EP0237790A1 - Honing device - Google Patents

Abstract

A honing device has a honing tool (3) for fine machining blind holes in a workpiece (1). The honing tool (3) has a shaft (35), at the free end of which honing stones (39) are arranged. They can be moved radially outwards with a spreader bar (37). A coolant channel arrangement (34) is provided in the honing tool (3), via which coolant is supplied to the end (36) of the honing tool (3) facing the workpiece during the machining of the workpiece (1). To return the coolant, return channels (42, 43) are provided which run on the outer circumference of the honing tool (3). The honing device also has a coolant supply device (5) which can be aligned and fixed with respect to the honing tool (3). The supply and return of the coolant ensures a precisely defined coolant flow within the work area.

Description

The invention relates to a honing device according to the preamble of claim 1.

In such honing devices (DE-GM 83 25 106) it is already known to supply the coolant in a targeted manner in the working area of the honing tool. It has an axially extending coolant channel that opens directly into the work area via radial bores. The coolant is supplied via a coolant distributor arranged above a clamping point of the tool body. It is guided on a connecting tool connected to the honing tool and held axially immovable. The connecting tool has a further clamping end opposite the clamping end of the honing tool, which can be clamped in a drill chuck or the like of a machine tool.

This known honing device has the disadvantage that it has a relatively large overall length between the clamping end of the tool spindle and the working area. As a result, the shaft of the honing tool tends to skew and vibrate during machining with its working area in the bore of the usually gimbaled workpiece. which affects the machining accuracy and the service life of the honing tool. Furthermore, the flushing of the working area at the bottom of the blind hole is unsatisfactory, since this can result in fluidic dead zones. However, for high-precision machining, it is essential that the abrasion is immediately washed away from the machining zone.

The invention has for its object to avoid these disadvantages and to create a honing device for precision machining, with which relatively small bores, in particular blind holes, can be machined with an exceptionally high accuracy not previously achieved by honing with a long service life of the tool.

This object is achieved according to the invention in a honing device of the generic type with the characterizing features of claim 1.

The coolant supply device according to the invention can be arranged directly above the workpiece on a device plate. The coolant supply device can be penetrated centrally by the honing tool and can accommodate guide and sealing elements that can align freely with the honing tool shaft. The guide and sealing elements are then held in the aligned position by the coolant pressure during honing. This results in an exceptionally stiff and vibration-free guidance of the honing tool. The supply of the coolant under high pressure in the interior of the honing tool to the end of the honing tool facing the workpiece bore, and the return of the coolant via the return duct ensures a precisely defined cooling middle management within the work area. As a result, the machining accuracy with the honing device according to the invention is considerably improved, so that the device is particularly suitable for producing blind holes which have to be machined with high precision, such as for example for machining holes in injection pump parts.

Further features of the invention result from the further claims, the description and the drawings.

• Fig. 1 eine erfindungsgemäße Honeinrichtung im Axial­schnitt,
• Fig. 2 ein Honwerkzeug der Honeinrichtung nach Fig. 1 im Axialschnitt längs der Linie II-II in Fig. 3,
• Fig. 3 einen Schnitt längs der Linie III-III in Fig. 2.

The invention is described below with reference to an embodiment shown schematically in the drawings and on an enlarged scale. It shows:

• 1 is a honing device according to the invention in axial section,
• 2 shows a honing tool of the honing device according to FIG. 1 in axial section along the line II-II in FIG. 3,
• 3 shows a section along the line III-III in FIG. 2nd

In Fig. 1, a workpiece 1 is shown with a blind hole 2, which is processed by a honing tool 3 of a honing device. For this purpose, the workpiece 1 is received and held (which is not shown in more detail) in a known cardanic workpiece holder 4.

Immediately above the workpiece holder 4 or the work area, a coolant supply device 5 is arranged on a device plate 6 fixed on the machine side in such a way that a shaft of the honing tool 3 penetrates it centrally.

