1. Field of the Invention
The present invention relates to an assemblage, in particular to a fuel injection system for high-pressure injection in internal combustion engines, having a fuel distributor and multiple fuel injection valves.
2. Description of the Related Art
Published European patent application document EP 2 151 572 A2 discloses a fuel distributor rail having multiple fuel injection valves. In order to connect the fuel injection valves to the fuel distributor rail, a shoulder is placed around an undercut on the respective fuel injection valve, tongues being configured on the shoulder. An injector connector on the fuel distributor rail has a cylindrical body into which the upper end of the fuel injection valve is fitted. A retaining bracket is fitted over the cylindrical body, and recesses in the retaining bracket interact with the tongues of the shoulder. Mounting of the associated fuel injection valve on the fuel distributor rail is thereby accomplished.
The configuration known from Published European patent application document EP 2 151 572 A2 has the disadvantage that during operation, the fuel distributor rail is excited to vibrate in the audible frequency range. This occurs principally as a result of noise sources in the fuel injection valves. The solid-borne sound propagates from the fuel injection valves via the cylindrical bodies of the injector connectors, the fuel distributor rail and rail holder, or the like, to the attachment structure, from which obtrusive noise is radiated. This obtrusive noise can in some circumstances even penetrate into the interior of the vehicle. The cylinder head can serve as an attachment structure.
The assemblage according to the present invention has the advantage of enabling decoupling or damping, in terms of vibration engineering, between the fuel injection valves and the fuel distributor. It results in particular in the advantage that noise emissions which do occur can be decreased.
The assemblage is especially suitable for internal combustion engines for direct gasoline injection. The fuel distributor can be configured here in particular as a fuel distributor rail. The fuel distributor can serve on the one hand to distribute fuel to multiple fuel injection valves, in particular high-pressure injection valves. The fuel distributor can serve on the other hand as a common fuel reservoir for the fuel injection valves. The fuel injection valves are connected to the fuel distributor, and inject the fuel necessary for the combustion process under high pressure preferably directly into the combustion chambers of the internal combustion engine. The fuel is compressed via a high-pressure pump, and conveyed in a controlled quantity via a high-pressure line into the fuel distributor.
The fuel distributor can be mounted to an attachment structure, in particular to a cylinder head of the internal combustion engine, directly or also via spacing sleeves and optionally further connecting elements.
Advantageously, the fuel injection valves can be mounted on the cups as suspended fuel injection valves. The holding element for connection can form a snap-lock connection on the one hand with the cup and on the other hand with the fuel injection valve. A partially annular setback of the cup can be configured in the form of a lug or a collar. Advantageously, a collar is correspondingly provided on the fuel injection valve. The quasi-static forces can thereby be transferred for mounting. At the same time, the holding element performs the function such that the relative deflection of the fuel injection valve with respect to the associated cup under the action of operating forces remains below a defined limit value, thereby protecting, for example, an O-ring seal or a Teflon ring seal from damage and wear.
It is advantageous that the abutment surface of the cup and the abutment surface of the fuel injection valve face away from one another. It is further advantageous that the abutment surface of the cup and the support surface of the cup face away from one another. With this embodiment the holding clamp can advantageously be embodied as a U-shaped holding clamp. Upon assembly, the holding clamp can then, so to speak, be clipped onto the cup and onto the fuel injection valve that is inserted into the cup. A reliable connection is thereby formed, and assembly can be carried out in simple fashion.
It is also advantageous that an at least partially annular setback of the cup is configured on the outer side of the cup, at which setback the abutment surface of the cup is configured. The at least partially annular setback can be configured as an annular setback or as a partially annular setback. It is correspondingly advantageous that an at least partially annular collar is configured on the fuel injection valve, at which collar the abutment surface of the fuel injection valve and a support surface facing toward the support surface of the cup are configured. The at least partially annular collar can be configured as a partially annular collar or as an annular collar. In the case of a partially annular configuration of the setback of the cup or collar of the fuel injection valve, multiple respective setbacks or collars can also be provided, on which multiple holding clamps are mounted. The number of holding elements, configured as holding clamps, that mount a fuel injection valve on an associated cup of the fuel distributor can be selected with reference to the particular application instance.
