WO2000037703A1 - Method and arrangement for thermally coating the surfaces of an inner area, especially cylinder bearing surfaces in a cylinder crankcase in an internal combustion engine - Google Patents

Abstract

The invention relates to a method and device for thermally coating the surfaces of an inner area, especially the cylinder bearing surfaces of a cylinder crankcase. The cylinder crankcases are fed to a processing station where the surfaces to be coated are pretreated and said surfaces are then thermally coated. The areas of the cylinder crankcase that should not be treated in said processing station are covered (masked) before pretreatment and/or coating is carried out.

Description

 Method and arrangement for the thermal coating of surfaces of an interior, in particular of cylinder surfaces of a cylinder crankcase of an internal combustion engine

The invention relates to a method for the thermal coating of surfaces of an interior with the features mentioned in the preamble of claim 1 and an arrangement for the thermal coating of surfaces of an interior with the features mentioned in the preamble of claim 9.

It is generally known to achieve surface treatment by means of a thermal coating. In the case of such a thermal coating, for example a plasma coating, a coating material, in particular a metal, is supplied in powder or rod form to a flame, melted in it and deposited on a substrate. Depending on the coating material used and the ambient atmosphere used, coatings with different properties, in particular with desired sliding properties, hardness properties, layer thicknesses or the like, can be achieved.

For example, it is known from US Pat. No. 5,080,056 to apply an aluminum-bronze alloy to workpieces consisting of an aluminum alloy or a magnesium alloy by high-speed flame spraying, the layer thickness of which is then machined to a final dimension by honing.

Furthermore, an aluminum engine block is known from US Pat. No. 2,588,422, the cylinder raceways of which have a thermally sprayed coating. Finally, GB 2 050 434 A discloses various coatings obtained by thermal spraying. These coatings are on steel or cast parts of internal combustion engines, such as piston rings or cylinder liners. Another coating for cylinder liners is known from DE AS 21 46 153, in which a plasma coating is described.

When coating interiors, for example cylinder surfaces of a cylinder crankcase of an internal combustion engine (reciprocating piston engine), there is the problem that the interiors to be coated are relatively narrow, so that freedom of process is severely restricted. This concerns both the preparation of the surface to be coated, the implementation of the thermal coating itself and the finishing of the coated surface. Defined and reproducible machining is necessary in particular for the thermal coating of cylinder running surfaces on internal combustion engines, since the thermal properties of pistons in the cylinder crankcases are significantly influenced by the thermal coating.

The invention has for its object to provide an arrangement of the generic type with which a safe, in particular the use of a cylinder crankcase thermal coating is not negatively influencing is possible in a simple manner. The invention is also based on the object of specifying a method of the generic type with which a reliable thermal coating is possible in a simple manner.

According to the invention, this object is achieved by a method having the features mentioned in claim 1. The fact that at least before the pretreatment and / or before the coating of the surfaces to be treated, the areas of the cylinder crankcase are covered where no treatment is to be carried out in the processing station, is advantageously achieved that the material-removing or material-applying work steps actually only on those to be treated Surfaces act and all other areas of the cylinder crankcase are protected. Thus, a previously set dimensional accuracy of the cylinder crankcase is not adversely affected by the coating and the pretreatment or aftertreatment required for the coating. This makes it possible in a reproducible manner to treat a large number of cylinder crankcases which are within the specified and to be observed dimensional tolerances. In particular, accidental contamination of further interiors provided in the cylinder crankcase, such as coolant channels, fitting bores or the like, is avoided so that their later function is not impaired.

In a preferred embodiment of the invention it is provided that this, hereinafter also called stenciling, covering of the cylinder crankcase takes place before the cylinder crankcase is introduced into the processing station. Thus, each cylinder crankcase to be thermally coated at least in regions can be provided continuously, for example in continuous production, with a cover template. This then takes over the protection of the other areas during the entire pretreatment and the actual thermal coating of the surfaces of the interior, in particular the cylinder running surfaces of cylinder bores.

