CH677889A5 - - Google Patents

Description

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CH 677 889 A5

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description

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

To clamp rotating, machining tools in rotating tool spindles of machine tools, a chuck with a conical insertion shaft is inserted in a known manner into the axial, conical receiving bore of the tool spindle of a machine tool. This chuck is provided with an inner cone into which the collet with an identical outer cone is inserted. The collet is pressed with its outer cone into the identical inner cone of the chuck by means of a clamping nut designed as a screw nut. The collet is fitted with a cylindrical shank of a cutting tool, e.g. a tap, receiving bore and has axially parallel, evenly distributed over the circumference, for example, 6 slots. You divide the collet into 6 segments, for example, which are designed so that the bore that receives the shank of the clamped tool is reduced in diameter by pressing the collet into the outer cone of the chuck by tightening the clamping nut so that it goes into the mounting hole of the collet inserted shaft of a cutting tool, e.g. a tap, positively and non-positively enclosed and thus the required torque is transmitted without slippage.

When machining materials with cutting tools, the cutting edges of the tools and at the interfaces of the material in connection with the often high speeds of the tool cause a strong heating, which has a detrimental to destructive effect on the tool and workpiece and, above all, the service life of the tool cutting edges reduced to a minimum. In order to avoid these thermal loads on the tool and workpiece and to reduce the extreme frictional forces that occur during machining, the cutting edges and the interface are flooded with liquid coolant, as far as this is permissible due to production and material, whereby lubricating properties can be imparted to the coolant by additives reduce the frictional forces. In the known machining processes, the cutting edges of the tool and thus also the interface on the workpiece are acted upon by a coolant jet which is supplied from outside under pressure and which, in particular when machining bores, still has the task of removing the crumbly chips produced during machining.

The supply of the coolant to the tool cutting edges and thus to the interface, especially in the case of horizontal or diagonally arranged bores or holes to be machined from below, in particular in the case of small diameters, results in an inadequate flooding and cooling of the tool cutting edges and inadequate washing out of the cutting edges despite the sufficient supply of the coolant accumulated chips, which often causes the cutting edges to break or the tool to break, eg of the tap, especially with blind or blind holes.

The task is to remedy the disadvantages of the coolant supply and to construct a coolant supply in the collet which is simple in terms of construction and manufacture and which enables the coolant to be supplied to the tool without loss. This object is achieved in a collet according to the preamble with the features of the characterizing part of patent claim 1. Further features of the invention result from the dependent patent claims in connection with the description of the exemplary embodiments and the drawing.

The threaded hole for receiving the pulling bolt coming from the tool spindle and screwing into the rear conical part of the chuck is used as a receiving space for the liquid coolant, which is fed from the chuck outer surface to the receiving space via supply channels. In one embodiment, the axially movable, tubular plunger is mounted within the receiving space of the chuck, which partially protrudes into the chuck accommodated in the chuck and with its end face protruding into the chuck with the interposition of a seal on the end face of the tool shank clamped in the chuck is present. A compression spring is used to seal the end face of the plunger on the opposite end face of the tool shank, which is supported on the one hand on a contact collar of the plunger and on the other hand on the insert in the threaded hole for the pull stud. A stop ring is used to limit the axial movement of the plunger slidingly guided in the chuck and in the collet when the tool received in the collet is removed. The coolant is introduced through a transmission ring, which is connected to the delivery line coming from the coolant reservoir, into the feed channels arranged on the rotating chuck, a pump delivering the required pressure. The tools to be used with the collet in accordance with the invention, such as taps, are provided with the necessary inlet channels to the tool cutting edges, the inflow openings of which are arranged on the end face of the tool shank.

