WO2008101263A1 - Dressing tool - Google Patents

Abstract

The invention relates to a dressing tool for the surface treatment of grinding tools, the tool having a base body, which comprises one or more dressing surfaces, which are at least partially equipped with superhard cutting materials, such as diamond monocrystal grains, and have a plurality of recesses into which the edge protecting elements are inserted and in which the same are fixed, wherein polycrystalline edge protecting elements (7, 8, 9, 14, 15) having a geometrically defined shape are inserted into the plurality of recesses, and the polycrystalline edge protecting elements (7, 8, 9, 14, 15) are embedded in the base body in a positive and non-positive manner, wherein the recesses are adjusted to the geometric shape of the polycrystalline edge protecting elements (7, 8, 9, 14, 15).

Description

 dressing tool

The invention relates to a dressing tool for the surface treatment of abrasive tools having a base body which has one or more dressing surfaces which are at least partially coated with high-hardness cutting materials, e.g. Diamond single crystal grains are occupied and have a plurality of wells, in which edge protection elements are inserted and fixed.

Dressing tools fulfill a key function in terms of quality and cost-effectiveness of the entire manufacturing process in all grinding processes. Only with properly adapted dressing tools and with correspondingly effective use of grinding processes are inexpensive and efficient controllable and only then the high performance potential of the grinding tools can be retrieved successfully.

By dressing and profiling, the grinding tools get their geometric shape, the required, precise concentricity and the desired surface finish of the effective surface of the grinding wheel (Wirkrautiefe), with which the workpiece surface is controlled and reproducibly influenced. Although a rough dressed grinding wheel surface (high effective roughness depth) will work well and aggressively, it will produce a poor tool surface, while a grinding wheel with less effective roughness will remove less efficiently, but will allow workpiece surfaces of higher quality. By choosing the dressing tool correctly, the grinding process can be decisively influenced in terms of performance and cost-effectiveness.

Dressing tools of various designs have been known for a long time and are used in dressing tools, e.g. Single- and multi-grain dressers, dressing tiles, etc. and subdivided into rotating dressing tools, which also include the dressing rollers or dressing and profiling discs.

The rotary dressing tools are after the negative process and after the Positiwerfahren generated in galvanic and sintered bond.

Dressing tools made by electroplating have a metallic base body and are coated on their circumference or on their peripheral surfaces and on the frontally adjacent surfaces, on the peripheral apex and also on the tool flanks with diamond grains, which may be formed from artificial or natural diamonds.

The fixation of the high-strength abrasive grains is carried out by applying the electroplating process, wherein the abrasive grain is first attached and then embedded depending on the application at different depths electrochemically. The adhesion or embedding can alternatively be done by means of chemical processes.

The dressing tools thus produced find their application in giving grinding wheels their required shape after passing through a large number of working processes. The grinding wheel to be dressed and the dressing wheel rotate at different rotational speeds.

A disadvantage of the known dressing tools is that the very hard diamond grain is only partially firmly fixed to the base body by the particular metal used, which is used for galvanic embedding. This has the consequence that during the profiling or dressing process, the embedding material is subject to considerable abrasion, which causes the diamond grains protrude further and further out of the embedding until they finally fall out of the metal frame. On the other hand, due to the intensive mechanical stress of the single-ply layer, it is processed rapidly, which leads to very short service lives and thus to high grinding costs.

Finally, a further weakness of the abovementioned dressing tool is that the diamond layer on the dressing wheel wears itself off at different speeds and thus, particularly in the highly loaded edge region, its efficiency loses in terms of grain utilization. The wear occurs mainly at the edge regions of the dressing wheel, since the diamond grains find little support on these.

