DE3702937A1 - Method for polishing and polishing device - Google Patents

Abstract

A method for polishing bases of sharp-edged mould chambers in dies, in particular injection-moulding dies of steel, according to which a polishing medium is reciprocated on a path. The technical problem is to provide a polishing method which permits clean and uniform working even of sharp corners and edges in mould recesses. The path is generated by superimposing a reciprocating linear movement and a reciprocating transverse movement. The transverse movement is flexibly guided. This results in an elliptical path which is deformed in the direction of the longitudinal axis at the ends into points. A higher-frequency oscillating movement is superimposed perpendicularly to the linear movement. <IMAGE>

Description

The invention relates to a method for polishing base areas chen of sharp-edged mold chambers in tools, in particular Injection molds made of steel, after which a polishing carrier on a Web is moved back and forth.

Polishing processes with reciprocating motion are already in place known. When using this method to polish sharply angular mold cavities in tools, especially injection molding tools gen, it can happen that the polishing carrier in a corner of the form recess remains and in this area there are surface traces works. Otherwise it can be when bumping against the edges of the mold scratches or other polishing marks.

The object of the invention is to provide a polishing process rens that a clean and even processing even sharper Corners and edges of shape recesses allowed.

This object is achieved according to the invention in that the Path by superimposing a reciprocating rectilinear movement supply and a reciprocating transverse movement is generated that the transverse movement is flexible and that perpendicular to the ge linear motion over a swinging motion with higher frequency device.

The invention differs from the prior art in that than the reciprocating transverse movement has a compliance. The This results in an elliptical orbit, the longitudinal axis of which is in the direction of the and aligned movement is aligned. The transverse movement has against a smaller amplitude over the reciprocating motion. There through the polishing carrier can knock off when it hits an edge or corner give way. Under the influence of the friction, the elliptical orbit at the En  that of the long axis compressed, so that there tips form. The superimposed vibration moves the polishing pad into the Corners or edges of the shape recess to be machined especially gentle and ensures, so to speak, a floating movement of the polishing carrier. The superimposed vibration creates a cross line of the Polishing carrier and thus ensures an optimal honing surface. A total of it is impossible that the polishing carrier will stick. It is one uniform machining of shape recesses with sharp corners and Edges possible.

So that the resilience of the polishing pad and tip shape the path are adjustable, it is provided that the amplitudes of the ge linear movement and the transverse movement ver independently are adjustable.

A polisher to perform the procedure is to follow Features marked:

• a) a coupling element carrying the receptacle is lower about an axis pivotable to the longitudinal axis of the rod;
• b) the pivotable part of the coupling element is via a guide rod coupled to the crank back and forth;
• c) the guide rod has a flexibility in the pivoting direction;
• d) the recording contains another drive for the driver, by which he swings back and forth within his plane of movement is cash.

The straight line movement can be in the range of a few millimeters be made, as well as the transverse movement. If the lateral movement was the same The size of the linear movement creates a circle. If the transverse movement is smaller than the linear movement, you get an ellipse, the long axis of which is in the direction of rectilinear movement is aligned. However, this ellipse becomes yielding as a result speed of the transverse movement deformed under the influence of the friction, so that the ends of the long axis taper into tips. You can do that too Process sharp corners in the area of the base of a recess without leaving any marks on the polishing pad. Because an excessive The load on the polishing carrier is due to the flexibility of the cross avoided movement. In addition, the superimposed vibration causes one Cross stroke and thus a floating movement of the polishing pad. By adjusting the speed and the size of the transverse movement all shape contours are recorded and optimally processed. Due to the white smooth and smooth transition of the shape curves becomes a floating Ge  feel conveyed when polishing. A hooking and beating the bottom lier carrier in a corner is not in this swimming movement conceivable.

For precise and impact-free guidance of the driver is provided hen that the rod is guided in a straight line and through a connecting rod is coupled to the crank.

