EP1484272A1 - Drive for a paddle wheel or a an outlet conveyor - Google Patents

Abstract

The drive is for a copy conveyor (6-8), the speed of which is variable in conformance with the type of production which may be double production or copy-run production. A motor drives the copy conveyor, and the drive system incorporates a planetary gear (20) with a first drive component (16) rotationally driven by the motor, a second drive component (17) rotationally driven in at least one of the production types, and a driven component (18,19) which with the drive components forms a superimposing stage and drives the copy conveyor. An operating unit is coupled to the planetary gear and can change the rotational speed differential of the drive components for a change from one production type to the other.

Description

The invention relates to a drive a copy transport device, namely a Paddle wheel and / or a copy conveyor, in or for a folder in one or for a printing press, preferably a web-fed rotary printing press, particularly preferred a printing press for the printing of newspapers ..

Folders can be used in different types of production, especially in the Production type of double production and production type of collective production, operate. In double production, the incoming web into the folder is cut transversely to their transport direction and per section to a printed copy folded. The folded copy is fed to a paddle wheel and of the Paddle wheel removed by means of a copy conveyor. In the collection production the web will also be cut and folded crosswise, but will be on the Folding knife cylinders collected at least two sheets on top of each other and at the handover folded on the jaw cylinder. The folding blade cylinder thus carries at least two Turns to pass a printed copy on the jaw cylinder. Would the paddle wheel rotate at the same speed as in the Double production, so only every second blade of the paddle wheel with a Printed copy to be filled. Would the copy conveyor with the speed promote double production, a continuous scale flow could not be formed become. Nevertheless, to fill each blade and a continuous scale flow to The paddle wheel and the copy display are included in the collective production a correspondingly lower speed than in double production, namely at half the speed, if per printed copy on the Folding knife cylinder two sheets are collected.

Usually, the speed of the paddle wheel and the speed of the Copy conveyor with an independent drive depending on the Production type discontinued. Due to the increasing utilization of printing presses Production changes more frequently. Here comes the security of the exact Production adjustment is becoming increasingly important. Desirable is also the Remote adjustment of the folder.

It is an object of the invention to provide a drive of a specimen transport device, namely a paddle wheel and / or a copy conveyor to create, in the case the change of production a rapid and exact adjustment of the speed the copy transport facility allows.

The invention relates to a drive a copy transport device, namely a Paddle wheel or an associated copy conveyor or preferably the Paddle wheel and the copy conveyor in combination. The drive includes the Copy transport, an actuator, a planetary gear, and a motor, the copy transport device via the adjusting device and the planetary gear drives. The speed of the specimen transport device is by means of Adjusting device and the planetary gear in adaptation to the production types Double production and collective production changeable. The planetary gear has a from the motor rotationally driven first drive member, one in at least one of Production types also rotationally driven second drive member and a driven member on, which forms a superposition stage with the drive links and the Copy transporter device drives. The planetary gear can be multi-level, in However, the preferred embodiment, it is only one stage from the Antriebsgliedem and the Output member formed. The adjusting device is coupled to the planetary gear so that by means of a differential rotational speed of the drive members for a change of one of the types of production can be changed to the other.

According to the invention is thus in the drive train to the specimen transport device a planetary gear with at least one, preferably exactly one superposition stage arranged. The rotational speed of the output member of the superposition stage and thus together the rotational speed of the item transport device can by the Changing the differential rotational speed of the drive members in a simple manner and without axial displacement of gears and therefore constantly in the drive train be adapted adapted to meshing gears.

In one of the types of production, one of the drive members can in particular by means of Be set fixing device. In the other of the production types, the Differential rotational speed can be absolutely zero. Other speed ratios However, between the two drive links are also conceivable to the required Output speed of the output member to achieve.

The drive comprising the copy transport device can be present as such or already be an integral part of a folder. The folder can turn also be present as such or already installed in a printing press.

A particular advantage of the invention is that for the change in the speed of Item transport equipment no additional engine is needed. The Advantageously, copy transport means may even be provided by the same engine a jaw cylinder and / or a folding blade and / or a Cutter cylinder of the folder to be driven.