In DE 298 19 006 U1 a diamond dressing wheel is described, which is covered on its peripheral surface and / or its end face with randomly shaped diamond grains. In an end face of the dressing wheel approximately radially extending grooves are formed, which extend into the peripheral edge, in which elongated diamonds are inserted and fixed. Or these are radially formed in the peripheral edge itself. The elongated diamonds protrude with their end into the peripheral surface and reduce the wear of the dressing wheel, whereby their efficiency can be improved.

DE 101 46 952 A1 discloses a diamond dressing wheel whose diamond grains bound with a binder to form an abrasive coating are significantly larger and less splintered than the diamond grains of the diamond grinding wheel to be dressed.

All of these dressing systems have the disadvantage that they either insufficiently protect either the particularly stressed attack surfaces of the dressing wheel or that the breaking out of the diamond grains is not prevented by insufficient edge protection elements. But above all, the outer peripheral edges of the

Dressing discs are insufficiently secured against abrasion, which has the consequence that the

Dressing wheels achieve only short service lives, cause idle times and thus high grinding costs when changing the wheel.

Another disadvantage arises from the undefined shape of the edge protection elements used so far, which are formed from elongated, acicular diamond with irregular shape, resulting in a poor embedding and a slight diamond eruption and impact and temperature sensitivity.

The object of the invention is therefore to provide a dressing tool of the type mentioned specify that prevents the excessive abrasion of the diamond coating, especially on the particularly stressed disc areas, resulting in better removal performance and reduced costs of the dressing tool and the entire grinding process.

Another object of the invention is to provide a dressing tool of the type mentioned, which withstands highest loads, without causing a loosening or breaking of the edge protection elements.

Furthermore, it is an object of the invention to ensure a long life and high wear resistance of the edge protection elements.

According to the invention, this is achieved, on the one hand, by inserting polycrystalline edge protection elements with a geometrically defined shape into the multiplicity of depressions, and by embedding the polycrystalline edge protection elements in the basic body in a positive and non-positive manner, wherein the depressions are adapted to the geometric shape of the polycrystalline edge protection elements.

The high-precision dressing body of the metal dressing tool according to the invention, e.g. Aluminum, steel, etc. are profiled, giving the body the final shape needed for the application. In a subsequent operation, a plurality of recesses (slots) are incorporated in the prepared basic body shape, which correspond to the geometric shape of the polycrystalline edge protection elements, thereby ensuring that they are accurately embedded in the base body and fixed there.

With the edge protection elements according to the invention an improved embedding in the dressing body and thus stronger fixation is achieved, whereby impact and temperature sensitivity are reduced. The specific shape of the edge protection elements, their wear is extremely reduced and the dressing performance can be increased many times. The resulting,

- A - Sustainable anchoring has the effect that the forces occurring during dressing are transferred directly to the base body and no steadily increasing loosening of the edge protection elements is more observable.

Depending on the dressing tool edges, the geometric shape of the edge protection elements according to the invention may be selected differently and the polycrystalline edge protection elements may be formed with a cross-sectional area adapted to the grinding wheel geometry.

The edge protection elements are so attached to the tool circumference, without projecting about this, that they protect the most extreme stress zones of the grinding or dressing zones of the dressing tool according to the invention, the edge protection elements can be used if necessary even along a pointed conical body.

So far it has been, e.g. According to DE 35 03 914 A1 common, the polycrystalline edge protection elements of any shape, as they result from the production to use in prepared slots in the dressing tool and then make a galvanization, in which remaining gaps and voids between the edge protection elements and the slot walls are filled. At high loads during the dressing, it comes after some time to a relaxation of the seat of the edge protection elements and thus to a drastic decrease in tool quality.

In the invention, the edge protection elements are in contrast inserted in a geometrically defined shape in the body and the recess is adapted to this geometric shape so that just form and force fit prevails, whereby the best possible fixation and embedding is given in the dressing tool. Thus, during the dressing process, the absorption of the forces acting on the edge protection elements takes place via the base body.

The achievable in this way increased resilience and durability of the dressing tool according to the invention exceeds those properties of the known from the prior art tools by a multiple.

