DE4235704C1 - Longitudinal buffer for electrophotographic printer or copier - provided in path of recording carrier in endless format and forms loop for compensation of varying transport speeds of differing sets of printer or copier - Google Patents

Abstract

A conducting rocker (1) located swivelable at a swivel axis (4) contacts the recording carrier (2) at a point (3) with a set force (RP). A spring combination with a deflection spring element (5) applies a deflection moment on the rocker, and with a spring element (6) applies a compensation moment at the swivel axis. The working line of the spring force (10) of the spring element (6), in the initial position of the rocker free end, runs in a dead position to the swivel axis (4) so that the recording carrier force (RP) is determined by the deflection moment of the spring element (5). With the swivelling of the rocker (1) in the working range, the working line of the spring force (10) of the compensation spring element (6) is swivelled from the dead point, so that the compensation spring element exerts the compensation moment on the rocker (1). ADVANTAGE - Risk of harm e.g. tearing of recording carrier is minimised, so that processing reliability and quality of printer or copier is improved.

Description

The invention relates to a length buffer for an electrogra fish printing or copying machine, the record carrier in processed in an endless format. The record carrier will in the record carrier transport path by tractors operating in engage an edge perforation, or by pairs of rollers, be standing from pressure and counter roller, in record carrier direction of transport. Such drives are on several Places provided in the record carrier transport route. At for example, the record carrier is driven by a tractor drive to a fusing station, where one on the up Carrier-based toner image due to pressure and heat is fixed on the record carrier. The up Drawing medium between a motor driven Fi xierwalze and a pressure roller pinched and by Frik tion transported in the direction of recording medium. Two between the tractor drive and the friction drive wrestle brief asynchronies of the transport speed ity causing damage or tearing of the record can lead.

From EP-A1-0 432 298 it is known between two drives for to provide a recording medium with a length buffer. Of the The length buffer consists of one around a swivel axis pivoting guide arm that counteracts a spring force the pivot axis is pivotable. The free end of the guide Swing arm has a touch area for the recording carrier on. The recording slides in the touch area flat on the guide arm or it is supported by a roller arranged in the contact area. About the Be the guiding arm presses the recording medium  ger away from the swivel axis and thus extends the recording carrier transport route. At the extreme swivel positions of the Guide arm arranged sensors provide information about which of the drives for the record carrier must run faster or slower for the recording tion carrier between the drives remains so tense that it neither tears nor flutters. The guide arm therefore acts as Loop puller.

It has now been shown that despite the use of the length buffer deformation or even cracks in the record can occur.

From DE-OS 19 08 270 an unwinding device for an in Roll form provided paper stock known that a Includes loop puller. At the stored end of the loop pull herarms is a cam on which a Zugfe that attacks at an acute angle to the loop puller arm. By this arrangement is achieved that the on the force acting on the paper is independent of the loop deflection is pending.

The aim of the invention is to reduce the risk of damage to the Record carrier or even a tearing of the record to minimize the carrier and thus the processing reliability casualness and the processing quality of the electrographi to increase printing or copying equipment.

This goal is achieved by those specified in claim 1 Features resolved.

Advantageous embodiments of the invention are in the Un marked claims.

In the length buffer according to the invention, the force with which the guide rocker presses against the record carrier the entire swivel range is approximately constant. This solution  is based on the knowledge that in the known Längenpuf fer the force with which the guide arm in the recording Carrier presses, depending on the swivel position of the guide arm is. This has a particularly negative effect on the up drawing carrier because in the operation of printing or copying device, the guide arm constantly swings between is subjected to their extreme positions.  

The stroke of the swivel movements could indeed be fine current regulation of the drive speeds of the one behind the other the switched drives can be reduced. Such a fine one Feeling regulation would be an analog recording of the Assume the swing arm of the guide rocker. This is ever but not possible for reasons of cost and reliability. Instead of the analog detection of the swivel position in the Usually two different pivot positions of the guide swing arm detected with one sensor each. It so happens that the guide rocker constantly operates between these two Swivel positions in which the guide rocker is different Exerts forces on the record carrier, commutes.

