DE19826502A1 - Printer with controlled tractor drive and friction rollers - Google Patents

Abstract

The printer is designed to handle either single sheets of paper or continuous paper of a form having perforations along both edges. The feed system includes a switching device (10) and includes controlled tractor drive wheels that engage the holes and are located on a polygonal shaft. This is driven by a motor via a gear train and a cam disc. For single sheet feed the motor drives rollers on a shaft.

Description

The invention relates to a printer with at least one controllable or switchable Tractor pair and at least one friction roller pair according to the other features len of the preamble in claim 1.

Such a printer, with a controllable or switchable tractor pair, the front direction of thrust for single sheets or endless webs is reversible and two tractor pairs can be driven via a gear train and a polygonal shaft can be controlled by switching movements via an axially acting control cam can be triggered is known from DE 42 05 777 C2.

The known printer has a limited number of switching functions of the tractor pair, but the system is ready for a functional extension rode. On the other hand, a selection of functions and a corresponding gearbox be and can also be used with other drive designs of printers Such a transmission should also be very compact and small in size.

The invention is based, for the known design, the number of the task Increase functions, d. H. to create a manual transmission in different Printers can be used and takes up little space.  

The task is inventively characterized by the features of the nenden part in claim 1 solved. This makes one in the smallest of spaces Coupling or decoupling one or more polygonal waves from tractor pairs or of drive shafts for friction rollers possible. The multitude of achievable Shifting functions are increased and the manual transmission is for different ones Printer applicable.

A specific embodiment of the invention is created so that the Manual transmission each from a first, located in the drive train of the drive motor Chen drive wheel and drivers arranged for a coaxial, second mirror image netes drive wheel from a by means of a toothing in the first drive wheel sliding guide sleeve with axial guide ribs on an internally toothed Sliding sleeve with front locking teeth and consists of a coaxial on the Guide sleeve slidable rotary sleeve is formed, which the sliding sleeve turns with counter-locking teeth corresponding to the sliding sleeve and that an axial annular surface of the first drive wheel against one with a control cam wheel provided axially abuts. The compactness of the gearbox arises in particular from the mirror images of the first and second drive wheels and through the sliding members of the guide sleeve se, the sliding sleeve and the rotating sleeve.

Actuating forces are also generated in that a one on the guide sleeve supported against the rotating sleeve and on the other hand against a stop ring Compression spring is arranged.

A backlash-free function is also established in that the ratchet or ver first drive wheel and the second drive wheel against each other by means of tension springs are tense.

Another actuating movement takes place in that the sliding sleeve by Dre hung the ratchet wheel can be pushed against the rotating sleeve via the first drive wheel.  

It is provided that the rotary sleeve on the axial guide ribs of the guide tion sleeve is slidable. This creates another detachable connection achieved.

A rotation around a predetermined circumferential path can thereby be achieved that the rotary sleeve by means of a compression spring, the bevels of the front Locking teeth of the sliding sleeve and the bevels of the counter-locking teeth of the rotating sleeve is rotatable into the next position.

According to other features, it is provided that when rotating the Schalttrades the rotating sleeve in a following position of the axial guide ribs on the Guide sleeve is clickable.

The system of the individual functions is determined by a starting point in in the basic position of the ratchet wheel the position "zero" is determined, in which the first drive wheel is in engagement with the teeth of the guide sleeve and the Rotating sleeve with its counter-locking teeth in the locking teeth of the sliding sleeve on one Snap point is.

This makes a positioning movement advantageous for the further functional sequence achieved that in an intermediate position the ratchet wheel to a predetermined Ni veau of the control cam is rotated, the first drive wheel, the second to drive wheel, the sliding sleeve and the rotating sleeve can be pushed into an intermediate position are in which the first drive wheel and the rotating sleeve is not in the guide sleeve are locked.

Another position for another function is that for driving a second pair of tractors in addition to the intermediate position, the rotating sleeve in the Sliding sleeve is clickable.  

