EP1144138A2 - Method for grinding at least one surface on a cutting knife used in machining, use of said method and grinding wheel used to carry out said method - Google Patents

Abstract

A grinding wheel (28) that rotates around an axis and that has a working area consisting of a ring area with a circular arc profile is used to create a surface by initial grinding with the ring surface oriented at a first point in space on the cutting knife (22) by means of at least one first translational relative movement.Subsequently one part of the surface produced with the ring surface oriented at a second point in space is grinded by means of at least one second translational relative movement. The grinding wheel (28) is a diamond cupped grinding wheel and has the same abrasive covering for the entire working area (34). Roughing down and smooth-polishing occur using areas of the grinding wheel (28) that have the same specifications but different grinding parameters. Preferably, spatial orientation between the grinding wheel (28) and the cutting knife (22) is selected by adjusting the cutting knife (22) in relation to the grinding wheel (28). The inventive method enables planar and/or convex and concave surfaces to be created on a cutting knife.

Description

METHOD FOR GRINDING AT LEAST ONE SURFACE ON A CUTTING KNIFE USED IN CUTTING TECHNOLOGY, USE OF THE METHOD AND GRINDING WHEEL FOR CARRYING OUT THE METHOD

description

The invention relates to a method for grinding at least one surface on a cutting knife used in machining technology with a grinding wheel rotating about an axis, the working area of which is an annular surface, an advantageous use of the method and a grinding wheel for carrying out the method.

Today, two technologies exist for grinding cutting knives used in cutting technology, namely form grinding and production grinding. The main difference between these two grinding technologies is that the shape is generated in advance on the tool (dressing). This creates a simple process in which the grinding tool is the profile carrier. Only one feed movement is then required to generate the surface. In contrast, the generation is generated by at least two machine movements, which makes the process more complex. Generation grinding is more flexible than form grinding, because a variety of profiles can be created using any combination of movements. The increase in flexibility is greatly appreciated when special profiles have to be manufactured in a small or medium batch size. In this case, it is not necessary to bring the generation profile onto the grinding wheel. The generation grinding is associated with greater control effort than the profile grinding.

A method of the type mentioned is known from US 5 168 661. In this known method, a special their grinding wheel configuration and a special movement sequence when moving the cutting knife relative to the grinding wheel to enable the formation of a number of desired surfaces on a cutting knife. In addition, spiral grooves that are created on the workpiece surface by the grain protruding the highest from the grinding wheel should be avoided. For this purpose, in the known method a grinding wheel is used which has a narrow, essentially flat surface for finish grinding on the outer part of the wheel surface, which surface is held essentially tangential to a surface of a workpiece during the finishing grinding. The grinding wheel consists of an expensive, extremely durable grinding material such as CBN crystals, but other materials such as aluminum oxide can also be used, since the grinding wheel does not need to be dressed. In addition to the narrow, flat surface that is used for finish grinding, the grinding wheel has an inner conical surface that is used for rough grinding. The roughed knife surface is then finished with the narrow, flat surface.

This known method requires a complicated movement sequence, because each surface to be ground on a cutting knife is first roughed with the inner conical surface and then finished with the narrow, flat surface. The grinding wheels used in the known method consist of grinding materials with different grain size in their roughing and finishing area. The grinding and finishing work to be carried out by the grinding wheel is thus divided into two different grinding wheel areas, one of which is used only for rough grinding and the other only for finishing grinding. The cutting knives, which are ground by the known method, are the usual high-speed steel knives. Another disadvantage of the known method is that finish grinding of concavely curved surfaces is not possible because the finish is always carried out with the narrow flat surface. Furthermore, at the known generation grinding method disadvantageous that carbide knives cannot be ground due to the CBN discs used. A CBN disc would not have sufficient stability when machining hard metal knives. Tungsten carbide knives cannot be shaped easily. A wide diamond wheel would be required for carbide knives for shape grinding, but these diamond wheels are very difficult to condition.

To manufacture the gears of a transmission, it may be necessary, for example, to use six different types of knives in order to produce six different profiles. These six profiles could be produced on a Borazon grinding wheel by re-profiling. That would not be economical on a diamond grinding wheel. Rather, several different diamond disks would have to be provided for shape grinding.

The object of the invention is to provide a method of the type mentioned at the outset which enables a simpler workflow and the use of a grinding wheel with a simpler configuration and in particular also permits the grinding of curved surfaces. In addition, an advantageous use of the method and a grinding wheel for carrying out the method are to be specified.

This object is achieved according to the invention by the method according to claim 1, by the use according to claim 15 or by the grinding wheel according to claim 16.