Furthermore, it is provided in a preferred embodiment of the invention that the stenciling takes place separately with respect to the pretreatment and the thermal coating. This advantageously makes it possible to use cover templates which are matched to the respective treatment steps or treatment methods used, so that optimum protection of the other areas of the cylinder crankcase which are not to be treated is provided.

The object is further achieved according to the invention by an arrangement with the features mentioned in claim 9. Because the processing sections are assigned a device for stenciling the cylinder crankcase, stenciling of the cylinder crankcase can be achieved in a simple manner, at least during pretreatment and during thermal coating. It is particularly preferred that the device comprises a turntable which can be rotated in defined steps by means of a drive about its axis of rotation, so that a cover template can be brought into a defined position in relation to the cylinder crankcases within the machining section. This advantageously ensures that a cover template can be brought into position in a simple manner, which is in a defined position relative to a cylinder crankcase to be treated. The turntable can be used to move the cover template into the processing position in a simple and space-saving manner.

In a further preferred embodiment it is provided that the turntable has a plurality of, in particular four, receptacles which are offset by 90 ° from one another for receiving a respective cover template. As a result, a cover template can be brought into the machining position by rotating the turntable step by step by 90 °.

In a further preferred embodiment of the invention it is provided that the device for stenciling the cylinder crankcases is assigned a cleaning device by means of which used cover stencils can be cleaned. With such a combination, a covering template used for covering can be cleaned immediately after use and prepared for further use. The combination with the turntable can so very advantageous for each machining section on which the cylinder crankcase is to be covered, continuous operation is maintained by means of at least two, in particular four, cover templates. While one cover template is in the processing position, a second cover template can be in the cleaning position. Material and space requirements can be optimized to a minimum through such a design.

The cleaning device can preferably be formed by a sleeve exchange machine, by means of which sealing sleeves in the cover templates can be exchanged. By using new or regenerated wear sleeves, the dimensional accuracy of the cylinder surfaces to be machined can be achieved with great accuracy.

Further preferred embodiments of the invention result from the other features mentioned in the subclaims.

The invention is explained in more detail below in exemplary embodiments with reference to the associated drawings. Show it:

Figure 1 is a schematic view of a processing station for thermal

Coating of cylinder liners in cylinder crankcases;

Figure 2 is a schematic side view of a processing section of the

Processing station and

Figure 3 is a schematic plan view of the machining section according to

Figure 2.

FIG. 1 schematically shows a processing station 10 for the thermal coating of cylinder running surfaces of cylinder crankcases 12. Only one cylinder crankcase 12 is indicated in each case, this also only having indicated cylinder bores 14, here four. The walls delimiting the cylinder bores 14, that is to say the cylinder running surfaces, are to be coated by means of the processing station 10. The coating is done using a plasma coating technique. In the context of the present description, the actual process of plasma coating is not dealt with in more detail, since this is known. The cylinder crankcases 12 are moved through the processing station 10 by means of a transport path 16, for example a roller conveyor or the like. The processing station 10 comprises processing sections 18, 20, 22, 24, 26, 28, 30, 32, 34 and 36. The individual processing sections will be briefly discussed below.

In FIG. 1, details such as drives, locks, inlets and outlets for gases, electrical energy or other media, control and monitoring devices or the like have been omitted for reasons of clarity.

The processing section 18 comprises a feed station at which the cylinder crankcases are transferred to the processing station 10. The cylinder crankcases 12 have already been manufactured in a manner not to be considered in detail here and are mechanically finished with all the necessary functional elements, such as, for example, cylinder bores, coolant channels, fitting bores or the like.