The dressing tool according to the invention can be designed as a dressing tool or as a surface treatment tool, wherein the side surface can be coated on one or both sides with abrasive grain. In addition, the dressing tool according to the invention has the possibility to use this rotating or stationary.

In the dressing tool according to the invention, the geometry of the edge protection elements on the base and on the side surfaces of the wells is tunable, resulting in an optimally adapted embedding of the edge protection elements in the wells and thus a reinforced anchorage.

The edge protectors may be configured to fit into depressions that lie along the tool surface, in some cases along an acute-angled dress and flank processing disc. The edge protection elements including the depressions can also be attached to the processing surfaces.

It has also been found that otherwise common chip combs can be omitted, and the processing results can be improved.

A further improvement of the durability and the strength of the dressing tool and thus the achievement of the object of the invention is achieved in that polycrystalline edge protection elements are used with a geometrically defined shape in the plurality of wells, and that the polycrystalline edge protection elements each have a defined orientation of their grain growth planes exhibit.

The defined orientation of grain growth levels within the edge protection elements or with respect to the dressing geometry represents a new, Previously not used in this context measure to create a dressing tool that meets the highest requirements. It has been shown that only due to this particular crystallographic orientation, the failure rate of the dressing tools according to the invention is well below the previously achieved values.

A development of the invention can therefore be, for example, that the polycrystalline edge protection elements in the form of prisms, truncated pyramids, trapezoidal shapes, cylinders od. Like. Are formed, in particular, the cylindrical edge protection elements in the form of a cylinder with oval, round, rhombic, doppelrhombischer or polygonal Cross-sectional area be formed.

Since the correct fit of the edge protection elements has a significant influence on the resistance of the dressing tool, the recesses can be adapted to the geometric shape of the polycrystalline edge protection elements.

In order to achieve the objects of the invention, an exact production of geometrical shapes from high hardness materials is required, which according to another embodiment of the invention can be achieved by forming the polycrystalline edge protection elements of polycrystalline diamond (PCD) or gas phase deposition diamond (CVD) are.

Another feature of the invention may be that the polycrystalline edge protection elements are elongated. This makes them easy to fix in the dressing body.

By the correct choice of number, angle of inclination, insertion depth and base area of the edge protection elements according to the invention, the wear of the edge protection elements on the one hand and the entire dressing tool assignment with diamond on the other hand can be reduced and it can be achieved sparing the heavily loaded edge region. If the edge protection elements are set in such a way that the grain growth planes are oriented perpendicular to the longitudinal axis in the polycrystalline edge protection elements, considerable increases in the performance of the dressing tool can be achieved.

A favorable range is further that the polycrystalline edge protection elements are oriented such that the grain growth planes enclose an angle in the range of 5 ° to 85 °, preferably an angle α equal to 45 °, with respect to the operative grinding force vector.

For this purpose, specially grown PCD-CVD single-crystal crystals can be used, in which the crystal wear can be significantly reduced by the orientation of the grain growth levels.

A further increase in dressing tool quality can be achieved when the polycrystalline edge protectors are surface treated, thereby providing an additional hardening layer on the edge protectors which increases the efficiency of the edge protectors.

Thus, for example, the polycrystalline edge protection elements can be formed with coatings of nitrides and carbides of the elements Ti, Cr, Ni, Si, Al, V, W, Ga and In or combinations thereof. Through the surface of metal carbides or metal nitrides, the edge protection elements can be made more stable.

The dressing tool according to the invention can be equipped in its diamond-coated effective area and at its outer edge with the recesses for receiving edge protection elements according to the invention, in which these are fitted and anchored, with anchoring as the galvanic or chemical nickel standard.

In addition to the pure nickel plating, the polycrystalline edge protection elements be fixed by metallic embedding with Ni, Ni alloys, Cu or Cr.

For very large edge protection elements, it may be beneficial to fix them by soldering or gluing.