The following function of the gearbox provides that for a position of an on the sheet by means of pairs of friction rollers, the ratchet wheel counterclockwise is rotated, the first drive wheel, the second drive wheel, the sliding sleeve and the rotating sleeve is pushed back by means of the compression spring until the rotating sleeve is in the guide sleeve is engaged.

Another function results from the fact that in an additional intermediate position the switching wheel to the predetermined level of the cam curve of the first intermediate is rotated and that the first drive wheel, the second drive wheel, the sliding sleeve and the rotating sleeve can be pushed into the additional intermediate position are. This makes it easier to thread the rotating sleeve into the sliding sleeve.

Another function can be achieved in that for a basic position of the the first pair of tractors the ratchet wheel with its control curve to the level "zero" is set that the first drive wheel engages in the guide sleeve and that the rotating sleeve in the position of the first drive wheel in a locking point in the Guide sleeve snaps into place.

Exemplary embodiments of the invention are shown and are shown in the drawing described below.

Show it:

Fig. 1A is a plan view of a printer with two tractor pairs and a plurality of Friktionsrollenpaaren,

FIG. 1B the printer of FIG. 1 kerrahmen in a side view on the Pressure,

Fig. 2 shows the transmission as a module in perspective view;

Fig. 3 is an exploded view of a plurality of functional components of the gearbox,

Fig. 4 shows the components of FIG. 3 in the assembled state,

Fig. 5 is a view of the gearbox in the basic position,

Fig. 6 is a view of the gearbox in position 1 / intermediate position

Fig. 7 is a view of the gearbox in position 2 / second tractor

Fig. 8 is a view of the gearbox in position 3 / sheet feeder

Fig. 9 is a view of the gearbox in position 4 / intermediate position

Fig. 10 is a view of the gearbox in position 5 / second tractor and

Fig. 11 is a view of the gearbox in position 6 / basic position for the first tractor.

The printer has a printer frame 1 . An electric drive motor 2 is mounted on the right side ( FIG. 1A). A pinion on the motor shaft engages in a drive train 3 which leads to a manual transmission 10 . A drive train 4 also leads from the manual transmission 10 to a first pair of tractors 5 and from there to a second pair of tractors 6 . A polygonal shaft 7 of a pair of tractors 5 or 6 is driven in each case ( FIG. 1B).

From the drive train 3 , the drive for the manual transmission 10 is derived by means of a pinion 9 .

The manual transmission 10 is actuated by means of a ratchet wheel 8 and a control cam 8 a. The manual transmission 10 generates a variety of functions for setting a basic position ( FIG. 5), a first intermediate position ( FIG. 6), in which a preparation position is brought about for engagement, a drive position for the second pair of tractors 6 ( FIG. 7) for a single sheet feeder 25 ( Fig. 8), for a second intermediate position for threading a rotating sleeve 18 into a sliding sleeve 17 ( Fig. 9), a drive position for the second pair of tractors 6 ( Fig. 10) and a basic setting for driving the first Tractor pair 5 ( Fig. 11). For the individual functions, translatory, rotary and / or rotationally lockable switching movements are triggered.

The essential components of the manual transmission 10 ( Fig. 2) are the selector wheel 8 with the control cam 8 a, the drive pinion 9 , a first drive wheel 14 with a driver 14 a arranged on the circumference and a pair of drivers 14 b on the circumference, and a second drive wheel 15 , which is formed for the first mirror image, so that a relatively small axial displacement movement between the two drive wheels 14 and 15 can take place. The ratchet wheel 8 rests with its control cam 8 a on an axial annular surface 14 c constantly.

According to FIG. 3, the second drive wheel 15 is not shown in order to illustrate the essential parts of the unit pulled apart, the following being arranged in the order: the drive wheel 14 with the lower driver 14 a and the upper driver pair 14 b, a central toothing 16 a, a guide sleeve 16 with a suitable toothing 16 a and axial guide ribs 16 b, a sliding sleeve 17 with front locking teeth 17 a and bevels 17 b, a rotating sleeve 18 with counter-locking teeth 18 a and bevels 18 b.