The processing section 20 comprises a washing or cleaning station, within which the cylinder crankcases are completely washed free of chips and oil. Furthermore, the cylinder surfaces to be coated are dried and degreased absolutely. The absence of chips and oil is achieved, for example, by an injection flood wash, with critical areas, such as undercuts, bores, cavities or the like, being cleaned at high pressure by targeted injection of a wash liquor. Degreasing is carried out, for example, by superheated steam, which is conducted, for example, by appropriately designed lances onto the cylinder running surfaces of the cylinder crankcase 12. The superheated steam, for example, has a temperature of 130 ° C to 160 ° C and is introduced at a pressure of approximately 150 to 180 mbar. The subsequent drying of the cylinder crankcase is preferably carried out under vacuum, for example at a negative pressure of 80 to 120 mbar.

In the machining section 22, a so-called stenciling of the cylinder crankcase 12 takes place. Here, the previously cleaned and dried cylinder crankcase 12 is provided with a cover template 38. The cover template 38 has openings 40 indicated here. The openings 40 are aligned with the cylinder bores 14, so that the cylinder bores 14 remain accessible from above through the openings 40 when the cover template 38 is applied. The cover template 38 is designed such that all other areas of the cylinder crankcase 12 are covered by the latter. This applies in particular to coolant channels, fitting bores or the like. The cover template 38 can be placed on the cylinder crankcase 12 manually or by a corresponding gripper or the like. Here, the cover template 38 has an exact flat underside, which rests on the cylinder head surface of the cylinder crankcase 12 that has already been ground or milled. To fix the cover template 38, this can have fixing pins, not shown in detail here, which engage, for example, in fitting holes provided anyway in the cylinder crankcase 12, for example for later attachment of a cylinder head. The cover template 38 is made of a material that is resistant to the subsequent processing. In particular, this has a sufficiently high strength against a sandblast attack and against a plasma treatment and the like. The cover template 38 here lies only on the cylinder crankcase 12 due to its own weight. Due to the opposite, flat sides, however, a tight support is achieved, so that a gap between the cylinder head surface of the cylinder crankcase 12 and the underside of the cover template 38 is essentially sealed. After this stenciling in the processing section 22, the cylinder crankcase 12 provided with the cover template 38 is guided through the subsequent processing sections 24, 26, 28, 30 and 32.

Sandblasting of the cylinder bores 14 takes place in the machining section 24. This sandblasting is carried out in order to achieve a roughness of the cylinder running surfaces so that the plasma coating taking place in the machining section 32 obtains the necessary adhesive tensile strength. For sandblasting, at least one blasting lance, possibly two or more blasting lances, is introduced into the cylinder bores 14 simultaneously or in succession. The lances reach through the openings 40 of the cover template 38. Sandblasting is carried out, for example, with aluminum oxide Al ₂ O ₃ with a grain size of 0.18 to 1.18 mm depending on the required surface roughness, based on the substrate alloy of the cylinder crankcase or the adhesive tensile strength of the subsequent plasma coating. In the case of cylinder crankcases with four cylinder bores 14, the sandblasting is preferably carried out using a double sandblasting unit which has two sandblasting lances. Here, for example, the cylinder bores 1 are simultaneously sandblasted and 3, that is to say cylinder bores 14 which are not immediately adjacent. This makes better handling possible in the case of relatively limited space available, which depend on the pitch of the cylinder bores 14. This also halves the machining time for a complete cylinder crankcase 12, since two cylinder bores are machined simultaneously. If the cylinder bores 1 and 3 are blasted, either the cylinder crankcase 12 or the sandblasting unit is moved by the pitch of the cylinder bore 14 so that the cylinder bores 2 and 4 can then be sandblasted. The sandblasting takes place through the openings 40 of the cover templates 38, that is, the blasting lances are introduced through the cover template 38 into the cylinder bores 14. All other areas of the cylinder crankcase 12 are protected by the cover template 38 so that they do not come into contact with the sandblasting agent applied under pressure, so that the surfaces thereof are not impaired in any way. The action of the sand blasting takes place exclusively on the cylinder running surfaces of the cylinder bores 14.