In contrast to the known method with a complicatedly configured grinding wheel, a universal grinding wheel can be used in the method according to the invention, the working area of which is an annular surface which has an arcuate profile in axial section. By means of the method according to the invention, a surface on the cutting knife is first grinded by the ring surface under a first spatial orientation between the grinding wheel and the cutting knife by at least one generated first translational relative movement between the grinding wheel and cutting knife, and then at least a part of the generated surface with the ring surface is ground with a second spatial orientation between the grinding wheel and cutting knife by at least a second translational relative movement between the grinding wheel and cutting knife. According to the invention, a surface can be ground with one area of the ring surface and then this surface can be ground with another area of the ring surface. For this purpose, the grinding wheel used in the method according to the invention does not need to have different specifications in these two areas, because just by appropriately selecting the parameters, coupled with the two different spatial orientations, the same surface of the cutting knife can be ground and then ground, for example Rough and finishing grinding, regardless of whether the finished surface is flat, convex or concave. The grinding wheel used in the method according to the invention only needs to have a radius in its working area and therefore has a much simpler configuration than the grinding wheel used in the known method. The course of the method is also much simpler in the method according to the invention than in the known method because only two different spatial orientations can be selected, for example by choosing a different angle for the cutting knife with respect to the grinding wheel. The method according to the invention is thus considerably more flexible in use than the known method. The spiral grooves, which are avoided in a complex manner by the known method, are also avoided by the method according to the invention, without it being necessary to use a grinding wheel with a narrow, flat surface for finish grinding.

When using the method according to claim 15, it is possible to ^produce hard metal knives. This is a very important use of the method according to the invention, because more and more in the manufacture of gears Dry milling is used, in which cutting blades made of hard metal must be used. Tungsten carbide can only be machined with diamond, but diamond profile grinding wheels can hardly be profiled by dressing, so that profile grinding of carbide knives is practically impossible. The method according to the invention can thus not only be used for the production grinding of cutting knives made of high-speed steel, but also of cutting knives made of hard metal, by simply using a diamond grinding wheel.

According to the invention, the grinding wheel for carrying out the method is a diamond cup grinding wheel with a working area which lies partly in an end region and partly in a cylinder region of the cup grinding wheel. This offers the advantage that either flat or curved surfaces (with the end region) or concave surfaces (with the cylinder region or the end region) can be ground, depending on the spatial orientation between the grinding wheel and the cutting knife. With a diamond grinding wheel, the wear behavior is better and the wheel geometry is more stable. The diameter of the so-called profiling point, which can be precisely determined, does not change during a technological phase compared to a CBN grinding wheel. Compensation for the position of the diamond grinding wheel is therefore not necessary. In addition, a knife shoulder, in which the oversize is larger, can be produced in a separate technological phase, which contributes to increasing the efficiency of the process.

The cutting knives to be ground using the method according to the invention can consist of different types of hard metal.

A knife flank produced with the grinding wheel according to the invention can consist of one or more geometric surfaces. The surface and flank shape is created by the relative positioning of the grinding wheel and cutting knife. In this sense, the cylinder area creates the grinding wheel a concave surface, whereas the end region can produce a curved or a flat surface. Therefore, the knife flank can consist of two or more than two different surfaces (eg a concave surface with a larger clearance angle and a flat facet with a smaller clearance angle).

Advantageous embodiments of the invention form the subject of the subclaims.

If, in an advantageous embodiment of the method according to the invention, the first spatial orientation between the grinding wheel and the cutting knife is achieved by adjusting a first position of the cutting knife in relation to the grinding wheel and the second spatial orientation between the grinding wheel and cutting knife by adjusting a second position of the cutting knife in relation to the grinding wheel is achieved, a conventional grinding machine can be used, in which the grinding wheel is rotatable about its own axis and vertically movable in the Y-axis.

If the first position of the cutting blade, is in a further advantageous embodiment of the method according to the invention chosen such that the grinding wheel generates the surface on the ^• cutting blades with a port in a cylinder area of the grinding wheel first surface element of the annular surface, and the second position chosen of the cutting blade so If the grinding wheel grinds over at least a part of the area produced on the cutting knife with a second surface element of the ring area located in an end area of the grinding area, then the concave surface produced with the cylinder area can optionally be grinded over with the end area so that the area created remains concave or becomes flat or at least partially flat.

If, in a further advantageous embodiment of the invention, the second position of the cutting knife is selected such that the grinding wheel covers the at least part of the area generated generated on the cutting blade as a concave or ^'planar facet, only the spatial orientation between the grinding wheel and the cutting blade needs to be selected accordingly.

If, in a further advantageous embodiment of the method according to the invention, the removal takes place only by infeed in a Y axis of the machine when generating a surface on the cutting knife, the generation grinding process can be controlled in a simple manner.

If, in a further advantageous embodiment of the method according to the invention, the generation of the surface on the cutting knife takes place only with three mutually perpendicular linear axes and other axes are used as mere adjustment axes and are positioned on the cutting knife before the actual generation grinding of the surface, can be carried out by three controlled linear movements any desired area on the cutting knife on a conventional grinding machine such as a B22 grinding machine from the applicant (see company brochure "CNC Tool Grinding Cell Oerlikon B22", OGT-B22 / D / hJ) or type B5 from the applicant (cf. both Company brochures each with the designation "profil B 5", K 1.11 - d / e - cH or OGT-profil B5 / E / dH).