The measures according to the invention are applicable to all types of dressing tools of the type mentioned, in particular rotationally symmetric dressing tools.

Hereinafter, the invention with reference to the illustrated in the drawings

Embodiments explained in detail. It shows

1 shows a section along a diameter through an embodiment of the dressing tool according to the invention.

FIG. 2A shows a section through a detail of the dressing tool according to FIG. 1; FIG. 2B is a section through a detail of another embodiment of the

dressing tool;

2C shows a section through a detail of a further embodiment of the dressing tool according to the invention;

3 shows a section through a detail of a further embodiment of the dressing tool according to the invention;

Fig. 4 is a section along a diameter through another

Embodiment of the dressing tool according to the invention;

5 shows a section through a detail of the dressing tool according to FIG. 4;

Fig. 6 is a split plan view of four embodiments of the dressing tool according to the invention;

Fig. 7 is a plan view of another embodiment of the invention

Dressing tool and

8 is a plan view of a detail "A" of the embodiment of FIG. 7.

Fig. 1 and Fig. 2A show a dressing tool 10 for surface treatment of abrasive tools with a rotationally symmetrical base body 1, the Peripheral edge 3 has three annular dressing surfaces 4, 5, 12, the od with a layer 6 of high-hardness cutting materials, such as diamond single crystal grains, CBN, carbides, nitrides or combinations based on the elements Ti, Al, Si, Co, Cr. are occupied and have a plurality of wells, in which edge protection elements 7 are used.

The base body 1 has a bore 2 in the center for receiving a drive shaft. Around the bore 2 extends on both sides of the main body 1, an annular, planar surface 20 for receiving a machine flange, not shown.

The three dressing surfaces 4, 5, 12 are subjected to a heavy load during the dressing process, which is why the edge protection elements 7 are distributed along the circumference of the main body 1 in the recesses provided for them.

According to the invention, polycrystalline edge protection elements 7, 8, 9, 14, 15 having a geometrically defined shape are inserted into the multiplicity of depressions, and the polycrystalline edge protection elements 7, 8, 9, 14, 15 are embedded in the basic body in a form-fitting and force-fitting manner, wherein the depressions engage the geometric shape of the polycrystalline edge protection elements 7, 8, 9, 14, 15 are adapted.

Since the depressions correspond exactly to the shape of the edge protection elements 7, a secure anchoring in the main body 1 of the dressing tool 10 results.

The edge protection elements according to the invention can also be used in non-rotationally symmetrical dressing tools. In principle, the shape of the dressing tools in the context of the invention can vary greatly depending on the application requirements. Single-stage and multi-stage dressing tools, as well as multi-sided dressing surfaces can be executed. Also, the geometries of the edge protection elements can be different executed and this only be integrated on one side or on several sides in the dressing surfaces.

A cross section through one of the geometrically defined edge protection elements 7 of the dressing tool 10 shown in FIG. 1 is shown in detail in FIG. The edge protection element 7 is inserted in such a way that it is embedded on the dressing surface 4 and protrudes so far forward to the edge of the dressing surface 12 and into the layer 6 present there, in order to protect it against wear. Further variants of the edge protection elements 8, 9 shown by way of example are shown in FIGS. 2B and 2.

The edge protection elements 7 can be arranged both on only one side (FIG. 3) or on both sides of the dressing tool, such as in the dressing tool 11 of the embodiment according to FIG. 4 and FIG. 5, in addition to edge protection elements 15 which are in the peripheral area also protrude further edge protection elements 16 are provided, which are further set back to form an edge reinforcement at the transition from an inclined cross-sectional profile.

Furthermore, the edge protection elements 8, 9 (FIG. 2B, FIG. 2C) are incorporated into the dressing surface 12 of the circumferential surface 3 itself or inserted therein, for which purpose a special geometry of the edge protection elements 8, 9 is required.