The sandblasted cylinder crankcase 12 is then cleaned in the machining section 26 by removing dust, in particular very fine dust, from the cylinder bores 14 by the sandblasting. This can be done, for example, by cleaned, de-oiled and water-free compressed air, for example with a pressure of approximately 5 to 6 bar, with simultaneous suction of the dusts. Here, all cylinder bores 14 are cleaned, that is, blown out and suctioned out, at the same time.

In the machining section 28, the cylinder crankcase 12 is measured, in particular a roughness measurement of the cylinder surfaces. The measurement can be carried out fully automatically using suitable devices, for example photogrammetry. In this case, all cylinder bores 14 or only one of the cylinder bores 14 or a cylinder bore 14 of each nth cylinder crankcase 12 can be measured on a random basis. After measuring the cylinder crankcase 12, they are transferred to the processing section 30, within which the cylinder crankcase 12 is marked. If the measurement shows that the roughness lies outside the specified tolerances, the corresponding cylinder crankcase 12 can be sorted out and, if necessary, fed back to the sandblasting station. However, the number of the maximum possible blasting processes is limited. Becomes a faulty cylinder crankcase, the frequency of the roughness measurement can be increased.

Finally, the cylinder crankcases are transferred to the machining section 32, in which the actual thermal coating of the cylinder running surfaces takes place. The plasma coating is carried out in a manner known per se, in that a coating material, in particular a metal, is fed to a flame, melted out in the flame and deposited on the cylinder surfaces. In addition to the coating material, a coating atmosphere, for example oxygen and / or nitrogen or another process gas for stabilizing the flame and / or for regulating the oxide content in the plasma layer, is also supplied. The plasma coating of the cylinder surfaces can be carried out individually for each of the cylinder bores 14 or, similarly to sandblasting, by means of a double plasma unit, by means of which the cylinder bores 1 and 3 and subsequently the cylinder bores 2 and 4 are coated. The cover template 38 still located on the cylinder crankcase 12 reliably prevents impairment, in particular contamination, of regions of the cylinder crankcase 12 that are not to be coated.

After the plasma coating of the cylinder running surfaces, the cylinder crankcases are transferred to the processing section 34. This can optionally be part of a cooling zone. According to a further exemplary embodiment, a separate cooling zone is provided between the plasma coating in the processing section 32 and the processing section 34.

In the processing section 34, the cover template 38 is removed. This is removed from the cylinder crankcase 12 either manually or by auxiliary devices. Since the cover template 38 rests only on the cylinder crankcase 12 due to its own weight, additional measures for removing the cover template 38 are not necessary. Finally, the cylinder crankcase 12 is removed in a machining section 36 of the machining station 10 and fed to further machining, for example honing the plasma-coated cylinder bores 14, to attaching an inlet chamfer to the cylinder bores 14. Furthermore, the cylinder crankcase 12 can be marked in the section 36. The cylinder crankcase 12 is marked, for example, by a serial number or the like. By assigning a sequential number to each of the cylinder crankcases 12, it is possible, in addition to quality monitoring, to assign all relevant process parameters of the processing station 10 to the sequential number of the cylinder crankcase 12 and to log them in a system computer. By means of the logged process parameters and the unambiguous assignment to the cylinder crankcases 12 via the serial number, a later error analysis in the event of complaints is possible without gaps at any time.

In a manner not to be considered in the context of the present description, it can be provided that the openings 40 of the cover template 38 are slightly larger than the cylinder bores 14, so that a corresponding edge coating of the edge regions of the cylinder crankcase 12 surrounding the cylinder bores 14 takes place. It is hereby advantageously achieved that the later chamfer area has a correspondingly high adhesive tensile strength against cutting forces of the chamfering tool and the plasma coating is not damaged during the chamfering.