A clamping end 8 of the honing tool 3, which is opposite the workpiece holder 4 of the honing tool 3 and is arranged on the other side of the coolant supply 5, can be connected by known means, e.g. a (not shown) collet, firmly connected to a machine spindle 9.

A housing part 10 of the coolant supply device 5, which is designed essentially as a hollow cylinder, is guided axially displaceably in a guide bushing 11. It is coaxially connected to the honing tool 3 with the device plate 6, for example by means of a fitting flange 12. The housing part 10 coaxially receives in a cylinder bore 13 a guide part 14 with an outer diameter and an annular sealing part 15 adjoining the guide part in the axial direction. The guide part 14 has a flange-like widened central section 16, the outer diameter of which is slightly smaller than the diameter of the cylinder bore 13 of the housing part 10. The guide part 14 lies with a lower end face 17 against a bottom 18 of the housing part 10 formed by a step-like shoulder. A section 19 with a reduced diameter adjoins the center section 16 and projects through a bottom-side bore 20 of the housing part 10 to the outside. The bore 20 has a smaller internal width than the adjoining cylinder bore 13. The tapered section 19 of the guide part 14 projects through the bore 20 with greater play. An end section 21 adjoins the central section 16 at the top. Its outer diameter is substantially smaller than the inside width of the cylinder bore 13, but slightly larger than the outer diameter of the end section 19. Between the wall of the cylinder bore 13 and the outside of the end section 21, an annular chamber 22 for receiving coolant is formed.

The annular chamber 22 is bounded in the direction of the machine spindle 9 by the sealing part 15, which rests with a flange-like, widened section 23 without play on the end face 21a of the end section 21. The outside diameter of the section 23 is somewhat smaller than the inside diameter of the cylinder bore 13. It is closed in the direction of the machine spindle 9 with a cover 24 which is attached to a shoulder 10a of an enlarged bore section 25 of the housing part 10 which adjoins the cylinder bore 13 . The conditions are such that the guide part 14 and the sealing part 15 are axially immovable, but are kept floating in the radial direction within the cylinder bore 13. The cover 24 has a through bore 47 which runs coaxially to the cylinder bore 13 and through which an end portion 26 of the sealing part 15 which is tapered in diameter is penetrated with greater play.

The guide part 14 and the sealing part 15 have concentric through bores 27 and 28, respectively, which are penetrated by the tool shank 35 with little play and have a guiding and sealing function, as will be explained below. The bore 27 widens in the region of the end section 21 of the guide part 14 and forms a distributor chamber 29 which surrounds the honing tool shaft in this region and serves for the coolant supply conductive connection. In the exemplary embodiment, three sets of bores 30 are provided, each having the same axial distance from one another. The bores 30 of a set preferably have the same circumferential distance from each other.

The annular chamber 22 is connected via a connection bore 31 and a line 32 to a coolant pressure source (not shown). In the area of the distributor chamber 29, diametrically opposite radial bores 33 are provided on the honing tool shaft 35, which lead to coolant channels 34 in the interior of the honing tool. The bores 33 are preferably arranged at the same circumferential distance from one another in accordance with the bores 30.

As shown in FIGS. 2 and 3 in particular, the tool shaft 35 is provided with an axial through bore 36 in which a spreader rod 37 is guided. In the front area 7 of the tool shank 35, four slot-like slots 38 are preferably provided, each receiving a honing stone 39 with an abrasive coating. The honing stones 39 are dimensioned and shaped such that they can be moved radially in the slots 38 with very little play. For this purpose, the honing stones have an inner wedge surface 40 which runs in the longitudinal direction and which interacts with the conical section 41 of the expansion rod 37. The spreader rod 37 also has grooves 34 that begin slightly above the bores 33 of the tool shank 35 and extend toward the section 41 46 of the tool shank 35 flows. The grooves 34, as shown in FIG. 3, are preferably rounded in the form of a part circle.