In Fig. 4 the disassembled in Fig. 3 assembly is provided so that on the guide sleeve 16 with the toothing 16 a, the sliding sleeve 17 is pushed onto the axial guide ribs 16 b and the rotating sleeve 18 closes, whereby on the rear shaft of the guide sleeve 16 together with egg nem inserted shaft end 16 c, which has a polygon cross section, a compression spring 20 is supported against a stop ring 20 a. The compression spring 20 fe changes the rotary sleeve 18 . The sliding sleeve 17 can be pushed and coupled against the rotating sleeve 18 by rotating the switching wheel 8 via the first drive wheel 14 . Likewise, the rotating sleeve 18 is slidable over the axial guide ribs 16 b of the guide sleeve 16 . The rotating sleeve 18 is also rotatable by means of the compression spring 20 , the bevels 17 b of the front locking teeth 17 a of the sliding sleeve 17 and the bevels 18 b of the counter-locking teeth 18 a of the rotating sleeve 18 in the next position.

When oppositely directed turning the ratchet 8, the rotary sleeve can in a constricting position of the fol Axialführungsrippen 16 18 b on the guide sleeve 16 are engaged.

The basic position 19 shown in Fig. 5 assumes that the ratchet 8 is at a "level = zero mm", which is determined by the position of the teeth 16 a. The ratchet wheel 8 or the first drive wheel 14 and the second drive wheel 15 are braced against one another by means of tension springs 21 . The resulting unit is axially displaceable by means of the control cam 8 a relative to the fixed drive pinion 9 or the fixed gear wheel 11 and can be brought out of engagement (gear wheel 11 ) or engaged (drive pinion 9 ). In Fig. 5, the ratchet wheel is at zero level, the first drive wheel 14 is in 'engagement with the toothing 16 a, the rotary sleeve 18 is locked in a locking point 24 in the guide sleeve 16 . This results in a power transmission drive pinion 9 / first drive wheel 14 / guide sleeve 16 to the first pair of tractors 5 . The power transmission path is shown in dotted lines.

The position shown in Fig. 6 (as a function of 1) shows the teeth 16a out of engagement with the first drive wheel 14. The switching wheel 8 is rotated to a predetermined level (e.g. 7 mm). As a result, the first drive wheel 14 , the second drive wheel 15 , the sliding sleeve 17 and the rotary sleeve 18 are pushed into a first intermediate position by a gear wheel rotation 22 in which the first drive wheel 14 and the rotary sleeve 18 are not locked in the guide sleeve 16 . The first pair of tractors 5 is not driven thereby.

In Fig. 7 is a view of the transmission 10 in a second position (2nd functi on) is shown. To drive the second pair of tractors 6 , in addition to the first intermediate position, the rotating sleeve 18 is snapped into the sliding sleeve 17 . The power transmission runs via the drive pinion 9 , the first drive wheel 14 , the second drive wheel 15 , the gear wheel 11 to the second pair of tractors 6 , which in turn is indicated by the dotted line. In this case, there is a relative displacement in the direction of arrow 23 for the first drive wheel 14 . The resulting driving point 29 is reached by rotating the rotating sleeve 18 in the counterclockwise direction 26 .

A third function is shown in FIG . The position is provided for the single sheet by means of the friction roller pairs 25 . For this purpose, there are several friction roller pairs 25 , which are driven via the gear train 3 , on a shaft ( FIG. 1 B), wherein a drive of the tractor pairs 5 or 6 is switched off. The ratchet wheel 8 is rotated counterclockwise 26 . The drive wheels 14 and 15 , as well as the sliding sleeve 17 and the rotating sleeve 18 are pushed back by the compression spring 20 , the rotating sleeve 18 engaging in the guide sleeve 16 . A locking point 28 thus defines the sheet feeder. There is no power transmission to the tractor pairs 5 and 6 , because the two drive wheels 14 and 15 run empty on the guide sleeve 16 . Power is only transmitted through the drive pinion 9 . The first drive wheel 14 is not coupled by the toothing 16 a and the second drive wheel 15 is not in engagement with the gear wheel 11 .

