic pressure damper.
The exemplary embodiment in
Number | Date | Country | Kind |
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10 2013 218 873 | Sep 2013 | DE | national |
Filing Document | Filing Date | Country | Kind |
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PCT/EP2014/069385 | 9/11/2014 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
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WO2015/039948 | 3/26/2015 | WO | A |
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International Search Report for Application No. PCT/EP2014/069385 dated Nov. 17, 2014 (English Translation, 2 pages). |
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20160230726 A1 | Aug 2016 | US |