When using the length buffer according to the invention, the Guide arm in every swivel position, including the Ex extreme swivel positions in which the sensors are arranged, approximately the same force on the recording medium. This is achieved by using two spring elements. Of the The point of application of the deflection spring element is with respect to Pivot axis arranged so that the contact area of the Guide arm is pressed against the record carrier. Of the Point of application of the compensation spring element on the The guide arm is based on one of the maximum deflections kung assigned to the guide rocker, in which the Line of action of the compensation spring element in a dead was to the swivel axis, so that the Recordsträ force in this starting position only by the spring force of the Deflection spring element is determined so chosen that when ver the guide arm swings the line of action into the work area of the compensation spring element from the dead position so is pivoted that the compensation spring element Compensation moment exerts on the guide rocker. This Compensation torque compensates for this due to the extension of the deflection spring elements increasing off when pivoting the guide arm steering torque.  

When determining the spring force of the deflection spring element the starting point can be assumed. In this starting position this must depend on the spring force of the deflection spring element and the Lever arm of the deflection spring element on the guide rocker called deflection moment like a record carrier be the moment caused by the recording medium force and the Lever arm of the record carrier force is set. The hey Noise refers to the distance between the swivel axis and the respective line of action of a force. The recording Carrier force is determined by the parameters of each Record carrier specified. To these parameters of the The record carrier includes its width, thickness and tear strength. The lever arm of the record carrier force in the The starting point is the geometry of the record carrier route determined. Thus the record carrier is moment determined in the starting position. Lever arm and spring force of the deflection spring element are to be selected accordingly.

By choosing the point of application of the compensation spring ment on the guide arm, so that on the guide arm acting spring force of the compensation spring element in the Ar beitsbereich is approximately constant, you achieve that with compensation rectified to the record carrier torque moment almost exclusively from the compensation lever arm and thus from the point of application of the compensation spring element to the Guide arm depends. This dependency is also special well manageable, since they are linear when swiveling the Guide arm changes.

As spring elements are suitable for tension or compression Feathers. However, a torsion is also used as the deflection spring element suitable for spring. A torsion spring could, for example, ent be arranged along the pivot axis. The points of attack of the Spring elements can be arranged directly on the guide arm his. In many cases, however, you will prefer to use the Guide arm to couple a spring clip to which the An  handles are arranged. Depending on the design of the spring elements, the points of attack in the form of holes for Hook in tension, compression or torsion springs or in form of sliding surfaces running eccentrically around the swivel axis be designed for compression and / or leaf springs.

The spring clip allows the points of attack to be arranged to the side of the guide arm in the direction of the record carrier seen. The spring clip can run in the record carrier seen in front of or behind the pivot axis of the guide swing or directly on the swivel axis with the guide swing arm to be connected.

The use of a ge on both sides is particularly advantageous supported rigid axis serving as a pivot axis. Along this rigid axis can be the fixed end of the guide rocker be consolidated. This measure will, for example made of sheet metal or an aluminum drawing profile, guide arm designed as a guide flap transversely to the recording stiffened. This leads to a possible torsion of the Guide flap profile is prevented. A twist of the lead flap profile would have an impermissible inclination of the up drawing medium and thus a reduction in reliability of the printer or copier.

With the help of the rigid axle it is also possible to get one out two side swing arms and one between the swing arms poor existing role in the contact area To guide the guide arm without twisting. In addition, one Ensure even force distribution on the swing arms continuous

In addition, a rigid pivot axis has the advantage that the spring clip can be flanged directly to it and thus can be easily coupled to the guide rocker.  