If, in a further advantageous embodiment of the method according to the invention, the surface on the cutting knife is generated in one and / or in the other step in two passes by two first or second translational relative movements between the grinding wheel and the cutting knife, the surface can be in each case two steps roughing and finishing.

If, in a further advantageous embodiment of the method according to the invention, this is carried out on a CNC machine, the grinding process can be controlled in terms of geometry and technology in the usual way. If a CDS computing system (CDS is the abbreviation for Controlled Disk System) is used in a further advantageous embodiment of the method according to the invention for determining interrelationships between geometric and technological parameters for the generation grinding, only a special program package is required in order to use a conventional grinding machine , for example of the above-mentioned type B22, to convert to the generation loop according to the invention.

If, in a further advantageous embodiment of the method according to the invention, the surface on the cutting knife is produced in one step with at least one roughing cut and the at least part of the generated surface is ground with a finishing cut in the other step, each surface can be generated separately and influence the surface macro and micro geometry of the surface separately.

If, in a further advantageous embodiment of the method according to the invention, the translational relative movement between the grinding wheel and the cutting knife is generated by giving the cutting knife a pushing or pulling movement relative to the grinding wheel, the desired simple workflow can be achieved by appropriate selection of this movement.

If, in a further advantageous embodiment of the method according to the invention, the cutting knife is given a pulling movement relative to the grinding wheel with a finishing cut, this is the preferred workflow, but depending on the surface to be ground, instead of the pulling movement, an impact movement for the Finishing cut can be advantageous. Each technological phase (roughing or finishing) can be geometrically and technologically defined separately in the advantageous embodiments of the method according to the invention.

If in a further advantageous embodiment of the method according to the invention a grinding wheel is used, which in of their entire ring surface used for grinding has the same specifications, the roughing cut and finishing cut are advantageously selected solely by selecting feed parameters such as feed direction and speed.

In a further advantageous embodiment of the method according to the invention, roughing and finishing in the two steps of the method according to the invention and thus the surface elements of the ring surfaces used for grinding are interchangeable. Two technological phases, roughing and finishing, may be required, but the technological process may involve multiple roughing cuts and one finishing cut, and vice versa.

If, in an advantageous embodiment of the grinding wheel according to the invention, the working area is an annular surface which has an arcuate profile in axial section that extends over an overall contact angle, the roughing and finishing work areas of the grinding wheel can be shifted against one another within this working area by choosing different profile tilt angles or even separate.

If the total contact angle is approximately 145 °, the part of the working area used can be selected in the end area and / or cylinder area of the grinding wheel.

If in a further advantageous embodiment of the grinding wheel according to the invention the arcuate profile is circular and has a radius of curvature which is in a range from 0.5 to 5 mm and preferably from 0.5 to 1 mm and most preferably 0.5 mm or less there are flexible options for processing the cutting knife.

If, in a further advantageous embodiment, the grinding wheel according to the invention has a fixed geometry and cannot be dressed, its manufacture is particularly simple. It is much easier to just go with a certain radius IG

Grind if the radius is kept constant, which is the case with diamond grinding wheels that have a long service life. It can be assumed that the method is carried out with a constant radius, which simplifies and simplifies the control of the process. The question of whether a dressable or non-dressable grinding wheel is used depends on the grinding ability of the grinding wheel.

A non-dressable grinding wheel preferably consists of a metallic carrier body to which an abrasive coating made of diamond grains and a galvanic bond from which the diamond grains protrude is applied, the galvanic bond preferably consisting of nickel.

Instead of a non-dressable grinding wheel, a dressable grinding wheel can also be used. This is easily possible due to the construction of the type B22 machine, because the machine has a suitable dressing device and suitable dressing software is provided in order to be able to dress the grinding wheel occasionally in order to profile its radius again.

Embodiments of the invention are described below with reference to the drawings. Show it

1 shows a conventional grinding machine of type B22 from the applicant, which is prepared by further developing its software for carrying out the method according to the invention,

2 shows a schematic illustration of a cup grinding wheel for the method according to the invention,

3 is an explanatory view of the grinding wheel according to the invention,

4 is an enlarged detail of the working area of the grinding wheel according to the invention, 5a-5c three different types of knives which can be grinded by the method according to the invention on a machine according to FIG. 1, the arrangement of the cutting knife in a knife head on the left and the arrangement of the cutting knife in the clamping device of the grinding machine on the right,

6a shows the division of the cuts on a cutting knife with different abrasion on the knife shoulder and tip,

Fig. 6b, the division of cuts on a cutting knife with approximately constant removal on the knife shoulder and

-tip, fi ^' g. 7 the use of the method according to the invention for

Roughing the surface of a cutting knife in two

Passages,

8 shows the use of the method according to the invention for finishing the same area as in FIG. 7,

