DE102004054587B3 - Production method e.g. for reproducible micro drillings, having micro drilled hole with diameter of maximally 110micro m and aspect relationship of least 10 with drilling provided by electro-chemical process - Google Patents

Abstract

The method involves having a micro drilled hole with a diameter of maximally 110micro m and an aspect relationship of at least 10. The micro drilling (30) is provided by an electro-chemical process having an electrode (40) provided in a workpiece (10) and a prior pilot hole (20) being of smaller diameter (D20) than the micro drilled hole. The electro-chemical process in presence of an electrolyte (50) creates an electrical potential between the electrode (40) and the workpiece. The electrode is at an external position (52, 54) of the pilot hole and under electro-chemical process clears away a section of a wall of the pilot hole by dissolving in the electrolyte (50), and gradually into the workpiece and the pilot hole (20) is moved forward to expand on a desired diameter (D30) of the micro drilling. An independent claim is included for a device.

Description

The The invention relates to a method and a device for electrochemical Ablation, in particular for the electrochemical drilling of nozzle openings of injectors as well as throttle bores.

The Introduction of holes with defined hydraulic properties (Diameter from 50 to 300 μm) in steel or other metallic alloys by means of eroding used industrially for years, with very small bore diameters (Diameter 50 to 100 μm) the hole depth is severely limited. An application field for the Eroding is the drilling of gasoline and diesel injectors, the due to very high demands on the reproducibility of the hydraulic Properties of the bore with the shortest possible process time is marked. Eroding abuts at bore diameters of 80 to 100 μm and aspect ratios (Relationship of length to diameter of the hole) from 10 to its technically feasible limits.

From the DE 201 20 252 U1 discloses an erosion machine and an electrode guide for the erosion machine, which can produce micro-holes for injectors, wherein a defined position of an electrode can also be produced during advancement of the electrode during the entire erosion process with a certain low tolerance, the electrode guided without play in an electrode guide is.

Furthermore For producing micro-bores, laser boring methods, in particular percussion boring methods, known that under certain conditions with a suitably modulated Laser pulse with pulse durations in the range of a few 0.1 ms holes with diameters in the range of 20 to 800 microns can produce. Such holes can with short production times of less than 1 s are produced, but have only a low precision on, they unsuitable for applications with injectors without post-processing power.

Especially in the production of bores by means of erosion or laser drilling and small bore diameters is a reworking of the holes necessary for obtaining exact hydraulic properties. This is only possible with expensive and complex post-processing Fluidschleifens.

The EP 0 299 143 A1 and the US 4,786,777 disclose a spark erosive drilling method for making injection holes in injectors. In this case, a bore with a larger diameter is produced by means of the drilling process on a laser bore with undersize. Furthermore, these two documents disclose a corresponding device for producing the holes with a laser drilling device and a spark erosion device.

adversely erosion is further that is an electrode of the erosion machine in principle during the implementation the process wears down and so the producible holes in change their properties over time.

Further are for machining workpieces in the prior art electrochemical processes and devices known for their high precision and short process time distinguished.

The Basic principle of electrochemical removal or drilling (ECM - Electro Chemical Machining) corresponds to that of an electrolytic cell, in which a system of workpiece electrolytic tool, the electrolytic Cell forms, in the case of using suitable electrolyte solutions, the anode goes into solution due to charge exchange processes. Between a workpiece (anode) and a tool (cathode) flows through a machining gap an electrolyte solution with the highest possible speed, wherein hydrogen ions are discharged at the cathode. The at the Anode formed metal ions react with appropriate reactants, z. B. in basic electrolytes with OH ions of the electrolyte below Formation of metal hydroxide compounds by the flowing electrolyte taken away and transported away. Areas of application for the electrochemical Abtragen can be found u. a. in aerospace engineering (compressor and turbine blades (film cooling), Turbine disks), in drive technology, the food industry and medical technology. The towering Properties of the electrochemical removal are a great freedom of design also for complex spatial forms, a high removal rate (feed rates up to 3 mm / min) independently from the material hardness of the workpiece to be machined, a finishing of a workpiece in a single operation at the same time high dimensional accuracy and high surface quality, a good repeatability of the component properties, no tool wear, a cold removal process and thus no thermally or deformation-related structural influence, no appreciable machining forces, burr-free machining and no cutting forces.