FIG. 9 shows a second intermediate position 31 (as a 4th function) for threading the rotary sleeve 18 into the sliding sleeve 17 . The ratchet wheel 8 is turned back to the "7 mm" level by means of the control cam 8 a. The drive wheels 14 and 15 , the sliding sleeve 17 and the rotating sleeve 18 are pushed into the intermediate position. The first drive wheel 14 and the rotating sleeve 18 are not snapped into the guide sleeve 16 .

Referring to FIG. 10, a power transmission to the second tractor is represented as a couple of 6 5. Function. The switching wheel 8 is with its control curve 8 a at "level 7 mm". The rotating sleeve 18 is locked in the sliding sleeve 17 at a driving point 29 . Locking takes place when rotating counterclockwise 26 . Power is transmitted on the chain-dotted line via the drive pinion 9 , the first drive wheel 14 , the second drive wheel 15 , the gear wheel 11 to the tractor pair 6 .

In Fig. 11, a 6th function is shown as the basic position for the first pair of tractors 5 ge. The ratchet 8 is with its control curve 8 a at "level zero mm". The first drive wheel 14 is coupled by means of the toothing 16 a with the guide sleeve 16 ge. The rotating sleeve 18 is located in the locking point 27 for the first pair of tractors 5 and is locked in the guide sleeve 16 . The power transmission (dotted Li never) takes place via the drive pinion 9 , the first drive wheel 14 and the guide sleeve 16 to the first pair of tractors 5 .

Reference list

1

Printer frame

2nd

Drive motor

3rd

Drive train

4th

Drive train

5

first pair of tractors

6

second pair of tractors

7

Polygonal wave

8th

Ratchet

8th

a control curve

9

Drive pinion

10th

Manual transmission

11

Gear wheel

12th

Gear wheel

13

Tractor wheel

14

first drive wheel

14

aCarrier

14

b pair of drivers

14

caxial ring surface

15

second drive wheel

16

Guide sleeve

16

a toothing

16

bAxial guide ribs

16

cpolygonal shaft end

17th

Sliding sleeve

17th

locking teeth on the front

17th

bDevices

18th

Rotating sleeve

18th

a Counter-ratchet teeth

18th

bDevices

19th

initial position

20th

Compression spring

20th

a stop ring

21

Tension springs

22

Gear wheel rotation / 1. Intermediate position

23

Arrow direction for adjustment

24th

Snap point / first tractor

25th

Friction roller pairs

26

Counterclockwise

27

Snap point / first tractor

28

Point of engagement / single sheet

29

Take-away point / second tractor

30th

31

2nd intermediate position

Claims (14)