Appropriate refinements and developments as well as further advantages and essential details of the invention can be found in the following description and the drawing, which shows a preferred embodiment as an example in a schematic representation. They represent:

1 is a side view of a chuck according to the invention, partially cut with a plunger as a connecting part,

Fig. 2 the chuck acc. 1, but in another embodiment according to the invention with a connecting part designed as a receptacle,

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3 shows an angular compensation insert for the internal coolant supply in the chuck of FIG. 2 in a sectional, enlarged side view,

4 shows the basic body of the angle compensation insert of FIG. 3 in a sectional side view,

5 shows the base body according to FIG. 4 in plan view,

Fig. 6 shows the connecting part of the angle compensation insert of Fig. 3 in a sectional side view

Fig. 7 shows a connection part similar to Fig. 6, but in a different design for receiving tool shanks of larger diameter.

The chuck 1 received in the inner cone 16 of the rotating tool spindle 15 is held non-positively in the tool spindle 15 by the pull stud 2. In the freely protruding part of the chuck 1 is the tool, e.g. a tap 6, receiving collet 3 is used. By tightening the clamping nut 17 on the chuck 1, both the collet 3 and the tool 6 are non-rotatably clamped in a known manner. To supply the coolant to the cutting edges of the tool and thus also to the interface on the workpiece, the tool is provided with feed lines, the inlet opening 18 of which is arranged on the counter surface 19 of the tool 6. The coolant supplied for cooling the tool cutting edges or interface is released by a stationary transmission ring 20, which rests against the circumference of the rotating chuck 1, in order to flow into the receiving space 25 through the feed channel 21, 22. In the exemplary embodiment according to FIG. 1, an axially movable plunger 4 is arranged in the receiving space 25, which is provided with a through bore 26 through which the coolant flows from the receiving space 25 to the clamped tool.

The plunger 4 is arranged so that it projects with its part 27 facing away from the collet 3 into the receiving space 25 and with the part 28 facing the collet 3 into a receiving bore 29 of the collet 3 so that the plunger 4 bears with its end face 30 the counter surface 18 of the tool 6 clamped in the collet 3 bears sealingly under the pressure of the spring 7. To securely seal the transition between the end face 30 of the plunger 4 and the counter surface 18 on the tool 6, a sealing ring 8 is attached to the end face 30 of the plunger 4. The path of the axially movable plunger 4 is dimensioned such that the tool shank inserted into the collet 3, e.g. of a tap 6, the plunger 4 moves by a few millimeters in the direction of the tool spindle 15, so that a secure seal against escaping coolant is achieved on the surfaces 19, 30 with the sealing ring 8 in between. The contact pressure of the spring 7 is further supported by the pressurized coolant which acts on the annular surface 31. When removing the tool, e.g. a tap 6, from the receiving bore 29 of the collet 3, the plunger 4 is moved by the spring 7 only in the direction of the receiving bore 29 of the collet 3 until the

Tappet 4 rests on insert 5 with circlip 11 attached to it. The insert 5 screwed into the threaded bore 32 is provided with a sealing ring 10, the material of which is selected so that when the insert 5 is screwed into the threaded bore 32, the sealing ring 10 slightly projecting beyond the outer diameter of the insert 5 is pressed into the threads of the threaded bore 32 in a sealing manner . The opening 35 projecting into the tool spindle 15, into which the pull stud 2 is screwed, is sealed by sealing rings 9 against the escape of coolant.

This design of the chuck in conjunction with the collet for an internal coolant supply ensures that, regardless of the position of the tool, there is a safe and sufficient flooding of the tool cutting edges and the interface on the workpiece, as well as a continuous chip wash-off, regardless of the position of the tool.

In the inventive chuck 1 shown in FIG. 2, which can be designed essentially like the chuck shown in FIG. 1, so that the matching parts are also provided with the same reference numerals, the internal coolant supply to the tool is a Twist drill 50 can be provided as a closing part 53, which has a receptacle 67 for the shank of the tool 50 and an outlet bore 63 for the coolant, which opens into the shank receptacle 67. In the exemplary embodiment according to FIGS. 3 to 7, the connection part 53 is provided with an angle 51, which has a base body 52 and is connected to the connection part 53 via a snap ring 54.