One field of application of the ECM is the so-called electrochemical drilling, wherein in the electrolyte, the metal of the workpiece as full as possible is constantly dissolved and therefore can be better transported out of the sometimes very narrow gap between the workpiece and the cathode.

The DE 199 60 790 A1 discloses an ECM electrode for electrochemically drilling workpieces, wherein the electrode has a hollow cylindrical shape and the electrode material is a metal having a substantially amorphous structure, whereby this tube serves as an electrical conductor for applying a charge in an ECM process, on the one hand its interior can lead an electrolyte to the processing area in the workpiece. In this electrode, the electrolyte is guided inside the electrode down to its open free end, where the bore is driven forward. Returning the electrolyte takes place in an opposite direction, outside the electrode along the already formed bore instead. To limit the electrochemical action on a lower region of the electrode, this is provided at least in sections with an electrically non-conductive insulating layer.

Above Electrodes are for Holes with outside diameters of about 200 microns still inexpensive to manufacture. But should holes with smaller outside diameters (130 μm and below) are made quickly and inexpensively, so pushes the above Concept to its limits, since this electrode body with a diameter of a maximum of 110 microns and below are necessary (Insulating layer thickness and transport gap width add up to the electrode diameter in addition, each about 5 to about 10 μm).

The US Pat. No. 6,387,242 B1 discloses a method for electrochemically reworking bores in turbine blades of diameters of a few millimeters, wherein a bore inner wall is provided with ribs, ridges or ridges to create a turbulent flow as air passes. For this purpose, an ECM electrode is electrically insulated in sections from the outside and is not electrically isolated in sections. For reworking, the electrode is fully advanced into the bore then fed to an electrolyte and energized the electrode, the bore inner wall is removed relative to the electrically non-isolated locations.

The EP 1 179 379 A1 discloses a method for electrochemical post-processing of a bore taper by means of an electrochemical method. Here, an electrode with electrically non-insulated free end and otherwise electrically insulated surface is advanced to the shoulder of the bore taper, then fed to an electrolyte and energized the electrode, wherein the edges or the edge of the shoulder is smoothed.

The WO 2004/054748 A1 discloses a method for post-processing a Through-hole, in particular a method for cleaning a through-hole, the Z. B. due to oxidation or a surface coating of the relevant component was polluted. In this case, through the through hole a means passed through, the material dissipates inside the bore. This happens z. B. by means of an electrically conductive electrolyte and a at the outlet of the electrolyte under an electrical voltage standing electrode, or an acid. Right at the exit of the agent, the agent is preferably diluted so that there is no material attack outside the hole can come.

It is therefore an object of the invention, a method and an apparatus to disposal to provide, by means of which microbores with reproducible defined hydraulic properties, in particular for nozzle openings of injectors and throttle bores, cost-effective with low process times can be produced. The later ones Microbores are here z. B. for injectors one Diameter smaller than 80 μm up to approx. 110 μm exhibit.

The Invention is by means of a method for producing microbores with aspect ratios solved by at least 10 and diameters smaller than 110μm, the microbore by means of an electrochemical process at a position in workpiece is brought in, already present at the smaller pilot hole is whose hydraulic properties can have a large spread.

Prefers is the pilot hole by means of an ECM electrode and a in the Pre-drilling planned electrolyte reworked, where the electrode at an entry point of the pilot hole in the direction the pilot hole in the workpiece into it lowers. The electrode connected as a cathode increases together with the existing in the pilot hole electrolyte predrilling in an area around them, giving these the desired diameter later Microbore extended.

through the method of the invention it is possible Microbores with defined hydraulic properties in one workpiece be introduced, the microbores on the one hand for the technical Application small enough and on the other hand with short process times can be produced.