In the production of the base body 1 are adapted to attach the edge protection elements adapted to these recesses to allow the best possible fixation and embedding.

The so prepared dressing base body 1 is masked in the sequence by covering all unoccupied surfaces of the dressing wheel and are no longer made electrically conductive. Thereafter, the positive and non-positive fitting of the edge protection elements, which are formed with a matched to the grinding wheel geometry cross-sectional area, in the formadäquaten depressions in the main body, which are adapted to the geometric shape of the polycrystalline edge protection elements.

If the edge protection elements are inserted and anchored, then the dressing wheel is coated on selected areas with diamond grain 30, as shown schematically in FIG. 8, whereby the sequence of the process can correspond to a galvanic standard program for producing galvanic grinding wheels.

After unmasking, the dressing wheel is profiled and released for final use by the user.

The polycrystalline edge protection elements 7, 8, 9, 15, 16 according to the invention are adapted with their surfaces to the depressions and to the edges to be protected, and preferably in a polyhedral shape, e.g. designed as a prism, truncated pyramids, trapezoidal shapes, cylinders, in particular as a cylinder with an oval, round, rhombic, doppelrhombischer or polygonal cross-sectional area.

In general, the edge protection elements are hard material parts intended to prevent the single layer of e.g. Diamond dressing tool 1 is prematurely worn, has a short life and therefore causes high grinding costs.

In contrast to previously known monocrystalline edge protection elements for dressing wheels, the edge protection elements according to the invention are made of polycrystalline material, e.g. polycrystalline diamond (PCD) or gas phase deposition (CVD) diamond.

The wear is due to the application at the peripheral edge 3 and in the dressing surfaces 4, 5, 12 (Figure 1) greatest, which is why the edge protection elements 7 are also applied there primarily, but they can also be installed in other places as protection, as in Embodiment shown in FIG. 4 and FIG. 5.

Edge protection elements were previously elongated, in their geometric form varying or undefined elements, often diamond-shaped diamonds.

In contrast, the polycrystalline edge protection elements according to the invention are used with a geometrically defined shape in the plurality of wells, wherein the polycrystalline edge protection elements each having a defined orientation of their grain growth planes.

The geometry of the edge protection elements is - as shown by the embodiment of FIG. 7 and FIG. 8 - adapted to the growth areas of the polycrystalline edge protection elements by the grain growth planes 25 are preferably oriented perpendicular to the longitudinal axis of the edge protection elements 7. For this choice of orientation of the grain growth planes, the best results could be demonstrated, but other orientations could be made.

In the dressing tool, the polycrystalline edge protection elements 7 are aligned such that the grain growth planes enclose an angle α in the range of 5 ° to 85 ° relative to the grinding force vector F acting during operation, α α = 45 ° being a preferred angle in the exemplary embodiment according to FIG.

In addition, the polycrystalline edge protectors may be surface treated with the polycrystalline edge protectors e.g. coated with coatings of nitrides and carbides of the elements Ti, Cr, Ni, Si, Al, V, W, Ga and In or combinations thereof.

Furthermore, the polycrystalline edge protection elements are fixed by metallic embedding with Ni, Ni alloys, Cu or Cr or by soldering or gluing.

The arrangement of the edge protection elements on the dressing wheel 1, especially their position have a significant impact on their effectiveness. FIG. 6 shows four different dressing tools or rotationally symmetric dressing disks 10, FIG. 10 ', 10 ", 10'", wherein the edge protection elements 7 have a different orientation from the radial orientation.

In the dressing wheel 10 ", the edge protection elements 7 are arranged in pairs at an angle α equal to 45 ° relative to the acting grinding force vector, that they are each suitable for use in the one and in the other direction of rotation.

By the correct choice of number, angle of inclination, depth of the recess and base of the edge protection elements and the combination of these features is achieved that the wear of the edge protection elements on the one hand and the entire dressing tool assignment, for. on the other hand, with diamond grain is extensively reduced and it comes mainly to a protection of the extremely loaded edge region.