On the outer circumference of the tool shaft 35 there are preferably a plurality of axially spaced and axially extending Ab in the area of the honing stones 39 Flattenings 42 are provided. Between the honing stones, axially extending grooves 43 (FIG. 3) are also preferably provided with the same circumferential spacing from one another and are used to discharge the coolant from the working area. The grooves 43 are so long that they extend in the lower stroke end position of the honing tool from the lower end 46 of the honing tool 3 to somewhat above an upper workpiece edge 1a (FIG. 1).

The flats 42 and the grooves 43 form a return channel and are arranged such that guide webs 44 are provided between them, which are formed by outer surface portions of the tool shank 35. The grooves 43 are rounded in the shape of a partial circle in cross section (FIG. 3).

To increase its service life, the honing tool 3 is at least partially made of a particularly wear-resistant material. It is preferably made of solid carbide.

Before the start of honing, the machine spindle 9 is in its upper end length, the honing tool 3 with its honing stones 39 being located completely within the bore 27 of the guide part 14 (not shown). The coolant supply device 5 is also held in its upper end position with its housing part 10 by a known lifting device, not shown, within the guide bushing 11 (see dash-dotted lines in FIG. 1). In this position, the workpiece holder 4 with the workpiece 1 below the coolant supply device 5 is free in the horizontal direction movable, for example by means of a rotary indexing table to enable the feeding and removal of the workpieces 1. As soon as a workpiece is positioned below the honing tool 3, the coolant supply device 5 is lowered so far that the end section 19 of the guide part 14 reaches close to the upper edge of the workpiece 1 a and the honing tool 3 is then with its honing stones 39 from the machine spindle 9 into the blind hole 2 retracted. Here, the gimbaled workpiece 1 is aligned with the honing tool 3 rigidly clamped in the machine spindle 9 (FIG. 1). The honing stone feed and the rotating and lifting movement of the honing tool are then switched on and at the same time coolant is supplied via the line 32. The coolant enters the annular chamber 22 under high pressure, preferably under a pressure of about 20 to 30 bar, and presses the guide part 14 with its flange surface 17 against the bottom 18 of the cylinder bore 13. In addition, the sealing part 15 with its flange 23 presses against the cover 24 pressed. These two parts, which until then could float freely after the honing tool, are held in place and give the honing tool an additional guide. At the same time, the annular chamber 22 is sealed off from the outside. The coolant passes through the bores 30 into the distribution chamber 29 and flows around the tool shank 35, the tight play between the tool shank and the bore 28 of the sealing part 15 and the bore 27 of the guide part 14, in conjunction with the high coolant pressure, a hydrostatic guiding and sealing effect on the moving honing tool 3. At the same time, the coolant reaches the interior of the honing tool 3 via the further radial bores 33 and flows within the bore 36 in the axially extending grooves 34 in the spreader rod 37 to the end 46 of the honing tool 3. There it emerges directly in the area of the bottom of the blind hole 2. The coolant then has to flow out of the blind hole 2 via the flats 42 machined on the outer circumference of the honing tool 3 and the grooves 34. The entire working area of the blind bore 2 is flushed through perfectly and a good cooling and a reliable removal of the abrasion particles is guaranteed. In addition, the high coolant pressure in connection with the special storage and arrangement of the coolant supply device leads to a vibration-damping stiffening of the honing tool and workpiece system, which contributes to exceptional machining accuracy and a considerable increase in tool life.

When the honing tool 3 moves out of the blind hole 2 after the honing process has ended, the honing stones 39 are immediately taken up again by the bore 27 of the guide part 14 and held captively. For this purpose, the mouth of the bore 27 facing the workpiece 1 has a funnel-shaped extension 45, which facilitates the insertion of the honing stones 39.