According to the invention, for. B. the lack of quality of laser drilling (see above) can be improved by a controlled electrochemical machining such that thereby the desired hydrau The properties of injection openings for injection nozzles can be precisely set and reproducibly designed. By means of an embodiment of the method according to the invention, ie z. As a pre-drilling by means of a laser and an electrochemical post-processing of the laser bore, the unit cost per hole or per workpiece and the production time are more advantageous compared to the prior art. Both laser drilling and electrochemical machining have lower unit costs than eroding or subsequent fluid grinding. Furthermore, there is no risk of clogging of the bore during reworking during electrochemical reworking, as can be the case with fluid grinding.

According to the invention is for a single Nozzle injection opening a (Laser) pre-drilling made, which is smaller than the later target diameter of the Micro hole. In aspect ratios less than about 20 are such laser bores with about 50 microns in diameter can be produced with process times of less than 1 s. Subsequently, will by means of an ECM electrode and the method according to the invention introduced a hole with the desired final dimensions at the same location. Because of the already existing laser pre-drilling a quick exchange the electrolyte away from the machining electrode, it is possible This results in short process times, which are only a fraction of the process time be necessary would be if to work without a pilot hole. Here are cycle times from below one minute.

In a preferred embodiment the invention is for an exchange of the electrolyte in the workpiece the electrolyte from the side into the workpiece filled, from which the electrode penetrates into the workpiece. Here can the electrolyte is inside or outside the electrode the resulting microbore back to the machining gap and through the pilot hole discharged again become. If it's a later one Diameter of the microbore allowed, the electrode z. B. tubular and be made of a metal, with the electrolyte inside through the electrode passes. Furthermore, also with sufficient diameters the microbore, the electrode z. B. be a wire, which of a Pipe, z. B. glass, surrounded, wherein the electrolyte between the wire and the tube is conveyed in the direction of the machining gap and the tube advances along with the wire into the workpiece becomes.

Further The object of the invention by means of a device for manufacturing of reproducible microbores with certain hydraulic Properties solved, wherein the processing section of an ECM device - that is the one Part of the ECM device, which penetrates into the workpiece - a massive body is that for advancing into the workpiece at an external position the pilot hole on the workpiece is positioned and successively along the pilot hole in the workpiece below penetrates an electrochemical removal of the workpiece material. in this connection is the massive body essentially a solid cylinder, but to the realization from other bore cross sections the massive body has a different cross section, such as B. a rectangle or an ellipse, may own.

at this device according to the invention or the method according to the invention the electrolyte is passed along the outside of the electrode for replacement through the resulting microbore in the direction of the machining gap promoted and discharged from there by the remaining pilot hole. through This procedure according to the invention is it is possible very small, high quality, of their hydraulic properties Her, reproducible microbores with diameters of smaller as 80 μm to create. Here it is possible for injectors the corresponding microbores (nozzle openings) with a depth of about 1 mm in such a way that they are the same have hydraulic properties. In particular, by use a solid electrode are so small and high quality Microbores possible, since it is not necessary, for. B. in a hollow electrode, the electrolyte to the machining gap and out of the electrode again back to transport, but the forwarding over the outer gap and the removal through the pre-drilling away from the electrode. through the inventive arrangement the ECM device with an electrode - the only z. B. consists of a solid solid cylinder or full prism, and the Pre-drilling in the workpiece - is it possible a microbore in the workpiece bring in without the electrode for the outward and / or Wegtransport an electrolyte (eg with a surrounding tube for transport of the electrolyte between the inner wall of the tube and outer surface of the Electrode) in addition equipped have to be.

to guide The electrode along the pilot hole, the electrode on her have free end a projection, which in the manufacture of the Microbore leads the electrode in the direction of the pilot hole. in this connection the projection is preferably not electrically or very little conductive, so that by means of the projection no widening of the pilot hole takes place. In a simple embodiment, this projection conical.

For short process times, it is necessary to exchange the electrolyte in the area of the machining gap as quickly as possible. This will be done realizes that between the entry of the electrolyte at the penetration of the electrode and at the outlet of the electrolyte, a pressure difference is applied. So it is z. B. conceivable that the electrolyte is sucked off at one end of the pilot hole, which is opposite to the resulting microbore.