In the exemplary embodiment illustrated in FIG. 1, it has been assumed that the stenciling of the cylinder crankcase 12 is maintained throughout the entire passage through the processing sections 24, 26, 28, 30 and 32. For this purpose, the covering templates are applied in the processing section 22 and removed in the processing section 34. The covering templates 38 used in accordance with this exemplary embodiment must therefore be suitable both for sandblasting in the processing section 24 and for plasma coating in the processing section 32. Since on the one hand it is a material-removing process and on the other hand it is a material-applying process, the cover template 38 has to do justice to both mutually opposing processes.

The stenciling of the cylinder crankcase 12 is illustrated in a further exemplary embodiment with reference to FIGS. 2 and 3. Here, a schematic side view and a schematic top view of the machining section 24 or the machining section 32 are shown. The basic structure within the processing sections 24 and 32 is the same. The only differences are the sandblasting devices as tools and the plasma coating devices as tools. However, this will not be dealt with in more detail in the context of the present description. The stenciling of the cylinder crankcase 12 is decisive both in the case of sandblasting in the machining section 24 and in the case of plasma coating in the machining section 32.

The same parts as in Figure 1 are provided with the same reference numerals and not explained again.

In the schematic side view in FIG. 2, a cylinder crankcase 12 is arranged on a lifting table 42. The lifting table 42 is integrated in the transport path 16. This is done in such a way that the cylinder crankcase 12 is transported by means of the transport path 16 into the respective processing sections 24 and 32 and can be transferred there into its respective processing position by means of the lifting tables 42. Also indicated is a machining tool 44, each having a lance or, according to the exemplary embodiments already explained, two or more lances 46. The lances 46 are designed accordingly either for sandblasting in the processing section 24 or for plasma coating in the processing section 32.

The processing stations 24 and 32 further comprise a device, designated here overall with 50, for stenciling the cylinder crankcase 12. In contrast to the exemplary embodiment in FIG. 1, the stenciling takes place here in a processing-related manner on the one hand in the processing station 24 and on the other hand in the processing station 32. The device 50 comprises a turntable 52, which can be rotated about its axis of rotation 56 in defined steps by means of a drive 54. The turntable 52 has, as the schematic plan view in FIG. 3 better illustrates, receptacles 58 for one cover template each. From the top view it is clear that the cover templates 38 only have the openings 40, which are each assigned to the cylinder bores 14. The turntable 52 can be rotated step by step in a defined manner by means of the drive 54. In the exemplary embodiment shown, four templates 38 are arranged on the turntable 52, so that it can be rotated step by step in each case by 90 °. The device 50 is associated with an indicated cleaning device 62, which may have a milling cutter 64, for example. Instead of the cleaning device, a device for exchanging wear sleeves, which are arranged in the template 38, can also be provided. In addition, suction devices 66 and 68, which are indicated here, are also provided. The device 50 shown in FIGS. 2 and 3 has the following function:

Exactly one cover template 38 is always brought into a processing position by means of the drive 54. When the cover template 58 has reached its exact position, which is defined by the stops 60, the cylinder crankcase 12 is moved upward, that is to say against the cover templates 38, by means of the lifting table 42. As a result, the openings in the cover template 38 and the cylinder bores 14 of the cylinder crankcase 12 come into an aligned position. In accordance with this position, either tools are used for sandblasting in accordance with processing section 24 or plasma coating in accordance with processing section 32.

As illustrated in FIG. 3, at the moment when a cover template 38 is in its processing position, viewed clockwise, a next cover template 38 is in a transition position and a cover template 38 is in a position assigned to the cleaning device 62 (sleeve exchange device). Another cover template 38 is located between the cleaning position and the processing position. It is hereby achieved that at the same time, when a cover template 38 assumes its covering function, a second cover template 38, namely this cover template 38 which is exactly offset by 180 °, is cleaned by means of the device 62. The milling device 64 can, for example, restore the dimensions of the openings 40 of the cover templates 38. This can be impaired, for example, by deposits during the plasma coating. The dimensional accuracy of the openings can also be achieved by replacing the corresponding wear sleeves in the cover templates.