It is further advantageous that at least one of the composite damping elements has a bent outer segment that fits around an outer side of the collar. This reliably prevents contact between the outer side of the collar and the holding clamp. It is correspondingly advantageous that at least one of the composite damping elements is configured as an at least approximately planar composite damping element, and projects beyond an outer side of the collar. This guarantees a certain distance between the holding clamp and the outer side of the collar.
Advantageously, at least one of the composite damping elements is configured as an annular or partially annular composite damping element. Homogeneous impingement upon the composite damping element can thereby be achieved, thus resulting in effective damping over the service life. A circular configuration of the composite damping elements is particularly advantageous in this regard. If this is not possible, for example for assembly reasons in order to avoid a plug connector, then a partially annular contour, for example in the form of a C-shaped ring, can also be selected.
Advantageously, the composite damping element is disposed between the support surface of the fuel injection valve and the support surface of the cup. It is also advantageous that a first composite damping element is disposed between the fuel injection valve and the support surface of the cup, and that a second composite damping element is disposed between the abutment surface of the fuel injection valve and the holding clamp. Direct metal-to-metal contact is avoided with this configuration, by the fact that a composite damping element is always interposed in the mechanical energy transfer path. This results in particularly effective vibration damping.
It is furthermore advantageous that the holding clamp is configured from a composite element having at least one metallic metal layer and at least one damping layer. The holding clamp can then be manufactured by reshaping the composite sheet. The composite sheet can have, for example, a layered structure made up of two metal layers and one elastically deformable layer, in particular an elastomer layer, located therebetween. The construction for vibration decoupling can thereby also be simplified if applicable, the holding clamp made from the composite sheet enabling the insulating effect as a result of its inherent component damping. Depending on the application, however, the holding clamp can also be made from a rigid material.
Advantageously, the composite damping element is configured from at least one metal layer and at least one damping layer. Numerous variants, which differ inter alia in terms of the number of layers, are conceivable here.
Cups 9, 10 are provided on fuel distributor 2. Fuel injection valves 3, 4 are connected to cups 9, 10. Composite damping elements 11, 12 that decouple fuel injection valves 3, 4 from cups 9, 10 are provided.
In this exemplifying embodiment, an annular or partially annular setback 22 of cup 9 is configured on outer side 18 of cup 9, at which setback abutment surface 19 of cup 9 is configured. Also configured on fuel injection valve 3 is an annular or partially annular collar 23 at which abutment surface 21 of fuel injection valve 3 is configured. A support surface is furthermore configured on collar 23. In this exemplifying embodiment, support surface 17 of cup 9 and support surface 24 of fuel injection valve 3 are each oriented perpendicularly to longitudinal axis 15. In addition, support surface 17 of cup 9 and support surface 24 of fuel injection valve 3 face toward one another.
Composite damping element 11 is disposed between support surface 17 of cup 9 and support surface 24 of fuel injection valve 3. In this exemplifying embodiment, composite damping element 11 is configured as a flat composite damping element 11. Composite damping element 11 has metal layers 25, 26 that are each based on a metallic material. A damping layer 27 of composite damping element 11 is provided between metal layers 25, 26. Damping layer 27 can be configured from a rubber, in particular a natural rubber or a synthetic rubber. Damping layer 27 can be connected to metal layers 25, 26 in particular by vulcanizing. This makes possible a multi-layer configuration of composite damping element 11. Direct contact between metal layers 25, 26 is thereby prevented by damping layer 27. Direct metal-to-metal contact is thus prevented at the interface between cup 9 and fuel injection valve 3, since damping layer 27 is disposed in that path, as also depicted schematically with reference to
Assemblage 1 furthermore has a holding element 30 configured as a holding clamp 30. In this exemplifying embodiment, holding clamp 30 is made from a rigid material, in particular a metal. Holding clamp 30 engages on the one hand behind abutment surface 19 of cup 9, and on the other hand behind abutment surface 21 of fuel injection valve 3. Holding clamp 30 thereby pushes collar 30 of fuel injection valve 3 against underside 16 of cup 9. Holding clamp 30 can, for example, be clipped in an assembly direction 31 onto setback 22 of cup 9 and onto collar 23 of fuel injection valve 3 when fuel injection valve 3 is fitted partly into cup 3 in its final position. A certain preload can be exerted in this context onto composite damping element 11 and thus onto damping layer 27.