The through the workpiece create electrolyte flow can be used for process control and regulation. This z. B. the flow of electrolyte through the resulting microbore and the remaining pilot hole, from which the current Parameters of an electrochemical process control can be derived. So can z. B. for determining these parameters, the pressure difference between Inlet and outlet of the electrolyte, the flow rate of the electrolyte through the workpiece, the penetration depth of the electrode into the workpiece (including (including the machining gap) already existing length the microbore and remaining length of the pilot hole), by the electrode displaced Volume in the resulting microbore, the density ratio between Electrolyte and a working medium, which in the intended use of the workpiece through the microbore, are taken into account. The evaluation the hydraulic properties of the resulting hole during the Production of the microbore has the advantage that on the later properties the microbore directly in the production of microbore directly influence can be taken as these parameters are closely related to the desired hydraulic functional properties of the subsequent microbore correlate. This creates z. B. less waste in the manufacture of injectors, the z. B. depending on the type six to more than 24 Injection ports exhibit. Influencing process parameters are z. B. the electrolyte flow rate per time unit (over the pressure difference between entry and exit location), the machining gap width, the voltage between cathode and anode, the feed rate the electrode, the electrolyte and the concentration of the electrolyte.

Further it is desirable the electrochemical action of the electrode either on its direct Limit or electrochemical effect only in the environment Allow area of their free end.

This is on the one hand realized by means of a pulsed voltage source, wherein the voltage pulses are selected such that the electrons of the Voltage source only approx. 3 to 10 μm, preferably 5 μm, into the solution can move into it, whereby an electrochemical effect of the electrode in one area about that is not existent. As a result, a microbore is created, for electrons that can move only about 5 microns into the solution of their diameter ago by about 10 microns bigger, than the electrode itself.

A different possibility, the electrochemical action of the electrode to a desired range to limit, is the electrode on its outer surface electrically to isolate. This ensures that the electrochemical effect only occurs at the top of the electrode. By means of such Electrode microbores are feasible, their maximum diameter in the area of the largest diameter the electrode is located. In such an embodiment, however, are recesses longitudinal the electrode necessary to ensure an electrolyte flow, or make sure that the electrode at its tip is the diameter the resulting microbore made slightly larger than their own Diameter is. Such an electrically non-conductive insulating layer can z. B. a layer of AlON or TiAlON, a paint, a Be oxide or a mixed oxide. The layer thickness is preferably one such insulation as small as possible and generally moves between 5 and 10 μm. It is also possible the surface the electrode to oxidize and thereby the surface up to make it electrically non-conductive to a degree. So passivated Form surfaces one final dense film on the surface the electrode, the electrically non-conductive properties increase with the thickness of the oxide layer. Examples of such passivatable Metals are vanadium, chromium, titanium and aluminum.

One for the Invention suitable electrolyte, especially for the related injectors materials is a NaOH solution (caustic soda), at a suitable high throughput through the workpiece without Bubble formation within the holes can be conveyed through the workpiece is. This has the advantage that the flow through the workpiece can be precisely adjusted is because expanding gas bubbles do not hinder the flow.

Further preferred embodiments The invention will become apparent from the other dependent claims.

The Invention will be described below with reference to embodiments with reference to attached drawing explained in more detail. In show the drawing:

1 a block diagram of the method according to the invention or the device according to the invention.

The following explanations on the method according to the invention and on the device according to the invention relate essentially to the reworking of a passage pilot hole with a small diameter. In this case, the passage pilot hole can be reworked so that it is reworked either over its entire length or only up to a certain depth (blind hole). However, it is also possible according to the invention to rework a blind hole pilot hole, but a connecting channel should open into a lower area of the blind hole pilot hole in order to ensure an exchange of an electrolyte and thus to ensure a short production time. Furthermore, the reworking of arcuate pilot holes is possible, in which case corresponding circular arc-shaped electrodes must be used.

l shows the reworking of a pilot hole 20 (Through hole) in a workpiece 10 , z. B. a plate, in which z. B. a fluid throttle with certain hydraulic properties to be introduced. This is achieved by pre-drilling 20 by means of an electrode 40 an ECM device is finished, whereby a peripheral portion (wall) in the workpiece 10 the pilot hole 20 is removed by an electrochemical process.