After sandblasting or plasma coating of a cylinder crankcase 12 has taken place, the turntable 52 is rotated through 90 ° in each case, so that each cylinder crankcase 12 is assigned a new (cleaned) cover template 38. This ensures a constant processing quality during sandblasting or plasma coating.

The arrangement of the cleaning device 62 can be dispensed with in the processing station 24, since there is no additional material application that could impair the dimensional accuracy of the openings 40. Merely because of the material removal, covering templates 38 or wear sleeves that are no longer true to size can be replaced. By means of the device 50 shown in FIGS. 2 and 3, automatic stenciling of the cylinder crankcase 12 is possible in a simple manner. In particular if the device 50 is coupled to a system computer, the masking templates 38 can be positioned precisely, so that a constant quality can be achieved with sandblasting or with plasma coating.

Claims

PAT REQUESTS

1. A method for the thermal coating of surfaces of an interior, in particular of cylinder running surfaces of a cylinder crankcase, the cylinder crankcase being fed to a processing station, and at least one pretreatment of the surfaces to be coated and the thermal coating of the surfaces taking place within the processing station, characterized in that before the Pretreatment and / or before coating the areas of the cylinder crankcase are covered (stenciled) where no treatment should take place in the processing station.

2. The method according to claim 1, characterized in that the stenciling of the cylinder crankcase is carried out before introducing the cylinder crankcase into the processing station.

3. The method according to any one of the preceding claims, characterized in that the cylinder crankcase is washed, degreased and dried before stenciling.

4. The method according to any one of the preceding claims, characterized in that the stenciling is carried out by placing a cover template on a cylinder head surface of the cylinder crankcase.

5. The method according to claim 4, characterized in that the cover templates are placed by their own weight on the cylinder crankcase.

6. The method according to any one of the preceding claims, characterized in that the cover templates are fixed in position on the cylinder crankcases.

7. The method according to any one of claims 1 to 3, characterized in that the stenciling of the cylinder crankcase based on the pretreatment and the thermal coating is carried out separately.

8. The method according to claim 7, characterized in that the stenciling is carried out automatically by means of a feed device for the cover stencils.

9. Arrangement for the thermal coating of surfaces of an interior, in particular of cylinder running surfaces of a cylinder crankcase (12), with a processing station (10) divided into processing sections (18, 20, 22, 24, 26, 28, 30, 32, 34, 36) , wherein at least one pretreatment of the surfaces to be coated and a thermal coating of the surfaces takes place within the processing sections (24, 32), characterized in that the processing sections (24) and / or (32) have a device (50) for stenciling the cylinder crankcase ( 12) is assigned.

10. The arrangement according to claim 9, characterized in that the device (50) comprises a turntable (52) which can be rotated in defined steps by means of a drive (54) about its axis of rotation (56), so that a cover template (38) within of the machining section (24) and / or (32) can be brought into a defined machining position relative to the cylinder crankcases (12).

11. Arrangement according to one of the preceding claims, characterized in that the turntable (52) has receptacles (58) for the cover template (38).

12. The arrangement according to claim 11, characterized in that the turntable (52) has at least two, in particular four receptacles (58) offset from one another by 90 °.

13. Arrangement according to one of the preceding claims, characterized in that the processing sections (24) and / or (32) comprise a lifting device (42) by means of which the cylinder crankcase (12) against the positioned cover templates (38) are displaceable.

14. Arrangement according to one of the preceding claims, characterized in that the device (50) has a cleaning device (62) by means of which cleaning of used cover templates (38) can be carried out.

15. Arrangement according to one of the preceding claims, characterized in that the device (50) comprises a sleeve exchange machine by means of which wear sleeves in the cover templates (38) can be exchanged.

16. Arrangement according to one of the preceding claims, characterized in that the turntable (52) stops (60) for exact positioning of the cover templates (38) are assigned.