Given spring elements and spring engagement points elements is the force with which the spring elements act on the The guide arm acts through the pretensioning of the spring elements certainly. The preload of the spring elements is mechanical by the distance of the attack points from these attacks score opposite fastening points of the Federele ment determined. Now on a printer or copier Requested that this record carrier with under should be able to process different parameters. Depending on These parameters require the recording medium force with which the guide arm on the recording medium eng acts to adjust. In a particularly advantageous way this setting is made in one operation for the comm pensationsfederelement and the deflection spring element together. This common adjustment is through one with the deflection spring element and the compensation spring element coupled Spring element carrier, its distance from the guide rocker is changeable, easily possible.

In a special embodiment, the spring elements designed as spiral springs. These spiral springs are between the spring element carrier and the spring clip clamped. The line of action of the compensation spring element is between the point of application on the spring clip and the attachment point on the Fe the element carrier deflected. This happens because the compensation spring element on the side of a deflection roller, which is arranged along its longitudinal extension. By the position of the pulley with respect to the swivel axis the guide arm is the requirement regarding the course of the Line of action of the compensation spring element in the starting position easily achievable. The line of action of the Kompensa tion spring element in the starting position is therefore independent from the distance of the spring element carrier to the points of attack adjustable.  

It is not imperative to keep the coil spring on the order to let the steering wheel rest. A short com be selected spring, whose line of action to Federele ment carrier or to the point of attack on the guide arm extend a wire rope, which is passed over a pulley device. Such a solution could be disadvantageous compared to a long spring steeper force / path of the short compensation spring impact, thereby achieving optimal force compensation would be difficult.

The distance of the spring element carrier to the guide rocker can by a rotating spindle coupled to the spring element carrier can be changed easily. This lathe can either by a hand crank or by a tax The motor can be driven. So is an adjustment of the Optional record carrier force on the record carrier manually or automatically possible.

With automatic adjustment of the recording medium force the record carrier becomes the type of record carrier manually by operator input, semi-automatically by one Barcode reader pen or automatically by reading one on the Record carrier or its packaging printed bar code detected. A control unit controls the spindle driving motor so that the distance between the Federele ment carrier and the guide arm to the job to be processed Drawing carrier is adapted.

It is advantageous to use the rotating spindle and spring element carrier to couple a trapezoidal thread. With this thread there is self-locking, so that the set rotary posi tion and thus the set recording medium forces are automatically locked and fixed. On a special one Backstop can be dispensed with.

An embodiment of the invention is in the drawings shown and will be described in more detail below, for example wrote. It shows

Fig. 1 shows a schematic diagram of the length buffer with the guide arm pivoted into its initial position and

Fig. 2 shows a length buffer according to Fig. 1 with pivoted in an end position tion guide rocker.

An electrographic printing or copying machine, the recording carrier 2 processes in an endless format, includes various functional units, such as. B. a fuser and a transfer station. These two stations are successively arranged in the direction of the recording medium. As the recording medium 2 continuous paper with Randperfora tion is suitable. In both stations, the record carrier 2 is driven by friction between at least one motor-driven pair of rollers. The drive speeds of the two drives differ slightly from one another. This difference in speed arises, for example, due to roller diameters changing with temperature change or due to wear, a slippage of the recording medium 2 between the rollers or tolerances of the perforated edge of the recording medium 2 . This difference in speed would inevitably lead to egg formation or a tear of the recording medium 2 . To prevent this, a length buffer according to FIG. 1 is provided between the two drives in a record carrier transport path located between the drives.

At the installation point of the length buffer, the record carrier transport path has a change in direction, for example 45 °. Before and behind the buffer length on the record carrier 2 lies flat on the recording medium guiding means 15, 16. Between these recording medium guide means 15 , 16 , a contact area 3 of a guide arm designed as a guide flap 1 presses across the recording medium direction against the recording medium 2 . Here, the recording medium 2 is dependent on the deflection of the deflector 1 is a more or less large loop. In the formation of these desired loop, the guide vane 1 so presses against the recording medium 2, that this remains tensioned independently of the deflection of the guide flap 1 with a constant force. This voltage is achieved when inserting the record carrier 2 in that the Traktoran driven the edge perforation is slightly turned back compared to the roller drive.