For superimposing a transverse movement and creating an elip table movement is provided that the guide rod in one Attachment of the crank is slidable and a game in the transverse direction Has.

A swinging movement independent of the elliptical movement is generated by the fact that the recording is an eccentric arrangement driven an eccentric role, which in a profile curve engages a swivel head.

A precise alignment of the swinging movement in the plane of the el Liptic movement is ensured by the swivel head is pivotable about a pin within the receptacle, the Pin is aligned parallel to the axis of the bearing.

This ensures that the polishing carrier is carried without jamming aims that the driver has a cone tip, which is in a cone shaped receiving a polishing carrier engages.

The movements of the driver can thus be adjusted and adapt to the application conditions that the eccentric arrangements are adjustable.

An additional adjustment is ensured that the Pe Periods of the eccentric arrangements can be set independently of one another are.

The polishing device can be designed as a hand-held device or as part form a machine.

An embodiment of the invention is hereinafter referred to Taking explained on the drawings, in which represents

Fig. 1, a polishing apparatus in the view, partly in section,

Fig. 2 shows a section along the line II-II in Fig. 1,

Fig. 3 is a partially broken bottom view of Fig. 1 and

Fig. 4 is a schematic representation of the movement pattern of the driver in a greatly enlarged scale.

The polishing device is designed as a motor-driven hand-held device and can be accommodated in a schematically indicated housing 1 . The polishing device comprises a first drive element 2 and a second drive element 3 . The drive element 2 contains a drive motor, not shown, which drives a drive disc 5 via a gear 4 , in which an eccentric ring bolt 7 sits within an eccentric ring 6 , the approach of which is effective as a crank 8 . The eccentricity of the eccentric bolt 7 and thus the crank 8 can be adjusted in a known manner by turning the eccentric 6 in the range of a few millimeters. An eccentricity or amplitude of less than 1 mm is usually sufficient. The eccentric 6 can be determined by means of a screw 9 .

A straight guide 10 is seated on the drive element 2 , in which a rod 11 with a holder 12 can be displaced. The rod 11 is coupled to the crank 8 via a connecting rod 13 . This arrangement he produces in a known manner a reciprocating movement of the rod 11 , which is indicated schematically in Fig. 4 by the double arrow 14 . The reciprocating motion has an amplitude of about 2 mm. Other values are also possible.

A part 29, which can be pivoted about an axis perpendicular to the axis of the rod 11 , sits on the holder 12 with the interposition of a bearing 16 . These parts form a coupling element 15 . On the pivotable part 29 , a guide rod 17 is seated, which engages in an attachment 18 of the cure 8 with play and is thus pivoted back and forth during the rotary movement of the crank in the plane of the drawing in FIG. 3. The game ensures compliance of this transverse movement.

The coupling element 15 receives in the pivotable part 29 a receptacle 30 of the further drive element 3 , at the end of which a driver 19 is seated. The receptacle 30 can be displaced within the part 29 by a larger amount, which is not shown. The drive element 3 contains a drive motor, not shown, which drives a roller 21 via an eccentric arrangement 20 of the type already described. The roller 21 engages in a profile curve 22 which is formed at the end of a swivel head 23 . The pivoting head 23 is within the receptacle 30 about a pin 24 pivotable bar and holds the driver 19 already mentioned. When the drive motor (not shown) rotates within the drive element 3 , the roller 21 is moved on the crank pin of the eccentric arrangement 20 on a circular path, so that with the help of the profile curve 22 the swivel head 23 swings back and forth with the driver 19 around the pin 24 .

The driver 19 has a cone tip 25 and engages in a ke gel-shaped recess of a polishing carrier 26 .