The basic body 52 designed as a threaded insert has an external thread 55 and can be screwed into the threaded bore 32 of the receiving space 25 of the chuck 1 with this. The base body 52 also has a coolant passage 56, which runs coaxially to the longitudinal axis 57 of the chuck 1 and opens into a larger-diameter recess 58, which is formed in the end 53 of the base body 52 facing the connecting part 53. The base of the recess 58 is designed as a conical pan 59, which can also be designed spherically. The end region of the coolant passage 56 opening into the recess 58 can be designed as a hexagon socket 60 (FIGS. 4 and 5) into which a hexagon wrench (not shown here) can be inserted in order to screw the base body 52 into the threaded bore 32.

In the peripheral wall delimiting the recess 58, an annular groove 61 can be provided for the snap ring 54. In addition, two diametrically opposite slots 62 can be formed on the end face of the base body 52 facing the connection part 53.

The connecting part 53 has a through-bore 63 for the coolant, which also runs coaxially with the longitudinal axis 57 and which adjoins the passage 56 of the base body 52. The through hole 63 can be in diameter

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be approximately equal to or smaller than the passage 56. At the end of the connection part 53 facing the base body 52, a preferably approximately hemispherical dome 64 can be formed, which is movably mounted in the recess 58 of the base body 52 and rests with its spherical surface 65 on the conical surface of the socket 59. The hemispherical tip 64 can have a collar 66 which is overlapped by the snap ring 54 in the recess 58, so that the connecting part 53 is movably held in the recess 58.

A receptacle 67 for the shaft 68 of the tool 50 is formed in the end of the connecting part 53 opposite the tip 54. The shaft holder 67 is of a conical wall

69 limited, so that the receptacle 67 is designed in the form of a funnel. The wall 69 can preferably be inclined at an angle of approximately 30 ° with respect to the longitudinal axis 57, so that the receiving funnel 67 has an opening angle of approximately 60 °. However, it is also within the scope of the invention to provide a smaller or larger angle than 60 °. The coolant passage bore 63 opens into the receptacle 67 at the lower tapered funnel part. The opposite opening

70 of the receptacle 67, which faces the tool 50, is larger in diameter than the shank 68 of the tool 50, so that the shank 68 can be inserted into the receptacle 67 and its peripheral edge 71 can be placed tightly against the conical wall 69 .

A significant advantage is that, via the connecting part 53 and the compensation angle insert 51, a perfect internal coolant supply both for tools with only one central cooling channel (tool 6 in FIG. 1) and with two or more cooling channels 72 (tool 50 in FIG. 2 ) can be achieved. The coolant supply is independent of the position of the tool and is largely loss-free due to the tight connection of the shaft 68 in the funnel-shaped receptacle 67 of the connecting part, so that intensive cooling of the tool 6, 50 as well as the tool cutting edges and the workpiece to be machined is ensured. Another advantage is that tools with different shank diameters can be used optionally in the conical receptacle 67 of the connecting part 53 of the angle compensation insert 51. In the case of tools with a smaller shaft diameter, the circumferential edge 71 lies tightly in the lower region of the funnel-shaped receptacle 67, while tool shafts with larger diameters in the upper region of the receiving funnel 67 lie tightly against the conical wall 69 with their circumferential edge 71. In order to cover the largest possible range of different shank diameters, i.e. to be able to accommodate both relatively small and relatively large tool shanks, it may be advantageous to design the angle compensation insert 51 in such a way that at least two different connecting parts 53 with differently sized shank receptacles are inserted into the recess 58 of the base body 52 67 can be used optionally. Such different connection parts 53 are shown in FIGS. 6 and 7, for example. For example, tools, such as twist drills, with a shank diameter of up to 7 mm can be inserted into the receptacle 67 of the connecting part 53 of FIG. 6, while the receptacle 67 of the connecting part 53 shown in FIG. 7 for tools, such as twist drills with a shank diameter from about 7 to 13 mm is provided. The tool 50 is pressed into the receptacle 67 of the connection part 53, which is movably mounted in the socket 59 of the base body 52, so that the shaft 68 and the connection part 53 can center exactly when the peripheral edge 71 is placed against the conical wall 69 , whereby a perfect seal is achieved.