Preferably, the drive is from the engine to the actuator and of the Actuator on the epicyclic gearbox, via its output member on the Copy transport facility aborts. In principle, however, it would also be possible to Setting device with its own engine to form and drive in this case to overlap both motors in the overlay stage. However, preference is given to the Drive of the specimen transport device uses only a single engine, and the Actuator forms a torque split with a first branch for the Rotary drive of the first drive member and a second branch for the rotary drive of second drive member.

The adjusting device preferably comprises a coupling, by means of which the engine and the second drive member mechanically coupled for one of the production types and for the others can be decoupled. The coupling preferably couples positively and can preferably be switched in stages, z. B. according to the number of teeth of interlocking teeth of the coupling halves.

The adjusting device preferably comprises a brake, by means of which the second Drive member can be fixed to a frame of the item transport device. The brake preferably acts frictionally, so that it can be switched continuously. In order to prevent that after a change of the production type, in particular during the Transition from double to collective production, the copy fed to the paddle wheel too strong in the blade ground, the production conversion can advantageously in Dependence of different print job parameters by the connection of the friction brake be made. The conversion takes place during such a production changeover Delayed by a freely selectable rotation angle range after the copy delivery from Jaw cylinder to the paddle wheel. Imbalances on the paddle wheel become so reduces and prevents damage to printed copies. It does not have to a fixed rotational angular position of the paddle wheel in each case of double on Collective production and in the same position from collection to double production be converted. However, it is ensured that the copy transport facility does not lose its timed position to the jaw cylinder feeding the specimens.

In a particularly preferred embodiment, in which the adjusting device, the clutch and includes the brake, the brake acts on a shaft on which also acts the clutch. On this shaft sit one of the coupling halves of the clutch and one of the Brake halves of the brake. The shaft is preferably coaxial with one of the engine rotationally driven input wheel, with the shaft in the coupled state in common rotates. The input gear drives via Wälzkontakt with a first intermediate one of the Drive links, and the shaft drives over a sitting on her second, another Intermediate also via rolling contact the other of the drive links of the Circulating gear on.

The drive members of the superposition stage are preferably the sun gear and the Ring gear of the superposition stage formed as a planetary stage. Preferably, the form in a planet carrier rotatably mounted planet gears together with the self-rotatable stored planet carrier the output member. Basically, however, can also the sun gear or the ring gear of the planetary stage the output member and the two remaining members of the planetary stage form the drive links. The overlay stage is preferably a gear stage and more preferably a gear stage of stiff Gears.

For a preferably fully automatic changeover between the production types In preferred embodiments, the drive further comprises a control device. The Control device can be designed so that the changeover at a standstill or can be carried out during ongoing production.

The clutch and / or the brake preferably form or form one actuator or one each Actuator of the control device, particularly preferably such that the clutch coupled when the brake releases and brakes the brake, preferably locks when the Coupling decoupled.

Further preferred embodiments are described in the subclaims and their Combinations described.

Figur 1

einen Falzapparat mit einem Schaufelrad, einer Taktauslage und einem Exemplarabförderer, die einen gemeinsamen, erfindungsgemäßen Antrieb aufweisen,

Figur 2

ein Getriebe des Antriebs und

Figur 3

das Getriebe, einen Motor und eine Steuerung des Antriebs.

The invention will be described below with reference to a preferred embodiment. The features disclosed in the exemplary embodiment advantageously each individually and in each combination of features form the subject matter of the claims and also the embodiments described above. Show it:

FIG. 1

a folding apparatus with a paddle wheel, a clock display and a copy conveyor, which have a common drive according to the invention,

FIG. 2

a gearbox of the drive and

FIG. 3

the gearbox, a motor and a drive control.

FIG. 1 shows a folding apparatus with a cutting blade cylinder 3, a Folding blade cylinder 4, a jaw cylinder 5, a copy transport device 6-8 and an engine 10, the cylinders 3, 4 and 5 and the copy transport device 6-8 drives together. A paddle wheel 6, a clock delivery 7 and a copy conveyor 8 in combination form the copy transport 6-8. The copy conveyor 8 is a conveyor belt. About the folder two funnels 2 are arranged for Longitudinal folds of a printed web 1.

The engine 10 drives via a transmission, preferably via a single toothed belt or a single pair of gears, on a nearest to him driven by him Components of the folding apparatus, in the exemplary embodiment on the jaw cylinder. 5 From the shaft of the driven folder component, in the embodiment of the Shaft of the jaw cylinder 5, the other components of the folder via gear transmission also driven by the motor 10. In particular, the Exemplary transport 6-8 driven by the motor 10.