9 the grinding of a shoulder on a cutting knife with the grinding wheel according to the invention on the software-developed grinding machine of the B22 type,

10 shows the different possible grinding positions for different technological phases for grinding a cutting knife with the grinding wheel according to the invention,

11 the roughing of a free surface on the cutting knife with the grinding wheel according to the invention,

12 the finishing of the same free surface as in FIG. 11 with the grinding wheel according to the invention, 13 the determination of the working area of the grinding wheel during roughing,

14 is an illustration for explaining how a total contact angle GKW is shifted by changing a profile tilt angle PKW,

15 the determination of the working area of the grinding wheel according to the invention during finishing,

16a the conditioning of a dressable grinding wheel with a contour roller when approaching the grinding wheel contour, and

16b the conditioning of a grinding wheel according to the invention with a dressing roller by interpolation around the grinding wheel contour.

1 shows a knife grinding machine of the applicant's type B20, designated overall by reference number B22, which is actually intended for grinding bar knives with profiled disks in the form grinding process, but here has an extension for grinding cutting knives, in particular hard metal knives, in the production process. The extension consists primarily of an extension of the software for controlling the knife grinding machine 20, in particular in the area of the adaptation control (PMC), the machining cycles and macros of the CNC, the user interface and the data management with an integrated PC. The CNC has the function of the "master" and is used for axis control, for executing the part programs (process sequence control), the part program management and for CNC screen displays. The adaptation control, also called PLC, takes over the interface function between the CNC and the knife grinding machine, the control of machine processes, monitoring functions, machine control panels, digital input / output and interface to the robot / magazine. Because of the available resources (RAM in the PC), a program is created for each of the two grinding processes (form and production grinding) created for the user interface. The change between the user interface for form or production loops can be carried out during the startup of the PC software. The knife shape is only generated with the linear axes X, Y, Z. An A and a C axis are pure adjustment axes and are positioned before the actual grinding of the knife surfaces. The path calculation and the cutting division take place in the PC, so that only macros and cycles for workpiece change and conditioning of the grinding wheel have to be available on the CNC level. The main interpolation plane for grinding the cutting knives is formed by the axes Y and Z.

The workpiece spectrum comprises cutting knives 22, of which three different types are shown in FIGS. 5a-5c. The structural geometry and the arrangement in a cutter head 24 are different for the three cutter types, and consequently the three cutter types are ground in three different clamping devices 26, Fig. 5a shows a clearance angle of 8 ° on the left and a cutter inclination angle of 20 ° in the cutter head. Correspondingly, the cutting knife 22 in FIG. 5a on the right in the clamping device 26 must have an inclination angle of 28 ° so that the head of the knife is arranged for grinding without a clearance angle. The same applies to the representations in FIGS. 5b and 5c. The angles given on the far left and top left in FIGS. 5a and 5c are not of interest for the description here and therefore do not need to be explained in more detail. When the surface is generated on the cutting knife 22, the removal takes place only by infeed in the Y axis of the machine, which is indicated in FIGS. 1 and 5a.

An important prerequisite for the method described here, which has been developed in particular for hard metal grinding, is the properties of the A axis of the knife grinding machine 20 shown in FIG. 1. In the conventional form grinding method, the A axis is only used for device positioning and is then clamped . The head radius is generated by at least two translational movements (Y, Z). These translational movements are described in more detail below with reference to FIGS. 7-15. The generation grinding method described here is carried out with a grinding wheel 28, which is preferably a diamond cup grinding wheel. The grinding disc 28 is shown schematically in axial section in Fig. 2 and in an enlarged partial view in the working position in Fig. 3. In the embodiment shown in FIG. 3 and described here, the grinding wheel 28 consists of a carrier body 30 made of steel, to which an abrasive coating 32 made of grain and galvanic bond is applied. The galvanic bond consists of nickel, which was electrolytically deposited on the carrier body 30 made of steel in galvanic baths. The diamond grains (not shown in detail) protrude from the bond after the galvanic treatment is complete. A dressable grinding wheel could be bound with synthetic resin.

FIG. 4, to which reference is also made, shows a further enlarged work area 34. The grinding wheel 28 has a grinding or rounding radius R. A part 34 'of the working area 34 lies in a front area and a part 34' 'of the working area 34 lies in a cylinder area of the grinding wheel 28. The grinding wheel 28 has a fixed geometry and cannot be dressed . When the tool life is at an end, the work area 34, i.e. the active surface of the grinding wheel can be occupied again.