The number of edge protection elements used depends, e.g. From the disk diameter, preferably, they can be used at a mutual distance of 1 mm to 15 mm, preferably 3 mm to 5 mm along the circumference. The usual base area of the edge protection elements may be a value of 2 mm 2 and, depending on the application, a value in the millimeter range for their length. All these values can be adapted by the specialist according to the needs.

Claims

A dressing tool for surface treatment of abrasive tools having a base body having one or more dressing surfaces at least partially coated with high-hardness cutting materials, e.g. Diamond single crystal grains are occupied and have a plurality of wells, in which edge protection elements are used and fixed, characterized in that in the plurality of wells polycrystalline edge protection elements (7, 8, 9, 14, 15) are used with a geometrically defined shape, and that the polycrystalline edge protection elements (7, 8, 9, 14, 15) are embedded in the base body in a form-fitting and non-positive manner, wherein the depressions are adapted to the geometric shape of the polycrystalline edge protection elements (7, 8, 9, 14, 15).

2. dressing tool for surface treatment of abrasive tools with a base body having one or more dressing surfaces, at least partially with high-hardness cutting materials, e.g. Diamond single crystal grains are occupied and have a plurality of wells, in which edge protection elements are used and fixed, characterized in that in the plurality of wells polycrystalline edge protection elements (7, 8, 9, 14, 15) are used with a geometrically defined shape, and that the polycrystalline edge protection elements (7, 8, 9, 14, 15) each have a defined orientation of their grain growth planes.

3. Dressing tool according to claim 1 or 2, characterized in that the polycrystalline edge protection elements (7, 8, 9, 14, 15) in the form of prisms, truncated pyramids, trapezoidal shapes, cylinders od. Like. Are formed.

4. dressing tool according to claim 3, characterized in that the cylindrical edge protection elements (7, 8, 9, 14, 15) in the form of a cylinder with an oval, round, rhombic, doppelrhombischer or polygonal cross-sectional area is formed.

5. dressing tool according to claim 1 or 2, characterized in that the polycrystalline edge protection elements (7, 8, 9, 14, 15) are formed with a matched to the grinding wheel geometry cross-sectional area.

6. Dressing tool according to one of the preceding claims, characterized in that the polycrystalline edge protection elements (7, 8, 9, 14, 15) of polycrystalline diamond (PCD) or of gas-phase deposition diamond (CVD) are formed.

7. Dressing tool according to one of the preceding claims, characterized in that the polycrystalline edge protection elements are elongated.

8. dressing tool according to claim 7, characterized in that in the polycrystalline edge protection elements (7, 8, 9, 14, 15), the grain growth planes are oriented perpendicular to the longitudinal axis.

A dressing tool as claimed in claim 8, characterized in that the polycrystalline edge protection elements (7, 8, 9, 14, 15) are oriented so that the grain growth planes (25) are at an angle in the range of 1 to 2 relative to the operating force of the abrasive force vector (F) 5 ° to 85 °, preferably an angle α equal to 45 °.

10. Dressing tool according to one of the preceding claims, characterized in that the polycrystalline edge protection elements (7, 8, 9, 14, 15) are surface-treated.

11. Dressing tool according to claim 10, characterized in that the polycrystalline edge protection elements with coatings of nitrides and carbides of the elements Ti ₁ Cr, Ni, Si ₁ Al, V, W, Ga and In or combinations thereof.

12. Dressing tool according to one of the preceding claims, characterized in that the polycrystalline edge protection elements are fixed by metallic embedding with Ni, Ni alloys, Cu or Cr.

13. Dressing tool according to one of claims 1 to 11, characterized in that the polycrystalline edge protection elements by soldering or

Gluing are fixed.

14. Dressing tool according to one of the preceding claims, characterized in that it is rotationally symmetrical.