1. Printer with at least one controllable or switchable pair of tractors and at least one pair of friction rollers, which can be driven by means of a common drive motor via gear trains and polygonal shafts of the pair of tractors, switching movements being able to be generated by means of a rotationally driven, axially acting control cam, characterized in that Functions for setting a basic position, intermediate positions, predetermined positions, for actuating the friction roller pairs ( 25 ) and basic positions of several tractor pairs ( 5 ; 6 ) by means of a translational, rotary and / or rotationally lockable guide ( 16 ) via a single manual transmission ( 10 ). , Sliding ( 17 ), rotating ( 18 ) or locking elements are releasable. 2. Printer according to claim 1, characterized in that the gearbox ( 10 ) each from a first, in the drive train ( 3 ) of the drive motor ( 2 ) located drive wheel ( 14 ) and drivers ( 14 a, 14 b) for a coaxial, second mirror image arranged drive wheel ( 15 ) from a by means of a toothing ( 16 a) in the first drive wheel ( 14 ) insertable guide sleeve ( 16 ) with axial guide ribs ( 16 b) on an internally toothed sliding sleeve ( 17 ) with front locking teeth ( 17 a) and is formed from a coaxially on the guide sleeve ( 16 ) displaceable rotary sleeve ( 18 ), the sliding sleeve ( 17 ) facing with the sliding sleeve ( 17 ) corresponding counter-locking teeth ( 18 a) is formed and that an axial annular surface ( 14 c) of the first drive wheel ( 14 ) bears axially against a control wheel ( 8 ) provided with a control cam ( 8 a). 3. Printer according to one of claims 1 or 2, characterized in that on the guide sleeve ( 16 ) on the one hand against the rotary sleeve ( 18 ) and on the other hand against a stop ring ( 20 a) supported compression spring ( 20 ) is arranged. 4. Printer according to one of claims 1 to 3, characterized in that the switching wheel ( 8 ) or the first drive wheel ( 14 ) and the second drive wheel ( 15 ) are braced against one another by means of tension springs ( 21 ). 5. Printer according to one of claims 1 to 4, characterized in that the sliding sleeve ( 17 ) can be pushed against the rotating sleeve ( 18 ) by rotating the switching wheel ( 8 ) via the first drive wheel ( 14 ). 6. Printer according to one of claims 1 to 5, characterized in that the rotary sleeve ( 18 ) on the axial guide ribs ( 16 b) of the guide sleeve ( 16 ) is displaceable. 7. Printer according to one of claims 1 to 6, characterized in that the rotary sleeve ( 18 ) by means of a compression spring ( 20 ), the bevels ( 17 b) of the front locking teeth ( 17 a), the sliding sleeve ( 17 ) and the bevels ( 18 b) the counter-locking teeth ( 18 a) of the rotating sleeve ( 18 ) in the next position is rotatable ver. 8. Printer according to one of claims 1 to 7, characterized in that when rotating the ratchet wheel ( 8 ), the rotary sleeve ( 18 ) in egg ne following position of the axial guide ribs ( 16 b) on the guide sleeve ( 16 ) can be latched. 9. Printer according to one of claims 1 to 8, characterized in that in the basic position of the switching wheel ( 8 ) the position "zero" is determined, in which the first drive wheel ( 14 ) engages with the toothing ( 16 a) of the guide sleeve ( 16 ) stands and the rotating sleeve ( 18 ) with its counter-locking teeth ( 18 a) in the locking teeth ( 17 a) of the sliding sleeve ( 17 ) is at a locking point ( 24 ). 10. Printer according to one of claims 1 to 9, characterized in that in an intermediate position, the switching wheel ( 8 ) is rotated to a predetermined Ni level of the control cam ( 8 a), the first drive wheel ( 14 ), the second drive wheel ( 15 ), the sliding sleeve ( 17 ) and the rotating sleeve ( 18 ) can be pushed into an intermediate position in which the first drive wheel ( 14 ) and the rotating sleeve ( 18 ) are not locked in the guide sleeve ( 16 ). 11. Printer according to one of claims 1 to 10, characterized in that for driving a second pair of tractors ( 6 ) in addition to the intermediate position, the rotary sleeve ( 18 ) can be snapped into the sliding sleeve ( 17 ). 12. Printer according to one of claims 1 to 11, characterized in that for a position of a single sheet feed by means of friction roller pairs ( 25 ) the switching wheel ( 8 ) is rotated counterclockwise ( 26 ), the first drive wheel ( 14 ), the second drive wheel ( 15 ), the sliding sleeve ( 17 ) and the rotating sleeve ( 18 ) are pushed back by means of the compression spring ( 20 ) until the rotating sleeve ( 18 ) has snapped into the guide sleeve ( 16 ). 13. Printer according to one of claims 1 to 12, characterized in that in an additional intermediate position, the switching wheel ( 8 ) is rotated to the predetermined level of the control cam ( 8 a) of the first intermediate position and that the first drive wheel ( 14 ), the second drive wheel ( 15 ), the sliding sleeve ( 17 ) and the rotating sleeve ( 18 ) can be pushed into the additional intermediate position. 14. Printer according to one of claims 1 to 13, characterized in that for a basic position of the first tractor pair ( 5 ), the switching wheel ( 8 ) with its control curve ( 8 a) is set to the level "zero" that the first drive wheel ( 14 ) engages in the guide sleeve ( 16 ) and that the rotary sleeve ( 18 ) engages in the position of the first drive wheel ( 14 ) in a latching point ( 27 ) in the guide sleeve ( 16 ).