3, the grinding wheel 28 has the grinding or rounding radius R on the grinding edge, a wheel radius SR up to a tangent to the grinding edge, a wheel height SH from a spindle contact surface 36 to a tangent to the grinding edge, an inside angle IW an inner surface (cone) 40 to the axis 38 of the grinding wheel 28 and an outer angle AW of an outer surface (cone) 42 to the axis 38. The working area 34 of the grinding wheel 28 is an annular surface which, as shown in FIG The end region extends to a point 46 in the cylinder region of the grinding wheel 28 and, in the axial section shown in FIG. 4, has an arcuate profile which extends over an overall contact angle GKW which is shown in FIGS. 13 to 15 is shown and will be described in more detail with reference to these figures. The total contact angle GKW is about 145 °. The arcuate profile is arcuate, and the radius of curvature is in a range from 0.5 to 5 mm and preferably from 0.5 to 1 mm.

The grinding wheel has one and the same grinding covering in the entire working area 34, i.e. the different parts of the work area do not have to be coated differently in order to be used for roughing or finishing. The coating limits of the working area 34 are designated in the illustration in FIG. 4 with 48 or 50, the respective overhang beyond which the coating limit extends beyond the actual working area with 52 or 54. The angle within which the grinding wheel 28 with the Head of the cutting knife 22 can come into contact during grinding, is referred to as the head contact angle KKW. The head contact angle for the use of the grinding wheel 28 during roughing corresponds to the part 34 ″ of the working area, and that for the finishing to the part 34 ′ of the working area, as shown in FIG. 4. The use of these different parts of the work area for roughing and finishing is explained in more detail below.

A cutting knife to be ground has three active surfaces, namely two open surfaces 56 (only one of which is visible in FIG. 5a) and a rake surface 58. These three surfaces can be defined separately on the knife grinding machine 20 and then ground separately. Each free area can consist of two different areas (with two different clearance angles and with two geometries). The technological process can include several roughing and finishing cut ^¬. Each technological phase (roughing or finishing) or sparking can be defined separately.

In FIGS. 13, 14 and 15, the roughing and the finishing ^¬ technology represented schematically. During roughing (FIGS. 13 and 14), the cutting knife 22 is turned by a profile tilt angle PK tilted so that the working area 34 is brought into contact with the cylinder area of the grinding wheel 28. The free surface of the cutting knife generated in this way becomes concave on the flank and cylindrical at the head of the cutting knife 22. In the production grinding method described here, it is provided that the "roughing free surface" is ground with a larger clearance angle than the "finishing free surface". 13 and 14 it can be clearly seen that the total contact angle GKW depends on the profile tilt angle PK. The profile contact angle PKW is in a range from alpha to 90 ° - alpha. For different profile tilt angles PK, the different parts 34 ', 34''of the working area 34 of the grinding wheel 28 are brought into contact with the cutting knife 22. In this way, the roughing and finishing parts of the working area 34 of the grinding wheel 28 can be moved relative to one another or even separated from one another. The separation limit is PK = 90 ° - Alpha (with different grinding methods: bumping or pulling).

14 serves to explain how the profile tilt angle PK shifts the total contact angle GKW.

For the finishing phase, which is described with reference to FIG. 15, the knife profile is positioned vertically (PK = - Alpha). The grinding wheel 28 processes the flank of the cutting knife 22, in which the generatrix is an arc in one plane. A flat or cylindrical facet is created on the flank, the width of which can be calculated. Only at the head of the cutting knife 22 is no theoretically exact cylinder produced, but there will be a correct cutting edge. The "finishing clearance angle" is set smaller than for roughing, and the two different surfaces are created in this way. The value of the "finishing clearance angle" must of course be correct for the machining process. As mentioned above, the different areas 34 ″ and 34 ′ of the grinding wheel 28 are stressed by different positioning of the cutting knife 22 during roughing and finishing, which will lead to an increase in tool life. If the profile tilt angle PK smaller than 90 ° - alpha, there is always an overlap between roughing and finishing.

Fig. 6 shows the cut distribution for a knife processing, in which the removal takes place only by infeed in the knife axis. With this method, the removal on the knife shoulder and on the knife tip is significantly greater than on the side surfaces. If it is necessary due to the grinding technology that the removal is approximately constant, a suitable cut distribution must be calculated. Additional intermediate positions must then be implemented in the correct order in a CNC part program with the correct chronological sequence of the grinding operations. The additional grinding operations are marked gray in Fig. 6b.

The knife processing is described below using the example of a surface that is roughed in two passes and then finished with reference to FIGS. 7 and 8. For roughing in two passes, the cutting knife, which is clamped in the clamping device 26 (see FIG. 5a) not shown in FIGS. 7 and 8, is used to move to positions which are designated by 0-14. 7 shows the first pass on the left and the second pass on the right. The grinding wheel 28 maintains its position in each case, and the represented positions are approached with the cutting knife 22 itself, although the illustration in FIGS. 7 and 8 is selected as if the grinding wheel 28 were being moved. However, as the illustration in FIG. 1 shows, this can only perform a movement in the Y axis. The movements in the X, Z and, if necessary, in the Y axis are carried out by the clamping device 26, in which the cutting knife 22 is clamped.

