The present application claims the benefit under 35 U.S.C. ยง 119 of German Patent Application No. DE 102018203065.0 filed on Mar. 1, 2018, which is expressly incorporated herein by reference in its entirety.
The present invention relates to a method for producing an injector, which injects in particular fuel into an induction pipe or directly into a combustion chamber of an internal combustion engine, and to an injector of this kind.
Injectors for internal combustion engines are available in the related art in various embodiments. Conventionally, spray orifices are provided on injector outlets for injecting and dispersing the fuel. Normally, such spray orifices are produced by laser drilling. In a laser drilling process, however, a precise positioning and design of the spray orifices is possible only to a limited extent. This process, for example, limits the form design essentially to cylindrical spray orifices. Small inaccuracies in the production of the spray orifices may already result in deviations from the optimal spray patterns for the internal combustion engine. Consequently, there may be an increase in the production of pollutants, in particular an increased particle formation, and a reduction in the efficiency as a result of a deteriorated combustion in the internal combustion engine.
An example method of the present invention for producing an injector may have the advantage of achieving a high accuracy in the production of an injector in a simple and efficient manner. It is possible to provide an injector that has a precisely positioned and shaped spray orifice element on the injector outlet having at least one spray orifice in order to allow for an optimized injection and thus an optimized combustion in an internal combustion engine. This is achieved by an example method in accordance with the present invention that has the following steps:
The injector base element may be essentially tubular, the spray orifice element being designed as a plate-shaped component on the downstream end, in the injection direction, of the injector base element. The injector base element may be provided as a standard part. An adaptation to different internal combustion engines may be achieved by different designs of the spray orifice elements. This allows for a particular favorable and efficient production of injectors for a broad spectrum of use. This allows for a very flexible process, which makes possible a cost-effective and quick and thus efficient production of injectors both in individual parts as well as in great lot sizes.
For producing the spray orifice element, a rod having a negative matrix is provided by way of preparation. For this purpose, the negative matrix is produced on an axial end of the rod, which determines a shape of the spray orifice element having the spray orifice in a later method step. Producing the spray orifice element using a negative matrix makes it possible in a particularly advantageous manner to implement various and complex shapes of the spray orifice element as well as of the spray orifice. In addition, it is possible to vary the spray orifice in a simple manner by varying the negative matrix, while otherwise the method of producing the injector remains the same.
The rod having the negative matrix is subsequently inserted into the injector base element and positioned. The negative matrix is for this purpose situated relative to the downstream end, in the injection direction, of the injector base element in such a way that the spray orifice element may be formed on this end.
The spray orifice element is subsequently produced in that a galvanization layer or a galvanized layer is applied on the downstream end, in the injection direction, of the injector base element and on the negative matrix. For this purpose, an injector assemblage made up of the injector base element and the rod having the negative matrix are immersed in a galvanization bath, as a result of which a thin galvanization layer forms on the end of the injector base element and on the negative matrix. The negative matrix may be designed accordingly such that the galvanization produces a spray orifice element that has the spray orifice. By designing the spray orifice element as a galvanization layer directly on the downstream end of the injector base element, it is possible to implement a precise positioning and form design of the spray orifice element and of the spray orifice.
The spray orifice element has at least one spray orifice, through which fuel may be injected into an induction pipe or directly into a combustion chamber. It is also possible to provide for a plurality of spray orifices in a spray orifice element. The method of the present invention makes it possible to implement several different geometries of spray orifices in one spray orifice element without necessitating additional steps in the production of the injector.
Following the production of the spray orifice element by applying the galvanization layer, the rod and the negative matrix are removed in an additional method step. Rod and negative matrix may be removed jointly. It is also possible to remove the rod first and subsequently to remove the negative matrix separately.
The method of the present invention for producing the injector makes it possible to produce injectors of high quality in a simple and cost-effective manner. It is possible to achieve a high quality particularly with respect to the complex geometrical requirements of the spray orifice elements. The position and shape of the spray orifice element and of the spray orifices developed within it are formed precisely and without elaborate subsequent processing. This yields substantial advantages also in the use of the produced injector in an internal combustion engine. The precise form design and positioning of the spray orifice elements and of the spray orifices make it possible to achieve an optimized injection, which has a positive effect on the combustion in the internal combustion engine, in particular with respect to a particle reduction in the exhaust gases.
Preferred developments of the present invention are described herein.
The negative matrix of the spray orifice element is preferably produced by 3D printing. Particularly preferably, a microscaled 3D printing method is used for the production. A 3D-printed negative matrix allows for a particularly cost-effective and flexible design of the spray orifice element including the spray orifice. 3D printing makes it possible to implement a plurality of different form designs in a simple manner both for small and for large lot sizes. Moreover, a very precise production is made possible with respect to dimension and position of the forms.
It is particularly advantageous if the negative matrix is formed from a photopolymer. This for example allows for further processing and optimization of the produced negative matrix following 3D printing by radiation with light in a suitable wavelength range, for example UV light.
Preferably, the negative matrix is positioned relative to the injector base element by way of a fit and/or a shoulder.
Particularly preferably, the rod has a shoulder for this purpose. It is also possible, however, that the injector base element has a shoulder for positioning. A shoulder makes it possible to position the rod and the negative matrix axially in a simple manner. By way of a fit, in particular a transition fit or an interference fit, it is possible to position the negative matrix radially in a simple and precise manner.