The ECM device operates as follows: Between the workpiece 10 and the machining electrode 40 becomes an electric field by means of a power supply 60 constructed, with the electrode 40 preferably as a cathode and the workpiece 10 is connected as an anode accordingly. In the pilot hole 20 there is an electrolyte 50 , which is preferably exchanged during the process and by the pre-drilling 20 flowing. In this case, the electrolyte occurs 50 preferably at the location in the workpiece 10 a, on which the electrode 40 begins to sink into the workpiece (entry point 52 ) and is at an opposite end of the pilot hole 20 (exit location 54 ) discharged again. A reverse flow direction of the electrolyte is also feasible. The electrode 40 Now begins to position yourself 52 ( 1 ) in the workpiece 10 to sink in, with everywhere in the places where an electric field exists and an electrolyte 50 between electrode 40 and workpiece 10 is present, the workpiece 10 at these points in the electrolyte 50 dissolve. This is especially in the range of a machining gap 56 he wishes. A feed 90 Now move the electrode 40 in the direction of the pilot hole 20 ever further through the workpiece 10 through, with the pilot hole 20 to a larger diameter, the desired later bore diameter of a microbore 30 , is widened. Replacing the electrolyte 50 ensures the fastest possible removal of the wall around the pilot hole 20 around in the direction of a longitudinal axis 95 the pilot hole 20 What a high feed rate of the electrode 40 as well as always the same chemical conditions in the area of the machining gap 56 ensures.

Further, the ECM device for conveying the electrolyte 50 through the workpiece 10 through, a pump 80 which is preferably equipped with a filter that in the electrolyte 50 dissolved workpiece metal or its hydroxide compounds of a reusable electrolyte 50 separates. In addition, it is advantageous to have a flow of the electrolyte 50 through the workpiece 10 through what to do with a flow meter 70 happens. The reusable electrolyte 50 becomes the entry point after filtering 52 conveyed back.

The choice of the electrolyte 50 depends on the material pairing of the electrolytic cell from the workpiece 10 and electrode 40 , Ideally, they are neither workpiece 10 still electrode 40 , provided that no electric field between electrode 40 and workpiece 10 exists, in the electrolyte 50 solvable. Furthermore, only the material of the workpiece should 10 when applying an electric field between the workpiece 10 and electrode 40 go into solution and not the material of the electrode 40 itself. Preferred electrolytes 50 for ECM procedures are z. For example, saline and nitrate solutions, acids and bases. In particular, acids and bases are suitable for electrochemical drilling. Depending on the material of the workpiece 10 it may be necessary to use another electrolyte 50 to choose. So z. As in the production of nozzle openings for injection nozzles as electrolyte 50 an aqueous NaOH solution (sodium hydroxide) proved to be advantageous. Furthermore, the electrolyte should 50 have a high chemical stability and a low corrosion effect on the working equipment.

In particular, for the electrochemical drilling, it is advantageous if the electrochemical action of the electrode 40 is restricted to its immediate environment or to its free end. This is particularly desirable when the later microbore 30 should have a same cross-section across almost their entire extent. This is z. B. by means of a pulsed voltage source 60 or an at least sectional electrical insulation of the lateral surface of the electrode 40 realized.

A pulsed operation of the power supply 60 As a result, the electrons leaving the cathode are in the electrolyte only for the duration of one pulse 50 wander what the electrochemical erosion effect of the ECM electrode 40 on the way of the advance of the electrons in an area around the electrode 40 limited. On the one hand, this means that the microbore 30 one, twice that distance plus the diameter the electrode 40 having later diameter D ₃₀ and, on the other hand, that the machining gap 56 equal or slightly less than the path of the electrons into the electrolyte 50 , As a result, the bore diameter D _{30 of} the microbore 30 be accurately adjusted by the duration of the voltage pulses. Furthermore, it is possible by the choice of the voltage pulse duration, by means of one and the same electrode 40 , Microbores 30 with different diameters D ₃₀ as well as manufacturing tolerances of the electrode 40 compensate. So it is z. As possible, with short voltage pulses, the electrode 40 completely through the workpiece 10 and thereafter, by extending the voltage pulses, to dilate the bore to a desired diameter D ₃₀ , during the microbore manufacturing process 30 Parameters are determinable, the conclusions about the later properties of the microbore 30 allow. In addition, it is possible the electrode 40 laterally (perpendicular to the hole) to move and so produce holes with arbitrary shapes.