In Fig. 7, 0 is the starting position, which can be approached from a standard position without collision. This position corresponds to X = 0, Y = 0, Z = 0, with the effective zero offset. The dashed arrows indicate rapid traverse, the solid arrows indicate feed. 13

The polygon point that is still approached in rapid traverse is designated by 1. 2-6 are the path points of the first pass that are approached with feed. Points 7 and 8 are intermediate points that are approached in rapid traverse. Points 9-14 are path points of the second pass, which are approached with feed. From point 14 the retraction to the standard position takes place in rapid traverse.

In FIG. 8, 0 is again the starting position, which can be approached from a standard position without a collision. 1 is the first railway point that is still approached in rapid traverse. 2-6 are the path points that are approached with feed. From point 6 the retraction to the standard position takes place in rapid traverse. 9-12 show how the operations shown schematically in FIGS. 7 and 8 are actually carried out on the knife grinding machine 20.

In FIG. 9, the cutting knife 22 is set so that the grinding wheel 28 with the part 34 ″ of its working area located in the cylinder area grinds a surface (A) of the cutting knife 22, namely roughing, starting from a shoulder 21 to a head 23 of the cutting knife 22.

10 shows the different possible grinding positions for different technological phases for grinding the cutting knife 22 with the grinding wheel 28.

As shown in FIG. 11, the other surface (B) of the cutting knife 22 is ground with the part 34 ″ of the working area located in the cylinder area, that is to say also roughed.

As shown in FIG. 12, the surface of the cutting knife 22 previously machined by rough grinding is then brought into a vertical position in which it is tangential to the end region of the grinding wheel 28. In this position, this surface of the cutting knife 22 is finished. The setting of the knife with respect to the grinding wheel movable in the Y-axis will now be described in detail with reference to FIGS. 13-15. Of the grinding wheel 28, only the grinding edge is in each case in FIGS. 13-15

Circle indicated, which corresponds to the circle shown in Fig. 4 at the cutting edge. The grinding wheel, which is not otherwise shown, has the same orientation as in Fig. 4, i.e. its end face extends vertically and the axis of rotation is horizontal.

13-15, the roughing and finishing technology are shown schematically. During roughing (FIGS. 13 and 14), the cutting knife 22 is tilted by the profile tilt angle PKW, so that the profile is brought into contact with the cylinder region of the grinding wheel 28. In this way, a free area is generated which is concave on the flank and is cylindrical on the head 23 of the cutting knife 22. The "roughing surface" is preferably ground with a larger clearance angle than the "finishing surface". 13 and 14 it can clearly be seen that the total contact angle GKW is dependent on the profile tilt angle PKW, as already explained above.

For the finishing phase (Fig. 15) the knife profile is positioned vertically (PK = - Alpha). The grinding wheel 28 processes the flank of the cutting knife with its end face, in which the generatrix is an arc in one plane, as also already explained.

As mentioned above, different parts of the working area 34 of the grinding wheel 28 are stressed by different positioning of the cutting knife during roughing and finishing. The feed direction (pushing or pulling) naturally plays an important role.

The method described above for grinding little ^¬ least a surface on a cutting knife 22 used in cutting technology with a rotating around the axis 38 Grinding wheel 28, whose working area 34 is an annular surface that has an arcuate profile in axial section (cf. in particular FIG. 4), can be summarized as follows:

a) First, a surface on the cutting knife 22 is created by grinding with the ring surface under a first spatial orientation between the grinding wheel 28 and the cutting knife 22 by at least a first translational relative movement between the grinding wheel and the cutting knife, as is the case for a surface e.g. is shown in Fig. 11, and

b) Subsequently, at least a part of the surface created is ground with the ring surface under a second spatial orientation between the grinding wheel 28 and the cutting knife 22 by at least one second translational relative movement between the grinding wheel 28 and the cutting knife 22, as shown in FIG. 12 .

Preferably, the first and the second spatial orientation between the grinding wheel 28 and the cutting knife 22 are achieved by adjusting a first and second position of the cutting knife 22 with respect to the grinding wheel 28. Depending on the inclination of the cutting knife 22 in FIG. 12, the grinding wheel 28 produces the at least part of the area generated on the cutting knife 22 as a concave or even facet. When generating the surface on the cutting knife 22, the removal is expediently effected only by infeed in a knife axis. It is essential to the invention that only translatory relative movements are carried out between the cutting knife 22 and the grinding wheel 28. Neither the grinding wheel 28 nor the cutting knife 22 needs to be rotated during the machining of the knife, of course apart from the rotation of the grinding wheel about 28 about its own axis 38. The surface on the cutting knife 22 can be in step a) and / or in step b) is produced in two passes by two first or second translational relative movements between the grinding wheel 28 and the cutting knife 22. It has already been explained above that the method is preferably carried out on a CNC machine and that a CDS computing system is used to determine interrelationships between geometric and technological parameters for the generation grinding. It was further described above using an example that the surface on the cutting knife 22 in step a) is produced in two passes, that is to say with two roughing cuts. However, it is clear that at least one rough cut is sufficient. The at least part of the surfaces generated is then ground in step b) with a finishing cut.