Claims (20)

1. Honing device with a honing tool for the fine machining of small bores, in particular blind holes in workpieces, in which the honing tool has a shaft that has at least one working area provided with an abrasive coating, which can be expanded with a spreading device arranged in the honing tool, and with one running in the honing tool Coolant channel arrangement for supplying a coolant to the work area,
characterized in that the coolant channel arrangement (34) opens approximately at the end at the end (46) of the honing tool (3) facing the workpiece (1), that at least one return channel (42, 43) is provided for returning the coolant, which is on the outer circumference of the Honing tool (3), and that a coolant supply device (5) which can be aligned and locked relative to the honing tool is provided. 2. Device according to claim 1, characterized in that the coolant channel arrangement (34) consists of several, preferably four, with the same circumferential spacing from one another circumferential grooves of the expansion device (37). 3. Device according to claim 1 or 2,
characterized in that the coolant is supplied under high pressure, preferably under a pressure between 20 and 30 bar. 4. Device according to one of claims 1 to 3,
characterized in that the coolant channel arrangement (34) extends from a lower end section (41) of the expansion device (37) to approximately radial bores (33) of the tool shank (35). 5. Device according to one of claims 1 to 4,
characterized in that the return duct (42, 43) is formed by flats (42) and grooves (43) on the outside of the tool shank (35). 6. Device according to one of claims 1 to 5,
characterized in that the return channel (42, 43) in the lowest stroke position of the honing tool (3) in the working position extends from its lower end (46) to beyond the workpiece (1). 7. Device according to claim 5 or 6,
characterized in that the honing tool (3) has guide webs (44) between the flats (42) and the grooves (34). 8. Device according to one of claims 4 to 7,
characterized in that the bores (33) of the tool shank (35) open into the coolant channel arrangement (34). 9. Device according to one of claims 4 to 8,
characterized in that the bores (33) of the tool shank (35) open into a distribution chamber (29) which is between the outer surface of the tool shaft (35) and a through hole (27) of a guide part (14) of the coolant supply device (5). 10. Device according to claim 9,
characterized in that approximately radial bores (30) of the guide part (14) open into the distribution chamber (29). 11. The device according to claim 10,
characterized in that several sets of bores (30) are provided, each consisting of several individual bores arranged at the same circumferential distance from one another. 12. Device according to claim 10 or 11,
characterized in that the bores (30) of the guide part (14) open into an annular chamber (22) on the side facing away from the distributor chamber (29), and the annular chamber (22) between an end section (21) having the bores (30) of the guide part (14) and the cylinder bore (13) of the housing part (10) of the coolant supply device (5) is provided. 13. Device according to claim 11 or 12,
characterized in that the annular chamber (22) is delimited in the axial direction by an upper sealing part (15) and a diameter-widened central section (16) of the guide part (14), and in that the guide part (14) and the sealing part (15) also radial play floating in the cylinder bore (13) of the housing part (10) is arranged. 14. Device according to one of claims 11 to 13,
characterized in that a connecting bore (31) of the housing part (10) opens into the annular chamber (22) and is connected to a coolant supply line (32). 15. Device according to one of claims 1 to 14,
characterized in that the housing part (10) is arranged axially displaceably in a guide bush (11) of the coolant supply device (5). 16. Device according to one of claims 13 to 15,
characterized in that the sealing part (15) and the center section (16) of the guide part (14) abutting against a bottom (18) of the housing part (10) bear sealingly over the entire surface of the housing part (10) during machining of the workpiece (1), and that the sealing part (15) rests on a cover (24) which is fastened in an enlarged bore section (25) of the cylinder bore (13) of the housing part (10). 17. Device according to one of claims 13 to 16,
characterized in that the central section (16) bears against a bottom (18) of the housing part (10). 18. Device according to one of claims 14 to 17,
characterized in that the base (18) and the cover (24) have mutually aligned bores (20, 47) through which the sealing part (15) and the guide part (14) have a tapered end section (26, 19) with radial play protrude. 19. Device according to one of claims 14 to 18,
characterized in that the sealing part (15) and the guide part (14) have concentric bores (28, 27) through which the tool shank (35) protrudes with little play, and in that the bore (27) of the guide part (14) on Free end of the tapered end portion (19) expanded. 20. Device according to one of claims 1 to 19,
characterized in that the honing tool consists of hard metal.

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