The guide flap 1 has a crescent-shaped profile. Its free end is curved and has accordingly the approximate range Berüh 3, on which the record carrier 2 moving tet. A fixed end of the guide flap 1 is fixed along a star ren pivot axis 4 , which extends transversely to the recording medium direction. The pivot axis 4 is located in the vicinity of the first record carrier guide means 15 seen in the direction of the record carrier, while the free end of the guide flap 1 is correspondingly moved in the region of the second record carrier guide means 16 . The radius of curvature of the crescent-shaped guide flap 1 is adapted to the deflection angle of the record carrier transport path and the swivel range of the guide flap 1 so that the record carrier 2 does not come into contact with a possibly sharp edge of the guide flap 1 in any pivoted position of the guide flap 1 .

A spring clip 11 is arranged in front of the pivot axis 4 as seen in the direction of the recording medium. The spring clip 11 is fastened to the pivot axis 4 and is located outside the record carrier transport path. The size of the Federbü gels 11 is dimensioned and its embodiment so designed that spring elements 5 , 6 suspended on the spring clip 11, the spring clip 11 in any possible pivot position of the guide flap 1 touch.

For hanging the spring elements 5 , 6 11 openings are made in the direction of the pivot axis 4 in the spring clip. One of these openings serves as the point of attack 7 from a steering spring element 5 . The other opening serves as the point of attack 8 of a compensation spring element 6 . The spring elements 5 , 6 are designed as spiral springs stressed on train. The end of the spring elements 5 , 6 opposite the points of attack 7 , 8 is in each case suspended on a spring element carrier 12 common to both spring elements 5 , 6 . The spring member support 12 is arranged below the recording substrate transport path, that the Auslenk spring element 5 exerts such a torque on the spring clip 11 to the guide vane 1 so that this presses with its touch area 3 against the record carrier. 2

An extreme position of the guide flap 1 is shown in FIG. 1. With this maximum deflection, the guide flap 1 is in its initial position. The starting position of the guide flap 1 marks the longest possible record carrier transport path. In this starting position, the line of action of the compensation spring element 6 runs in a dead position to the pivot axis 4th The spring force 10 of the compensation spring element 6 does not cause any torque on the guide flap 1 in this dead position. A compensation spring lever arm is not available in the starting position.

In order to bring the line of action of the spring force of the compensation spring element 6 into the dead position, a deflection roller 13 is arranged in a fixed manner in the length buffer. The Kompensationsfe derelement 6 is partially on the circumference of the guide roller 13 .

The line of action of the deflection spring element 5 is in the starting position at a certain distance from the pivot axis 4 . This distance forms a deflection arm AAO in the starting position. The spring force 9 of the deflection spring element 5 acts together with the deflection spring arm AAO in the starting position, a deflection torque on the guide flap 1 . This deflection moment counteracts a recording medium moment.

The record carrier torque is made up of the resultant force directed against the record carrier force RP, which results from the tension of the record carrier 2 and its deflection by 45 °, and from a record carrier lever arm APO in the starting position. The record carrier lever arm APO in the starting position is determined by the distance of the line of action of the force directed against the record carrier force RP to the pivot axis 4 .

If the guide flap 1 is now pivoted downward about its pivot axis 4 in the counterclockwise direction due to increasing forces in the recording medium 2 so that the recording medium transport path is shortened, then the compensation spring element 6 becomes effective. Since the spring clip 11 is located on the side of the pivot axis 4 opposite the free end of the guide flap 1 , the spring clip 11 is rotated counterclockwise around the pivot axis 4 upwards. The line of action of the compensation spring element 6 migrates from its dead position. Depending on the pivot position of the guide flap 1 , the distance of this line of action to the pivot axis 4 is different. In the fictitious end position of the guide flap 1 , which is marked by a straight connecting line between the recording medium guide means 15 , 16 , the distance of the line of action of the compensation spring element 6 from the pivot axis 4 is at a maximum and forms a compensation spring arm AKU in the end position. The guide flap 1 never reaches the end position since the length buffer is ineffective in this end position.