The translational relative movement between the grinding wheel 28 and the cutting knife 22 is generated in that the cutting knife 22 relative to the grinding wheel 28 has an impact movement (as shown for example in FIGS. 13 and 14) or a pulling movement (as shown for example in FIG. 15). is given. The particular advantage of grinding wheel 28, which is used in the method described here, is that the grinding wheel has the same specifications in its entire ring surface used for grinding, that is to say that the grinding wheel has, for example, one and the same grinding covering in the entire working area, and that the selection of roughing cut and finishing cut is made solely by selecting feed parameters such as feed direction and speed, cutting speed and oversize.

The surface elements of the ring surface, which are used in steps a) and b) for roughing or finishing, are interchangeable.

The method described here is preferably used to grind hard metal knives using a diamond cup grinding wheel.

The grinding wheel 28 can be dressable or non-dressable. If a dressable grinding wheel is used, the dressing could be carried out in the following ways:

Dressing with a contour roller 66 (FIG. 16a) which has the negative correction. In this case, no further axis movements are necessary, except for moving to the grinding wheel 28

Dressing with a contour roller 68 which has a contour similar to that which is usually used. In this case, the contour roller 68 must be used to trace a contour around the window profile.

Because of the inclined dressing spindle axis, the usual arrangement of the dressing unit cannot be adopted. With a new input signal, the controller must be informed that the dressing device (contour roller 66 or 68) has been set up for the diamond cup grinding wheel, so that software limit switches can then be activated and additional monitoring and plausibility checks can be carried out with regard to the grinding process. 16a schematically shows the conditioning with the contour roller 66 and with linear interpolation when approaching the grinding wheel contour. 16b shows the conditioning with the contour roller 68 by interpolation around the grinding wheel contour. In both cases, the conditioning process can take place at different relative speeds of the points of contact between the cup wheel and the dressing tool in order to achieve the desired surface quality or abrasion capacity of the grinding wheel 28. The actual dressing process will be a cycle stored in the CNC, which accesses the data from the tool database. The conditioning process according to FIG. 16b can be carried out if the condition for the radii and the steepness of the cone is fulfilled. Then there is a theoretically punctiform contact between the grinding wheel 28 and the dressing roller 68. The dressing cycle must be designed so that a dressing roller with a cylindrical part and one radius each can be attached to the edge.

It is stated above that at least two translational movements are necessary, namely one for the flank of the cutting knife 22 and one for the head 23 of the cutting knife 22, however, a third translational movement could also be used.

The optimization that is carried out in the generation grinding method described here can consist, for example, in that the force on the grinding surface remains constant. To achieve this optimization, it is e.g. possible to design the surfaces on the cutting knife 22 so that the cutting performance of the grinding wheel 28 always remains the same. The grinding wheel manufacturer usually recommends a certain cutting performance that should be maintained. The user then has the option of adapting the knife surfaces to be ground. A controlled cut distribution, as described above with reference to FIGS. 6a and 6b, enables a better optimization of the grinding process, namely constant power or forces, production of a desired facet width, etc.

A further optimization consists in the fact that the ground surface can be either flat or concave in the final state and that each free surface itself can consist of a combination of two free surfaces. For this purpose, only the spatial orientation between the grinding wheel 28 and the cutting knife 22 needs to be selected accordingly, combined with an abutting or pulling movement of the cutting knife 22, as set out above. The method described here is therefore extremely flexible. Industrial applicability

With a grinding wheel rotating about an axis, the working area of which is an annular surface that has a circular arc-shaped profile in axial section, a surface is first made on a cutting knife by grinding with the annular surface under a first spatial orientation between the grinding wheel and cutting knife by at least a first translational relative movement generated between them and then at least a portion of the generated area with the annular surface is ground with a second spatial orientation between the grinding wheel and the cutting knife by at least one second translational relative movement between them. The grinding wheel is a diamond cup grinding wheel. The working area lies with a part in a front area and with another part in a cylinder area of the grinding wheel. One part is used for rough grinding and the other part is used for finish grinding the surface to be produced on the cutting knife. The grinding wheel has one and the same grinding covering in the entire working area. Roughing and finishing are carried out using areas of the grinding wheel that have the same specifications, but with different grinding parameters. The spatial orientation between the grinding wheel and the cutting knife is preferably selected by adjusting the cutting knife in relation to the grinding wheel. The method allows surfaces to be created on a cutting knife that can be flat and / or concave, enables a simpler workflow and the use of a grinding wheel with a simpler configuration than in the prior art.