The movement of the driver 19 is based on the reciprocating, linear movement of the rod 11 in the direction of the double arrow 14 , the pivoting movement due to the pivoting by the guide rod 17 and the reciprocating movement in the direction of the double arrow 28 due the eccentric assembly 20 together. The reciprocating, rectilinear movement in the direction of the double arrow 14 and the pivoting movement using the guide rod ge 17 result in essentially elliptical arches 27 of the driver. The amplitude of the transverse movement is at most equal to the amplitude of the reciprocating movement, which corresponds to a circular path. However, the amplitude of the transverse movement is normally smaller. This allows the eccentricity of the ellipse to be determined. The large axis of the ellipse is determined by the size of the reciprocating movement. The transverse movement depends on the ratio of the distance between the axes of the eccentric pin 7 and the coupling element 15 and the distance between the axes of the coupling element 15 and the driver 19 .

Due to the friction, the ellipse arches are deformed at the ends of the long axis into tips 31 , so that there is a clear deviation from the ellipse shape. These reversal tips are particularly important for an optimal polishing result. The elliptical-like path are then back and forth vibrations in the direction of the double arrow 28 superimposed, which are generated by the eccentric arrangement 20 and cause a cross line. Since the drive element 2 and the drive element 3 contain independent drive motors, the period of the movements can be set arbitrarily with regard to the period of the elliptical movement. The floating movement of the polishing pad ensures an optimal honing surface. All operational conditions can be recorded with this.

Of course, the drive of the two drive elements 2 and 3 can also be coupled via a continuously variable transmission.

The oscillating movement can also be generated by ultrasound.

Claims (10)

1. A method for polishing the base of sharp-edged mold chambers in tools, in particular injection molds made of steel, after which a polishing carrier is moved back and forth on a web, characterized in that the web is superimposed by a reciprocating rectilinear movement and a back and forth Herge-going transverse movement is generated that the transverse movement is guided resiliently and that perpendicular to the rectilinear movement, an oscillating movement with a higher frequency is superimposed. 2. The method according to claim 1, characterized in that the Amplitudes of rectilinear movement and transverse movement are independent are adjustable from each other. 3. Polishing device for carrying out the method according to claim 1 or 2, with a rod-shaped movable within a plane with the participant, the seat of which sits on a rod which can be moved back and forth by a crank, characterized by the following features:

• a) a coupling element ( 15 ) carrying the receptacle ( 30 ) can be pivoted about an axis perpendicular to the longitudinal axis of the rod ( 11 );
• b) the pivotable part ( 29 ) of the coupling element ( 15 ) is coupled to the crank ( 8 ) back and forth by a guide rod ( 17 );
• c) the guide rod ( 17 ) has a flexibility in the pivoting direction;
• d) the receptacle ( 30 ) contains a further drive for the participant ( 19 ) through which the same can be oscillated within its plane of movement.

4. Polisher according to claim 3, characterized in that the rod ( 11 ) is guided within a straight guide ( 10 ) and is coupled to the crank ( 8 ) by a connecting rod ( 13 ). 5. Polisher according to claim 3 or 4, characterized in that the guide rod ( 17 ) in an attachment ( 18 ) of the crank ( 8 ) can be pushed ver and has a game in the transverse direction. 6. Polisher according to one of claims 3 to 5, characterized in that the receptacle ( 30 ) has an eccentric arrangement ( 20 ) for driving an eccentric roller ( 21 ) which in a Profilkur ve ( 22 ) of a swivel head ( 23 ) intervenes. 7. Polisher according to claim 6, characterized in that the swivel head ( 23 ) about a pin ( 24 ) within the receptacle ( 30 ) is pivotable ver, the pin ( 24 ) being aligned parallel to the axis of the bearing ( 16 ). 8. Polisher according to one of claims 3 to 7, characterized in that the driver ( 19 ) has a conical tip ( 25 ) which engages in a conical receptacle of a polishing carrier ( 26 ). 9. Polisher according to one of claims 3 to 8, characterized records that the eccentric arrangements are adjustable. 10. Polisher according to one of claims 3 to 8, characterized indicates that the periods of the eccentric arrangements are independent of one another are adjustable.