DE3618972C2 - - Google Patents

Description

The invention relates to a drive device for photomechanical modification systems, in particular contouring devices with which one moves along two orthogonal axes Lich stored disc in a circular Movement is brought.

In line width converters, contouring devices or the like a disk describes a circular motion, being but remains aligned with two orthogonal axes. The extent of the circular motion determines, for example Line width on the film, for example as a print template  serves. It is known to be a drive for such devices to be provided with steel cable guides. Through the rope tension however, it is very easy for the Disc. The accuracy of the setting is also the known drive is not completely satisfactory (US 42 68 166).

The invention is therefore based on the object Drive device for photomechanical modifications systems, especially for contouring devices and line widths to create transducers that are easy on is built and enables precise adjustment. In front everything should be a large and sensitive adjustment range be realized.

This object is achieved in that an eccentric disk containing a pin on a Drive pulley is rotatably mounted eccentrically, wherein with the eccentric disc in the zero position the axis of the drive pulley coincides that a Adjusting spindle cooperates with an adjusting nut, which has a resilient articulated connection with the Eccentric disc is connected, and that the adjusting spindle is stored in a bearing component, which is via a spring elastic joint connection with the drive pulley ver is bound.  

In the drive device according to the invention Eccentric disc over an eccentric axis of rotation on the Swivel drive disc. The relative position of the Eccentric disc to drive pulley is due to the location the adjusting spindle. Will the drive pulley set in rotation, the pin describes the eccentric a circular motion around the axis of rotation of the Traction sheave, the extent of the circling movement by the relative position of the eccentric disc and Drive pulley is determined. The spigot can have a suitable gear connection to a disc of a line strength converter, a contouring device or the like be coupled.

The relative position of the adjusting spindle in relation to the drive disc and the eccentric disc changes with one Adjustment of the eccentric disc. The resilient Articulated connection enables the adjusting nut or the bearing component of the pivoting movement of the adjusting spindle can follow the adjusting spindle in the thread of the Adjusting nut is not wedged. The spring elasticity of the However, the articulated connection creates a certain tension between the bearing component or adjusting nut on the one hand and the adjusting spindle on the other hand. Inaccuracies and lots With such a solution the adjustment spindle is not required, so that it can be simply threaded.  

A fine thread is not required.

The drive device according to the invention enables one large and sensitive adjustment range. Inaccuracies by tilting or angling. These advantages are achieved with a simple construction.

A particularly simple embodiment of the invention provides before that the adjusting nut with a mounting block is molded in one piece from plastic and both parts over an elastic web are connected to each other. Analogue can according to a further embodiment of the invention Bearing component with a mounting block in one piece Plastic molded and both parts over one elastic web to be connected. A suitable Plastic is, for example, polyamide.

The mounting block connected to the drive pulley is preferably in a recess of the eccentric disc arranged, which enables space-saving placement light is.

It has already been mentioned that a bending stress in the elastic joint connection to tilt the Bearing component or the adjusting nut against the Lead screw leads. This does make a certain  Accepted friction. However, the friction prevents a lot and thus possible inaccuracies. An out design of the invention provides for this an arrangement of Adjusting nut and bearing component and the associated Fixing blocks in such a way that in the adjustment range the adjusting spindle has at least one articulated connection is under bending stress.

The eccentric disc is preferably in turn opposite the drive pulley guided to precise storage to get every point of the eccentric disc.

The invention is described below with reference to drawings explained in more detail.

Fig. 1 shows a partial side view of the drive device according to the invention.

FIG. 2 shows a section through an adjusting spindle of the drive device according to FIG. 1.

FIG. 3 shows a top view of the drive device according to FIG. 1.

Before going to the details shown in the drawings is discussed in more detail, it should be assumed that each of the  described parts for themselves or in connection with Merk paint the claims of essential importance to the invention is.

In Figs. 1 and 3 a drive plate 10 is shown, which is simultaneously formed as a flywheel. In the central bore 11 of the drive pulley, two ball bearings 12, 13 are arranged, which support an axis, not shown, about which the drive pulley 10 is rotated. An eccentric disk 14 is arranged on the drive disk 10 . It is circular only over approximately half of its circumference and has a recess 15 . A pin 16 sits in a bore of the eccentric disk 14 . The pin 16 interacts for example via a ball bearing with an arm 17 which is coupled to a disk of a con turing device in order to set this in a circular motion. Details of the disc and its storage are not given. They are state of the art.

The eccentric disk 14 is mounted eccentrically on the drive disk 10 with the aid of a screw pin 18 with respect to the axis of rotation of the drive disk 10 . In the eccentric disc are diametrically arranged for eccentric mounting 18 two arcuate slots 19, 20 in which guide pins 21, 22 are seated.