Another way, the electrical effect of the electrode 40 to limit, consists in an electrical insulation of the electrode 40 at those locations where electrochemical effects of the electrode 40 are undesirable. This is z. B. provided that the microbore 30 should have a uniform diameter cross-section, in the region of the lateral surface of the electrode 40 necessary. This limits the electrochemical action of the electrode 40 only on the free end, which the pilot hole 20 refinishing. Preferably, the thickness of the insulating layer is as small as possible and is generally between 4 to 10 microns. Such an insulating layer, for. TiAlON-based, can be applied to the electrode 40 be sputtered or steamed. In a preferred embodiment of the invention is on the entire surface of the electrode 40 applied an electrically non-conductive insulating layer. In addition, it is at a suitable electrode 40 possible to realize the insulating layer by means of an oxide layer of the electrode material. A so-called passivated surface of the electrode material forms a final dense film on the electrode surface and has the advantage that the electrode does not become thicker by an insulating layer, which makes it possible to realize very thin electrodes. In addition, it is advantageous for an insulation that the voltage source 60 does not need to be operated pulsed, which on the one hand a simple voltage control (with low cost for the device of the power supply) has the consequence and on the other hand, that the feed rate of the electrode 40 can be comparatively higher.

Moreover, it is possible with a so-called protective current electrode, the electrochemical action of the electrode 40 to limit. Here is on a lateral surface insulation of the electrode 40 an electrically conductive metal layer is applied, which via a DC power source to one of the electrode 40 opposite electrical potential is connected. As a material for the protective current electrode coating are all electrically conductive materials such. B. a graphite layer or a metal coating.

Centering the electrode 40 in the direction of the longitudinal axis 95 the pilot hole 20 is determined by the flow of the electrolyte 50 from the resulting microbore 30 to the remaining pilot hole 20 ensured. In addition, however, the electrode can 40 have at its free end an extension, by means of which the electrode 40 in the pilot hole 20 is centerable. In this case, the extension preferably sits centrically on the end face of the free end of the electrode 40 , It is important to ensure that the extension of the pilot hole 20 not clogged, hence an electrolyte flow from the entry point 52 to the exit point 54 is guaranteed. This can be achieved either with a corresponding shaping of the extension or recesses therein. In general, the cross-sectional area of the extension must be less than the cross-sectional area of the pilot hole 20 , The same applies to the electrode 40 that the microbore 30 ausformt, otherwise no electrolyte flow through the microbore 30 it is possible.

Furthermore, it is possible by means of a corresponding shaping of the electrode 40 the electrode 40 in the micro bore 30 to center. For this purpose, the lateral surface of the electrode 40 electrically isolated, with a maximum diameter of the electrode 40 the later diameter of the microbore 30 equivalent. To ensure electrolyte flow through the resulting microbore 30 the electrode points through it 40 in their longitudinal direction elongated recesses, which is an electrolyte 50 allow, at the entry point 52 the microbore 30 along the electrode 40 to the machining gap 56 to flow and from there through the remaining pilot hole 20 to be dissipated. Since such a cross-section (eg approximately star-shaped) u. Depending on the cross-sectional shape and size of the recesses for the Si cherstellung of the electrolyte flow and for the most regular formation of the microbore 30 be necessary that the electrode 40 around its longitudinal axis 95 rotates.

In a preferred embodiment of the invention, the electrode is 40 an elongated solid cylinder. In addition, by means of the device according to the invention and the method according to the invention other forms of electrodes reversible. So z. B. cuboid or prismatic massive elongated electrodes 40 possible, the corresponding bore cross-section of the microbore 30 cause. In addition, elliptical cross sections are also provided with corresponding electrodes 40 realizable. Furthermore, it is z. B. with a not electrically insulated on its lateral surface electrode 40 possible after the electrode 40 as far as desired in the workpiece 10 has been moved into, the electrode 40 no longer in its longitudinal axis 95 to move, but perpendicular to so z. B. to create slots with arbitrary cross-sections.