The line of action of the deflection spring element 5 changes its distance from the pivot axis 4 during the pivoting process and it extends in the end position to a deflection spring lever arm AAU in the end position. The deflection spring arm AAU in the end position is smaller than the deflection spring arm AAO in the starting position. Thereby, the already partially compensated 5 resulting in the spring clip 11 increasing the spring force of the Auslenkfederelements 5 during rotation due to the increase of the ex article between element support spring 12 and contact point 7 of the Auslenkfederelements. However, this compensation has hardly any effect on the forces actually acting on the recording medium 2 because, on the one hand, the change in force of the deflecting spring elements 5 is very large compared to the change in lever and, on the other hand, the forces acting on the recording medium 2 are reduced due to a shortening of the recording medium Increase the APU in the end position compared to the recording medium lever APO in the starting position. This lever arm ringing occurs because the contact area 3 of the guide flap 1 with the recording medium 2 moves when pivoting into the end position in the direction of the pivot axis 4 .

This effect does not occur with a guide rocker 1 , which consists of two lateral rocker arms and a roller running between the rocker arms in the contact area 3 . Compensation of the changing deflection forces acting on a guide rocker 1 of this embodiment is also possible.

The influence of the shortening of the recording medium lever AP and the increasing spring force 9 of the deflection elements 5 is compensated by the influence of the compensation spring element 6 so that the recording medium force RP and thus the force in the recording medium 2 remains approximately constant. The compensation effect and thus the compensation moment increases linearly until the end position of the guide flap 1 is reached. The reason for this is that the distance between the line of action of the compensation spring element 6 from the pivot axis 4 increases, so that the compensation spring lever arm AKU is greatest in the end position. At the same time, the distance between the spring element carrier 12 and the point of attack 8 of the compensation spring element 6 on the spring clip 11 changes only to such a small extent that the spring force 10 of the compensation spring element 6 remains approximately constant in the entire working range.

Record carriers 2 differ from one another by their material, their width and their thickness and the resulting tear strength. The recording medium force RP can be adapted to these different parameters. This is done in a simple manner by changing the distance between the spring element carrier 12 and the grip points 7 , 8 of the spring elements 5 , 6 on the spring clip 11 .

A trapezoidal nut 17 is attached to the spring element carrier 12 . A rotating spindle 14 runs through this trapezoidal nut 17 . The axis of the bilaterally mounted rotary spindle 14 runs par allel to the line of action of the deflection spring element 5 in the starting position. The main plane of the spring element carrier 12 is perpendicular to the axis of the rotating spindle 14 . The distance HA of BEFE stigungspunktes the deflection spring element 5 to the spindle axis and the distance HK between the attachment point of the compensation spring element 6 on the spring element carrier 12 and the spin delachse are coordinated so that the resultant end acting on the spring element carrier 12 moment is zero. This protects the trapezoidal thread of the rotating spindle 14 and the trapezoidal nut 17 . With the help of a crank 18 , the rotary spindle 14 can be rotated and thus the distance between Fe derelementträger 12 and spring clip 11 can be changed. The trapezoidal thread of the rotary spindle 14 has a self-locking effect, so that the rotary positions of the rotary spindle 14 cannot be locked.