In Fig. 3, it is seen that on the side opposite the eccentric bearing side of the pin 16, a mounting block 23 by means of two Schraubstiften disc 24 on the eccentric 14 is mounted. Via a web 25 , the mounting block 23 is connected to an adjusting nut 26 . Adjusting nut 26 and mounting block 23 are molded together with the web 25 in one piece from plastic. In the recess 15 of the eccentric disk 14 , a further fastening block 27 is fastened with the aid of screw pins 28 . It is connected via a web 29 to a bearing component 30 . The last-mentioned parts are also molded in one piece from plastic.

As can be seen from FIG. 2, component 30 extends through the bearing and the adjusting nut 26 has an adjusting spindle 31 . The adjusting spindle 31 sits with its threaded portion 32 in the adjusting nut 26 . The bearing component 30 is mounted on the thread-free section of the adjusting spindle 31 by means of two ball bearings. A radial collar 33 is located between the components 26 and 30 . Between a rotary knob 34 and the other end of the bearing component 30 , which here represents a bearing bush, a spacer bush 35 is arranged. The adjusting spindle 31 is therefore axially secured with respect to the bearing component 30 . When the spindle is rotated via the rotary knob 34 , the adjusting nut 26 is moved along the spindle. In this way, the eccentric disc 14 is moved with respect to the pivot pin 18 . In Fig. 3 the one end position (zero position) is shown in solid lines. The other end position is indicated in dashed lines. It is limited by the stop of the guide pins 21, 22 at the ends of the guide slots 19, 20 .

As can be seen more clearly from FIGS. 2 and 3, the mounting blocks 23, 27 change their position relative to one another when the adjusting spindle 26 is adjusted and thus an adjustment of the eccentric disk 14 . This also changes the relative position of the mounting blocks to the adjusting nut 26 or the bearing component 30 . The webs 25, 29 are bent accordingly. In each relative position there is at least one web 25, 29 under bending stress, where a corresponding tilting of the adjusting nut 26 or of the bearing component 30 relative to the spindle 31 takes place. This creates a certain amount of friction.

In the zero position of the drive device shown, the position of the pin 16 is coaxial with the axis of rotation of the drive disk 10 . The other end position of the pin 16 is indicated by dashed lines in FIG. 3. The circular arc 36 describes the movement of the pin relative to the drive disk 10 when the eccentric disk 14 is adjusted. The maximum circle, which the pin 16 describes during the maximum adjustment, is indicated by the dashed line 37 .

In one example, the total adjustment is a maximum of 15 mm. With one turn of the adjusting knob, a ver position of 0.3 mm received (change in contour size). The reduction is 3: 1, i.e. H. it can be a normal one M 6 threads with a pitch of 1 mm can be used. A complex fine thread is not necessary.

Since the spindle 31 is pivoted when it is adjusted, not only the problem-free adjustability is obtained in a second frame, but also the transmission ratio is maintained.

Claims (6)

1. Drive device for photomechanical modification systems, in particular contouring devices and line width converters, with which a disc movably mounted along two orthogonal axes is brought into a circular motion, characterized in that a pin ( 16 ) containing eccentric disc ( 14 ) on a drive disc ( 10 ) is rotatably mounted eccentrically, wherein in the zero position of the eccentric disc ( 14 ) of the pin ( 16 ) coincides with the axis of the drive disc ( 10 ) that an adjusting spindle ( 31 ) cooperates with an adjusting nut ( 26 ), which via a spring elastic joint ( 25 ) is connected to the eccentric disc ( 14 ) and that the adjusting spindle ( 31 ) is mounted in a bearing component ( 30 ) which is connected to the drive disc ( 10 ) via a spring-elastic joint connection ( 29 ). 2. Drive device according to claim 1, characterized in that the adjusting nut ( 26 ) with a fastening block ( 23 ) is formed in one piece from plastic and both parts are connected to one another via an elastic web ( 25 ). 3. Drive device according to claim 1 or 2, characterized in that the bearing component ( 30 ) with a fastening block ( 27 ) is formed in one piece from plastic and both parts are connected to one another via an elastic web ( 29 ). 4. Drive device according to one of claims 1 to 3, characterized in that the eccentric disc ( 14 ) has a recess ( 15 ) within which the mounting block ( 27 ) for the bearing component ( 30 ) is arranged. 5. Drive device according to one of claims 1 to 4, characterized by an arrangement of adjusting nut ( 26 ) and bearing component ( 30 ) and the associated mounting blocks ( 23, 27 ) such that in the adjustment area of the adjusting spindle ( 31 ) at least one articulated connection ( 25 , 29 ) is under bending stress. 6. Drive device according to one of claims 1 to 5, characterized in that the eccentric disc ( 14 ) has two with respect to the eccentric disc fulcrum dia metric guide slots ( 19, 20 ), in which with the drive disc ( 10 ) connected guide pins ( 21, 22 ) protrude .