Acoustic decoupling can thus be implemented by way of composite damping element 11. The connection of fuel injection valve 4 to fuel distributor 2 is configured correspondingly.
A partial decoupling is implemented in the case of the first exemplifying embodiment described with reference to
With this configuration, a first of the composite damping elements 11, 13, namely composite damping element 11, is therefore disposed between fuel injection valve 3 and support surface 17 of cup 9, and a second of the composite damping elements 11, 13, namely composite damping element 13, is disposed between abutment surface 21 of fuel injection valve 3 and holding clamp 30. In addition, the two composite damping elements 11, 13 are configured as planar composite damping elements 13. Composite damping elements 13 each project beyond an outer side 38 of collar 23 of fuel injection valve 3. This ensures that holding clamp 30 is always spaced away from outer side 38 of collar 23.
Composite damping elements 11, 12, 13 each have at least one metal layer 25, 26 and at least one damping layer 27. A preferred configuration is made up of exactly two metal layers 25, 26 and one damping layer 27 disposed therebetween. The preferred configuration is also advantageous for the configuration of holding clamp 30 as described with reference to
A multiple-ply configuration of holding clamp 30 can also be implemented in corresponding fashion. Also possible are configurations of composite damping elements 11, 12, 13 and/or of holding clamp 30 made up of five or more plies, in which metal layers and damping layers alternate.
Substantial advantages can thereby be achieved, depending on the configuration. Partial or complete decoupling of fuel injection valves 3, 4 from fuel distributor 2 is possible. This yields a considerable reduction in solid-borne sound transfer into fuel distributor 2 and thus into attachment structure 5, while at the same time meeting requirements in terms of function and strength.
Noise emissions from fuel distributor 2 thus decrease.
In addition, a comparatively stiff attachment of fuel injection valves 3, 4 can be achieved despite the decoupling. This is because the flexibility of fuel injection valves 3, 4 relative to cups 9, 10 increases only slightly, so that all functional requirements, in particular little relative movement of fuel injection valves 3, 4, and strength requirements, in particular with regard to wear on a sealing O-ring, are met. At the same time, acoustic, functional, and strength requirements that arise from the design of fuel injection valves 3, 4 and of fuel distributor 2 can thereby be met.
Damping layers 27, 28, 37, 41 can be constituted in particular from an elastomer, and connected to metal layers 25, 26, 35, 36, 39, 40 by vulcanization. Connection by vulcanization is especially possible. In addition, an internal damping layer 27 such as the one described inter alia with reference to
The properties of damping layers 27, 28, 37, 41 can be adapted in terms of certain optimization parameters by way of the thickness and/or material properties. Optimization parameters that can be employed are principally the frequency components to be damped, and temperature.
The properties of an external damping layer 27, 28, as described inter alia with reference to
Composite damping elements 11, 12, 13 can be configured as annular or partially annular composite damping elements 11, 12, 13. In the case of a partially annular configuration, multiple composite damping elements can also be provided in a manner distributed over the circumference. Multiple holding clamps that correspond to holding clamp 30 can also be correspondingly provided over the circumference.
The invention is not limited to the exemplifying embodiments described.
Number | Date | Country | Kind |
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10 2012 206 890 | Apr 2012 | DE | national |
Filing Document | Filing Date | Country | Kind |
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PCT/EP2013/056850 | 4/2/2013 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
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WO2013/160068 | 10/31/2013 | WO | A |
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