A gear via which the torque of the engine 10 on the Exemplary transport 6-8 is transmitted, Figure 2 shows. The transmission is on Gear transmission. The transmission comprises between an input gear 12, which of the Motor 10 is driven, and an output gear 23, which on the Exemplartransporteinrichtung aborts 6-8, in particular a planetary gear 20 and a Torque branch, by means of which without changing the drive speed of Motor 10, the output speed of the output gear 23 can be changed around the specimen transporter 6-8 once in double production and the other time to operate in collective production.

The planetary gear 20 is a planetary gear with a single stage, in which the Speeds of a first drive member 16 and a second drive member 17 of the Circular gear 20 are superimposed to an output member 18/19 of the epicyclic 20th with the superimposed rotational speed to drive. In the embodiment, the first drive member 16, the sun gear, the second drive member 17, the ring gear and the Planet gears 18 with their common planetary web 19, the output member 18/19. The second drive member 17 forms a housing pot, the members of the epicyclic 20th surrounds and connected on a torsionally rigid with the first drive member 16 Input shaft 16a and a torsionally rigid with the planet carrier 19 connected to the Input shaft 16a coaxial output shaft 19a is rotatably mounted.

The motor 10 drives a gear 11, which is connected to the input gear 12 of the transmission combs. The input gear 12 further meshes with a first intermediate gear 13, the aborts on the first drive member 16. In the embodiment, the gear 13 and the first drive member 16 torsionally rigidly connected to each other by each torsionally rigid the input shaft 16a of the epicyclic gear 20 sit. In the input gear 12th Branches the torque flow, namely on the one hand to the first idler gear 13 and the first drive member 16 and the other to a further, second Intermediate gear 15 and the second drive member 17. The second intermediate gear 15th is torsionally rigid with a to the axis of rotation of the input gear 12 coaxial shaft 14th connected. In the exemplary embodiment, the input gear 12 is rotatable on the shaft 14 stored. The second intermediate gear 15 is connected to an outer toothing of the second Drive member 17 in a tooth engagement.

The input gear 12 and the shaft 14 may be either for one common rotary drive rigidly coupled together or for a relative to each other free twistability are decoupled. The coupling and decoupling is done by means of a Clutch 25 causes, one half torsionally rigid with the input gear 12 and the other half torsionally rigid with the shaft 14 is connected. The clutch 25 couples form-fitting. In the exemplary embodiment, it is toothed with each toothed, im engaged state interlocking gears of their two Coupling halves formed. The input gear 12, the shaft 14 and the clutch 25 form the named torque branch by the coupled state of the Clutch 25, d. H. in the coupled state of the intermediate gears 13 and 15, the Intermediate gears 13 and 15 and further the two drive members 16 and 17th be rotated together. In disengaged, d. H. decoupled state turns the input gear 12, however, free from the shaft 14 and drives alone the first Drive member 16 at.

Thus, in the decoupled state, the second drive member 17 does not rotate freely, but a Support torque can absorb when the first drive member 16 is driven, that is second drive member 17 via a brake 26 on a frame of the Copy transport 6-8, d. H. on the frame of the folder, supported. in the Embodiment, a brake half of the brake 26 torsionally rigid with the shaft 14 and the other brake half rigidly connected to the frame. The brake 26 is a Friction brake.

In addition to the components already mentioned, the transmission further comprises for the Downforce of the output member 18/19 on the copy transport 6-8 already called output gear 23 and other gears 21 and 22. The gear 21 is torsionally rigidly connected to the planet carrier 19 by the planet carrier 19 and the Gear 21 each rigidly connected to the output shaft 19a of the epicyclic gear 20 are. The gear 21 meshes with the gear 22, and the two gears 22 and 23 sit torsionally stiff on a common shaft. The output gear 23 of the transmission meshes with a gear 24 which is arranged coaxially with the axis of rotation of the impeller 6 and torsionally rigid with the paddle wheel 6 is connected. The gear 24 drives over corresponding gear couplings on the clock display 7 and the copy conveyor 8 from.