Claims (18)

Claims 1. Chuck for receiving a cutting tool, for example a tap, for a rotating tool spindle of a machine tool, characterized by a force-loaded, axially movable against the tool (6) arranged within the chuck (1) and the collet (3). adjustable connecting part (4; 53) which has at least one through hole (26; 63) for a coolant for the tool (6). 2. Chuck according to claim 1, characterized in that the connecting part is a plunger (4) which can be pressed against the tool (6) under the force of a spring (7), wherein between the end face (30) of the plunger (4) and the counter surface (19) on the tool (6) is provided with a seal (8). 3. Chuck according to one of claims 1 or 2, characterized in that the chuck (1) has a receiving space (25) for the coolant, which is preferably arranged centrally in the conical part (36) of the chuck (1) and in the rear part (37) of the chuck (1) is completed by a pull stud (2). 4. Chuck according to one of claims 1 to 3, characterized in that the receiving space (25) on the side opposite the pull stud (2) is closed by an insert (5) with a sealing ring (10). 5. Chuck according to one of claims 1 to 4, characterized in that the plunger (4) in the axial bore (38) of the insert (5) and in the bore (29) of the collet (3) is axially movable. 6. Chuck according to one of claims 1 to 5, characterized by at least one feed channel (21, 22) leading to the receiving space (25). 7. Chuck according to claim 6, characterized in that the feed channel (21, 22) consists of at least two intersecting holes, at least two pairs of feed channels (21, 22) are arranged rotationally symmetrically in the chuck (1). 8. chuck according to one of claims 1 to 7, characterized in that the the receiving 5 10th 15 20th 25th 30th 35 40 45 50 55 60 65 4th 7 CH 677 889 A5 space (25) facing radial annular surface (31) of the plunger (4) is designed as an application surface for the coolant. 9. Chuck according to one of claims 1 to 8, characterized in that the axial movement caused by the force of the spring (7) and under the action of the flowing coolant is limited by a locking ring (11). 10. A chuck according to claim 1, characterized in that the connecting part (53) is designed as a receptacle (67) for the shaft (68) of the tool (50) and has a through bore (63) for a coolant (63) which in the shaft holder (67) opens out. 11. Chuck according to claim 10, characterized in that the receptacle (67) of the connecting part (53) with a conical wall (69) is funnel-shaped. 12. Chuck according to one of claims 10 or 11, characterized in that the opening (70) of the receptacle (67) facing the tool (50) is larger in diameter than the opening of the through bore (63) and the tool shank (68), which can be placed tightly against the conical wall (69) of the receptacle (67) with a peripheral edge (71). 13. Chuck according to one of claims 10 to 12, characterized in that the connecting part (53) is mounted on a base body (52) which has a passage (56) for the coolant and in the receiving space (25) of the chuck (1) is definable. 14. Chuck according to claim 13, characterized in that the base body (52) of the connecting part (53) has an external thread (55) and can be screwed into the thread (32) of the receiving space (25) with this. 15. Chuck according to one of claims 10 to 14, characterized in that the connecting part (53) with the through bore (63) and the base body (52) with the passage (56) and the receiving space (25) coaxially in the chuck (1) are provided. 16. Chuck according to one of claims 10 to 12, characterized in that the connecting part (53) is mounted in a recess (58) of the base body (52) and is held by a snap ring (54) or the like. 17. Chuck according to one of claims 13 to 16, characterized in that the connecting part (53) has a spherical cap (64) which is mounted in the recess (58) in a conical or spherical socket (59) of the base body (52) and is movable relative to the base body (52) is. 18. Chuck according to one of claims 15 to 17, characterized in that in the recess (58) of the base body (52) connecting parts (53) with different sized shank holders (67) and / or coolant passages (56) can be used optionally. 5 10th 15 20th 25th 30th 35 40 45 50 55 60 65 5