The inventive method is particularly suitable for producing throttle bores and for producing injection openings of injection nozzles. Especially with the injection nozzles are the short process times of the process (including the production of a pilot hole 20 by means of a laser drilling method) is particularly advantageous.

Through holes of approx. 1 mm are necessary for producing injection openings of injection nozzles. Therefore, the electrode 40 for reworking pilot holes 20 in an injection nozzle for making injection openings slightly longer than 1 mm, which ensures that the pilot hole 20 also completely reworked. A modern injection nozzle has about 6 to more than 24 injection ports, which are predrilled by the method according to the invention by means of a laser drilling method. For this purpose, a solid-state laser with a high pulse energy of> 100 mJ and / or a high pulse repetition frequency> 10 kHz is preferably used. Subsequently, these pilot holes 20 refinished in the injection nozzle by means of the method according to the invention, wherein each pilot hole 20 to a microbore 30 with a defined diameter and thus defined hydraulic properties. When using the method according to the invention, the pilot hole is about 10 ± 5 to 20 ± 5 microns smaller than the later microbore 30 , Every subsequent microbore 30 should have a diameter of 110 microns for injection nozzles with 6 to 12 injection ports and a diameter of 80 microns for 24 injection ports. It follows that the diameter of a pilot hole in the application of the method according to the invention to injectors should have a diameter of about 55 to 105 microns, especially from 70 to 100 microns.

The dimensional accuracy of the electrode 40 is a decisive factor influencing the quality of the later microbore 30 , Its limits down the process of the invention in the smallest manufacturable electrode 40 ,

Claims (19)