FIG. 3 also shows the engine 10 and a gearbox beyond that of FIG Control device of the drive. The control device comprises a control member 9, which is housed in a control cabinet of the folder and the engine 10 via a Output 9a controls and regulates. The clutch 25 and the brake 26 form actuators of Control device. The control member 9 controls the clutch 25 via two outputs 9b and 9c and the brake 26 via two further outputs 9d and 9e. Both the clutch 25 and the brake 26 can each one of two possible clutch and Take braking conditions. The clutch 25 can optionally one of the two states Take "coupled" and "decoupled" in which the input gear 12 and the shaft 14 rigidly coupled or rotatable relative to each other and thus decoupled. The Brake 26 can optionally assume one of the two states "solved" and "fixed", in which the shaft 14 rotate freely relative to the frame or fixed to the frame. In the coupling 25, the coupling state is "decoupled" with S as collective production and the Coupled state labeled D as double production. At the brake 26 are the state "solid" with S as collective production and the state "solved" with D characterized as double production. The control member 9 controls the clutch 25 and the Brake 26 so that in the double production D, the clutch 25 couples and the brake 26 is dissolved, while in the collective production S, the clutch 25 decoupled and the Brake 26 brakes and locks the shaft 14 to the frame. The actuator 9 controls the Drive by means of its two actuators, namely the clutch 25 and the brake 26, between the output speed of the output member 18/19 for the collective production S and the higher output speed for the double production D um.

The function of the drive is described below in the synopsis of FIGS. 1 to 3 described.

In Figure 1, two printed web strands 1 are folded longitudinally in the formers 2 and to a track bundle merged. The track bundle runs into the gap between the cutting blade cylinder 3 and the folding blade 4, is on the Folding blade 4 fixed and cut across. Is it the current one? Production by a double production, so each copy obtained by the cut passed from the folding blade 4 on the jaw cylinder 5 and thereby transversely folded. The jaw cylinder 5 passes the transversely folded printed copies of the Paddle wheel 6, the copies in the cycle of double production in the blades of the Paddle wheel 6 thrown. By means of the clock display 7, the copies of the Buckets of the paddle wheel 6 pulled out and on the under the paddle 6 continuously discharging copy conveyor 8 in a uniform scale flow stored.

In the double production, the engine 10 runs according to the specification of the control member 9 at a certain speed. The control member 9 controls the clutch 25 via the outputs 9b and 9c in the state D "coupled" and the brake 26 via the Outputs 9d and 9e in the state D "solved".

The shaft 14 and the second intermediate gear 15 are thus rotationally driven and rotate with the speed of the input gear 12, via the permanent tooth engagement the first idler gear 13 drives. Through the resulting torque split becomes both the first drive member 16 and the second drive member 17th rotationally driven, namely in the same direction of rotation. The rotational speeds of Drive members 16 and 17 are superimposed in the output member 18/19, so that out the superposition of its output speed, namely the rotational speed of the Planet carrier 19, results. In the selected arrangement of drive and Output links results in a positive overlay, d. H. the rotational speed of the Output member 18/19 is larger than it would be if either the first drive member 16th or the second drive member 17 would be fixed. The output member 18/19 drives with his Output rotational speed via the gears 21, 22 and 23 the Copy transporter 6-8. About downstream gears is the drive within the item transport facility 6-8 as required predetermined distributed.

Should now be at standstill or while continuing press of the set Double production to be converted to collective production, for example on the Collecting two sheets of the cross-cut strand bundle, so is in Case of the changeover with continuing production the speed of the Copy transport 6-8 halved compared to the speed for the Double production.

The speed change is carried out fully automatically by the control device. It only has to be communicated to the control device that it should be changed For example, by pressing a button or by programming in advance in the course of Adjustment of the printing press can be done on the print production. For the conversion controls the control member 9 according to a software program the Engine 10 and the clutch 25 and the brake 26 at. It is basically possible that the motor 10 is driven so that it with unchanged speed continues or for the transition briefly to a lower speed is throttled, for example, to about one-third of the production speed, and then reboots again, of course, synchronously with the other drives of the Press.