Reference list

1 guide flap / guide arm
2 record carriers
3 touch area
4 swivel axis
5 deflection spring element
6 compensation spring element
7 point of application of the deflection spring element
8 point of application of the compensation spring element
9 spring force of the deflection spring element
10 spring force of the compensation spring element
11 spring clips
12 spring element supports
13 pulley
14 rotating spindle
15 first record carrier guide means
16 second record carrier guide means
17 trapezoidal nut
18 crank
AAO deflection lever arm in the starting position
AAU deflection spring lever arm in end position
AKU compensation spring lever arm in end position
APO record carrier lever arm in the starting position
APU record carrier lever arm in end position
RP record carrier force

Claims (7)

1. Length buffer for an electrographic printing or copying device, the recording medium ( 2 ) in an endless format ver works with

• - A arranged in a recording medium transport path and in the area of its one end on a parallel to a recording medium plane and transverse to a recording medium running pivot axis ( 4 ) pivotally mounted guide rocker ( 1 ), the other, free end in a working area between an end position and one maximum deflection associated starting position and is pivotable, has a contact region (3) with which the Leitschwinge (1) having a recording medium force (RP) against the recording medium (2) presses,
• - A spring combination acting on the guide rocker ( 1 ) with a deflection spring element ( 5 ) for applying a steering torque from the pivot axis ( 4 ) to the guide link ( 1 ) and a compensation spring element ( 6 ) for applying a compensation torque about the pivot axis ( 4 ) on the guide rocker ( 1 ), the point of attack ( 7 ) of the deflection spring element ( 5 ) on the guide rocker ( 1 ) and its spring force ( 9 ) with the point of action ( 8 ) of the compensation spring element ( 6 ) on the guide rocker ( 1 ) and sen spring force ( 10 ) are coordinated so that un depending on the pivoting position of the guide rocker ( 1 ) the record carrier force (RP) remains constant, with the choice of the points of attack ( 7 , 8 ) and for the coordination of the spring forces ( 9 , 10 ) applies:
  • - In the starting position of the free end of the guide rocker ( 1 ), the line of action of the spring force ( 10 ) of the compensation spring element ( 6 ) runs in a dead position to the pivot axis ( 4 ) through its center of rotation, so that the record carrier force (RP) in this starting position the Auslenkmo element of the deflection spring element ( 5 ) is determined,
  • - When pivoting the guide arm ( 1 ) in the Arbeitsbe rich swings the line of action of the spring force ( 10 ) of the compensation spring element ( 6 ) from the dead center, so that the compensation spring element ( 6 ) exerts the Kompensationsmo element on the guide arm ( 1 ).

2. Length buffer according to claim 1, in which the point of attack ( 8 ) of the compensation spring element ( 6 ) on the guide rocker ( 1 ) is selected such that the spring force ( 10 ) acting on the guide rocker ( 1 ) of the compensation spring element ( 6 ) in the working area is approximately constant. 3. Length buffer according to one of claims 1 or 2, with a pivot axis ( 4 ) serving, both sides mounted rigid axis to which one end of the guide rocker ( 1 ) is attached. 4. Length buffer according to one of claims 1 to 3, with a with the guide rocker ( 1 ) coupled spring clip ( 11 ) on which the points of attack ( 7 , 8 ) of the deflection spring element ( 5 ) and the compensation spring element ( 6 ) are arranged. 5. length buffer according to one of claims 1 to 4, with a with the deflection spring element ( 5 ) and the compensation spring element ( 6 ) coupled spring element carrier ( 12 ), the stand from the guide rocker ( 1 ) is variable, whereby the Fe derforce ( 9 , 10 ) both spring elements ( 5 , 6 ) are adjustable. 6. length buffer according to claim 5, with formed as spiral springs spring elements ( 5 , 6 ) and with a deflection roller ( 13 ), with the help of the spring force ( 10 ) of the compensation spring elements ( 6 ) between the guide rocker ( 1 ) and spring element carrier ( 12 ) is deflectable. 7. length buffer according to one of claims 5 or 6, wherein the distance of the spring element carrier ( 12 ) to the guide rocker ( 1 ) by a with the spring element carrier ( 12 ) coupled rotary spindle ( 14 ) is variable.