Method for producing a reproducible microbore ( 30 ) having certain hydraulic properties and a maximum diameter of 110μm and an aspect ratio of at least 10, the microbore ( 30 ) by means of an electrochemical process by means of an electrode ( 40 ) in a position in a workpiece ( 10 ) in which already a pilot hole ( 20 ), which has a smaller diameter (D ₂₀ ) than the later microbore ( 30 ). Process according to claim 1, wherein the electrochemical process is carried out in the presence of an electrolyte ( 50 ) while applying an electrical potential between the electrode ( 40 ) and the workpiece ( 10 ) takes place, the electrode ( 40 ) at an external position ( 52 . 54 ) of the pilot hole ( 20 ) on the workpiece ( 10 ), under an electrochemical ablation of a peripheral portion of a wall of the pilot hole ( 20 ) by dissolving in the electrolyte ( 50 ), successively into the workpiece ( 10 ) and while the pilot hole ( 20 ) to a desired diameter (D ₃₀ ) of the microbore ( 30 ) is widened. Method according to claim 1 or 2, wherein to ensure a continuous flow of the electrolyte ( 50 ) through the workpiece ( 10 ), the pilot hole ( 20 ) is a through hole and the electrolyte ( 50 ) from one side of the workpiece ( 10 ) in the direction of pilot drilling ( 20 ), at which the electrode ( 40 ) in the workpiece ( 10 ), and the electrolyte ( 50 ) on one of these opposite side of the pilot hole ( 20 ) is discharged. Method according to one of claims 1 to 3, wherein the electrolyte ( 50 ) at the outer position ( 52 ) of the existing microbore ( 30 ) into the resulting microbore ( 30 ) from outside the electrode ( 40 ) or an ECM device which is in the direction of the pilot hole ( 20 ) in the workpiece ( 10 ) penetrates the microbore ( 30 ). Method according to one of claims 1 to 4, wherein the flow rate increase of the electrolyte ( 50 ) through the workpiece ( 10 ), between an entry ( 52 ) and an exit point ( 54 ) of the electrolyte ( 50 ) on the workpiece ( 10 ) there is a pressure difference. Method according to one of claims 1 to 5, wherein for influencing a current production parameter in producing the microbore ( 30 ) the hydraulic properties of the microbore ( 30 ) by continuously detecting and evaluating a flow of the electrolyte ( 50 ) through the workpiece ( 10 ), to be monitored on the basis of these data, by means of a readjustment or control of electrochemical process parameters during the production of the microbore ( 30 ), on the later hydraulic properties of the microbore ( 30 ) Influence. A method according to any one of claims 1 to 6, wherein to limit the electrochemical action to an immediate environment of the electrode ( 40 ) a power supply ( 60 ), which determines the electrical potential between electrode ( 40 ) and workpiece ( 10 ), is pulsed and the duration of a voltage pulse is preferably in the range up to 100 ns, preferably 5 to 50 ns, in particular 10 to 30 ns, particularly preferably 20 ± 5 ns. Method according to one of claims 1 to 7, wherein the microbore ( 30 ) has a diameter (D ₃₀ ) of 50 to 150 μm, preferably 70 to 130 μm, in particular 80 to 110 μm, particularly preferably 90 to 100 μm. Method according to one of claims 1 to 8, wherein the diameter (D ₂₀ ) of the pilot hole ( 20 ) 3 to 40 microns, preferably, 5 to 30 microns, in particular 10 to 20 microns, more preferably 15 ± 2 microns smaller than the diameter (D ₃₀ ) of the microbore ( 30 ). Method according to one of claims 1 to 9, wherein the pilot hole ( 20 ) is produced by means of a laser drilling method, preferably by means of a percussion drilling method, and preferably a solid-state laser with a pulse energy of> 100 mJ and / or a pulse repetition frequency> 10 kHz is used. Method according to one of claims 1 to 10, wherein the electrolyte ( 50 ) is a NaOH solution. Component or device with a fluid throttle, the throttle bore with a method according to one of claims 1 to 11 is made. injection or injection nozzle system with at least one bore, which with a method according to a the claims 1 to 11 is made. Device for producing reproducible microbores ( 30 ) with certain hydraulic properties, whereby one in a workpiece ( 10 ) movable section of an ECM electrode ( 40 ) exclusively a solid, preferably substantially elongated, fully cylindrical body ( 40 ) and when making the microbore ( 30 ) the ECM electrode ( 40 ) without a surrounding electrolyte conveying tube in the workpiece ( 10 ) at the position of a pilot hole ( 20 ) is advanced. Apparatus according to claim 14, wherein a control device controlling a flow of an electrolyte ( 50 ) through the workpiece ( 10 ) and / or controls, and preferably a device is provided which a fluid pressure on the electrolyte ( 50 ) at least in the region of the workpiece ( 10 ) imprints. Device according to claim 14 or 15, wherein the ECM electrode ( 40 ) has at its free end a, preferably central, extension, by means of which the ECM electrode ( 40 ) in the pilot hole ( 20 ) is centered, wherein the extension is preferably electrically non-conductive. Device according to one of claims 14 to 16, wherein the ECM electrode ( 40 ) and / or its extension each have a cross-sectional area which is smaller in comparison to a cross-sectional area of a respective bore ( 30 . 20 ) in which the ECM electrode ( 40 ) or its extension when making the microbore ( 30 ) to allow a flow of an electrolyte ( 50 ) of its entry ( 52 ) to its exit point ( 54 ) on the workpiece ( 10 ) to ensure. Device according to one of claims 14 to 18, wherein, to limit the electrochemical action to a specific portion, preferably to a free end, of the electrode ( 40 ) a lateral surface of the electrode ( 40 ) is at least partially electrically isolated and an electrical insulation of the lateral surface of the electrode ( 40 ) is preferably realized by means of a mixed oxide or an oxide ceramic. System for producing a microbore ( 30 ) comprising a laser drilling device and a micro-drilling device according to one of claims 14 to 17, wherein the pilot bore ( 20 ) is produced by means of the laser drilling apparatus, which preferably carries out a percussion drilling method with a solid-state laser and uses a pulse energy of> 100 mJ and / or a pulse repetition frequency> 10 kHz, and the micro-drilling apparatus thereafter the microbore ( 30 ) in the position of the pilot hole ( 20 ) in the workpiece ( 10 ).