Preferably, prior to galvanization, an electrically conductive layer is applied at least on a subsection of the negative matrix. A silver conductive paint or a graphite spray are particularly suitable for this purpose. In the galvanization process, the galvanization layer is applied only on the subsection covered by the electrically conductive layer. For this purpose, the negative matrix may be coated entirely or only partially by the electrically conductive layer. The galvanization layer is respectively formed on the subsection of the negative matrix, whose surface is electrically conductive. This makes it possible, for example in the case of a negative matrix made from an electrically nonconductive material, to form the spray orifice in a simple manner in that accordingly no electrically conductive layer is applied on a subsection of the negative matrix.
Further preferably, the negative form is formed at least partially from an electrically conductive material. This yields the same design possibilities and advantages as when the electrically conductive layer is applied on the negative matrix. In addition to developing the negative matrix partially from an electrically conductive material, it is also possible to apply an electrically conductive layer on a subsection of the negative matrix. This allows for an even more flexible design of the spray orifice element having the spray orifice.
It is furthermore advantageous if the negative matrix has at least one protruding element. The protruding element is designed to form the spray orifice in the spray orifice element in the galvanization process. For example, the protruding element may be designed as a cylindrical pin and may protrude beyond an outlet plane of the injector base element, on which the spray orifice element is also produced.
At least one subsection of the protruding element is preferably not provided with an electrically conductive layer and/or is not formed from an electrically conductive material. This allows for a particularly simple and precise design of the spray orifice since no galvanization layer is formed on this subsection.
The spray orifice element is particularly preferably made from nickel. Nickel is particularly flexibly replaceable and is compatible with a great number of materials of the injector base element. Nickel additionally offers good corrosion protection.
Furthermore preferably, the negative matrix is removed using a mechanical or thermal or chemical treatment. Depending on the material of the negative matrix and the treatment for removal, it is possible to keep the negative matrix intact and reuse it. This has a particularly favorable effect in terms of low costs and low expenditure of effort in producing the injector. Furthermore, it is also possible to remove the negative matrix by destroying it, for example by smelting.
It is furthermore regarded as particularly advantageous if the method furthermore comprises a step of subsequent processing in order to clear the spray orifice and/or for subsequent shaping. For this purpose, the injector base element and the spray orifice element are preferably processed further by machining.
The present invention furthermore relates to an injector for injecting fuel, which is obtainable by the method of the present invention. The injector is preferably designed to inject fuel into an induction pipe or directly into a combustion chamber of an internal combustion engine.
The present invention furthermore relates to an internal combustion engine having an injector, which is producible by the method of the present invention.
Below, the present invention is described with reference to an exemplary embodiment in conjunction with the figures. Functionally identical parts are respectively provided with the same reference symbols in the figures.
To produce the spray orifice element 5 from a galvanization layer, an injector assemblage 10 is immersed in a galvanization bath 51 in a vessel 52. Injector assemblage 10 comprises an injector base element 2, a rod 3 and a negative matrix 4 of the spray orifice element 5 that is to be produced. The injector base element 2 is designed as a standard part and may be used as a basis for injectors having different spray orifice elements 5.
Injector base element 2 is respectively shown in the figures as a sectional drawing, the rod 3 and negative matrix 4 being respectively shown in a non-sectional view.
Injector base element 2 has a through hole 21, in which rod 3 is inserted. Negative matrix 4 is situated on an axial end 31 of rod 3, which determines the shape of spray orifice element 5 and spray orifices 6.
For an optimal definition of the geometries of spray orifice element 5, it is necessary to position negative matrix 4 precisely relative to injector base element 2 prior to galvanization. Negative matrix 4 is axially positioned by way of a shoulder 32 on rod 3. If rod 3 is inserted completely into through hole 21 of injector base element 2, shoulder 32 abuts on injector base element 2. In the radial direction, negative matrix 4 is positioned by a fit of rod 3 and of through hole 21 of injector base element 2.
Spray hole element 5 is produced by galvanization. For this purpose, using a voltage source 53, an electrical voltage is applied to injector assemblage 10 and to galvanization bath 51, which is a nickel electrolyte in the exemplary embodiment shown. As a result, a nickel coating is deposited on those regions of the injector assemblage 10 that are immersed into galvanization bath 51 and that have an electrically conductive surface. In the present case, this is the downstream end 22 of injector base element 2 and a subsection of negative matrix 4, which has an electrically conductive surface.
Producing negative matrix 4 by 3D printing is particularly advantageous for a favorable and flexible production of injector 1. Thus, it is for example possible to achieve very precise dimensions and the greatest variety of shapes of protruding elements 42 and thus of spray orifices 6. Furthermore, it is a simple matter to produce injectors 1 having different spray orifice elements 5 by merely using different negative matrices 4, the method for producing injector 1 remaining unchanged.
A subsection of negative matrix 4 is provided with an electrically conductive layer 41, in the present exemplary embodiment with a silver conductive paint. As shown in
Following the galvanization process, rod 3 and negative matrix 4 may be removed. Rod 3 and negative matrix 4 may be removed simultaneously or one after the other. The removal is performed with the aid of a mechanical or thermal or chemical treatment.
Subsequently, injector 1 may receive further processing.
Number | Date | Country | Kind |
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102018203065.0 | Mar 2018 | DE | national |