Claims

claims

1. A method for grinding at least one surface on a cutting knife (22) used in machining technology with a grinding wheel (28) rotating about an axis (38), the working area (34) of which is an annular surface which has an arcuate profile in axial section , by

a) generating a surface on the cutting knife (22) by grinding with the ring surface under a first spatial orientation between grinding wheel (28) and cutting knife (22) by at least a first translational relative movement between grinding wheel (28) and cutting knife (22), and b ) Grinding at least a part of the generated surface with the ring surface under a second spatial orientation between grinding wheel (28) and cutting knife (22) by at least a second translational relative movement between grinding wheel (28) and cutting knife (22).

2. The method according to claim 1, characterized in that in step a) the first spatial orientation between the grinding wheel (28) and cutting knife (22) is achieved by adjusting a first position of the cutting knife (22) with respect to the grinding wheel (28) , and that in step b) the second spatial orientation between grinding wheel (28) and cutting knife (22) is achieved by adjusting a second position of the cutting knife (22) with respect to the grinding wheel (28).

3. The method according to claim 2, characterized in that the first position of the cutting eater (22) is selected so that the grinding wheel (28) the surface on the cutting knife (22) with a first in a cylinder region of the grinding wheel (28) Surface element of the ring surface generated, and and that the second position of the cutting knife (22) is selected such that the grinding wheel (28) overlaps the at least part of the surface created on the cutting knife (22) with a second surface element of the ring surface located in a front region of the grinding wheel (28).

4. The method according to claim 3, characterized in that the second position of the cutting knife (22) is selected so that the grinding wheel (28) generates the at least part of the surface generated on the cutting knife (22) as a concave or flat facet.

5. The method according to any one of claims 1 to 4, characterized in that during the generation of the surface on the cutting knife (22), the removal takes place only by infeed in a Y axis of the machine.

6. The method according to any one of claims 1 to 5, characterized in that the generation of the surface on the cutting knife (22) only with three mutually perpendicular linear axes (X, Y, Z) and other axes (C, A) as mere adjustment axes used and positioned on the cutting knife (22) before the actual grinding of the surface.

7. The method according to any one of claims 1 to 6, characterized in that the surface on the cutting knife (22) in step a) and / or in step b) in two passes by two first or second translational relative movements between the grinding wheel ( 28) and cutting knife (22) is generated.

8. The method according to any one of claims 1 to 7, characterized in that the method is carried out on a CNC knife grinding machine (22).

9. The method according to claim 8, characterized in that a CDS computing system is used to determine interrelationships between geometric and technological parameters for the generation grinding.

10. The method according to any one of claims 1 to 9, characterized in that the surface on the cutting knife (22) in step a) is produced with at least one roughing cut and that the at least part of the surface generated in step b) with one Finishing cut is ground.

11. The method according to any one of claims 1 to 10, characterized in that the translational relative movement between the grinding wheel (28) and cutting knife (22) is generated in that the cutting knife (22) relative to the grinding wheel (28) a pushing or pulling movement is given.

12. The method according to claim 10, characterized in that the grinding knife (22) is given a pulling movement relative to the grinding wheel (28) when grinding with a finishing cut.

13. The method according to claim 10, characterized in that a grinding wheel (28) is used which has the same specifications in its entire ring surface used for grinding, and that the selection of roughing cut and finishing cut solely by selecting feed parameters such as feed direction and speed , Measurement and grinding speed.

14. The method according to claim 10 or 13, characterized in that roughing and finishing in steps a) and b) and thus the surface elements used for grinding the ring surface are interchangeable.

15. Use of the method according to one of claims 1 to 14 using a diamond cup grinding wheel (28) for grinding hard metal knives (22).

16. Grinding wheel for carrying out the method according to any one of claims 1 to 15, characterized in that the grinding wheel (28) is a diamond cup grinding wheel with a working area (34) which to a part (34 ') in an end region and to one Part (34 '') lies in a cylinder area of the cup grinding wheel.

17. Grinding wheel according to claim 16, characterized in that the working area (34) is an annular surface which has an arcuate profile in axial section which extends over an overall contact angle (GKW).

18. Grinding wheel according to claim 17, characterized in that the total contact angle (GKW) is approximately 145 °.

19. Grinding wheel according to one of claims 16 to 18, characterized in that the arcuate profile is arcuate and has a radius of curvature (R) which is in a range from 0.5 to 5 mm and preferably from 0.5 to 1 mm.

20. Grinding wheel according to one of claims 16 to 19, characterized in that the grinding wheel (28) has a fixed geometry and is not dressable.

21. Grinding wheel according to claim 20, characterized in that the grinding wheel (28) from a metallic carrier body

(30), on which an abrasive coating (32) made of diamond grains and a galvanic bond from which the diamond grains protrude is applied.

22. Grinding wheel according to claim 21, characterized in that the galvanic bond consists of nickel.

23. Grinding wheel according to one of claims 16 to 19, characterized in that the grinding wheel (28) can be dressed.

24. Grinding wheel according to one of claims 16 to 23, characterized in that the grinding wheel in the entire working area (34) has one and the same grinding surface (32).