The clutch 25 is in the state S "decoupled" via the outputs 9b and 9c. reversed so that the coupling halves are detached from each other and the shaft 14 and Finally, the second drive member 17 are decoupled from the motor 10. simultaneously controls the control member 9 via the outputs 9d and 9e, the brake 26 in the state S. "Fixed" order, so that the brake 26, the shaft 14 and the gear coupling with the Intermediate gear 15, the second drive member 17 fixed relative to the frame. Of the Transition from state D to state S is by means of the brake 26 via a predetermined rotational angle range of the impeller 6 delayed so that the first collected Printed copy not immediately with the after conversion less Relative speed between the jaw cylinder 5 and the paddle wheel 6 in impinges on the blade ground. As a result, imbalances of the paddle wheel 6, the otherwise when switching from double production to collective production, decreases.

In state S, d. H. in the collection production, of the engine 10 is only the first Drive member 16 of the epicyclic gear 20 rotationally driven, while the second Drive member 17 is fixed by means of the brake 26 and receives the support torque. The As a result, change the differential speed of the drive members 16 and 17 results in the Overlay a reduced output speed of the output member 18/19, in Embodiment halves the output speed. As a result, as in the double production each blade of the paddle wheel 6 each with a printed copy filled. With the reduction of the output speed reduce because of the fixed Coupling of the subordinate gear members of the item transport 6-8 inevitably the speeds of their components 6, 7 and 8 synchronously. If the production changeover motor 10 has been throttled, it will start after the Implementation of the decoupling means of the clutch 25 and the setting by means of the brake 26 accelerated back to full production speed, with the between the gear 11 and the gear 24 always present gear couplings be taken care that the drive of the specimen transport device 6-8 to the others Cylinders of the folder is in tact.

Claims (20)

Drive a copy conveyor (6-8), namely a paddle wheel (6) and / or a copy conveyor (8), in or for a printing press folder, the drive comprising: (a) the specimen transporter (6-8), the speed of which can be varied to suit the production modes of double production and collection, b) a motor (10) driving the specimen transport means (6-8), c) a planetary gear (20) having a first drive member (16) rotationally driven by the motor (10), a second drive member (17) also rotationally driven in at least one of the production modes, and an output member (18/19) connected to the drive members (16). 16, 17) forms a superposition stage and drives the specimen transport means (6-8), d) and with the epicyclic gear (20) coupled adjusting device (12-15, 25, 26), by means of a differential rotational speed of the drive members (16, 17) can be changed for a change from one of the production modes to the other. Drive according to claim 1, characterized in that the motor (10) rotatably drives the second drive member (17). Drive according to one of the preceding claims, characterized in that the motor (10) in the folder also drives at least one of the cylinders of cutting blade cylinder (3), folding blade cylinder (4) and jaw cylinder (5). Drive according to one of the preceding claims, characterized in that the adjusting device (12-15, 25, 26) a torque branch (12-15) with a first branch (12, 13) for the rotary drive of the first drive member (16) and a second Branch (12, 14, 15) for the rotary drive of the second drive member (17). Drive according to one of the preceding claims, characterized in that the adjusting device (12-15, 25, 26) has a first input gear (12) rotationally driven by the motor (10) and a first intermediate gear (13) rotationally driven by the input gear (12), which rotationally drives the first drive member (16). Drive according to one of the preceding claims, characterized in that the adjusting device (12-15, 25, 26) one of the motor (10) rotationally driven input gear (12) and a second intermediate wheel (15) which, for a common rotary drive with the Input gear (12) can be coupled and the second drive member (17) rotatably drives. Drive according to one of the preceding claims, characterized in that the adjusting device (12-15, 25, 26) comprises a coupling (25), by means of which the motor (10) and the second drive member (17) for one of the production modes coupled together and for the other can be decoupled from each other. Drive according to one of the preceding claims, characterized in that the adjusting device (12-15, 25, 26) comprises an input wheel (12) rotationally driven by the motor (10) and a clutch (25) by means of which the input wheel (12) and the second drive member (17) can be coupled together for one of the production modes and decoupled from each other for the other. Drive according to the preceding claim, characterized in that the input gear (12) rotatably mounted relative to a shaft (14) and a second intermediate gear (15) for driving the second drive member (17) with the shaft (14) are rigidly connected and in that the coupling (25) couples the input gear (12) and the shaft (14) for one of the production modes and decouples them from each other. Drive according to the preceding claim, characterized in that the input gear (12) is rotatably mounted on the shaft (14). Drive according to one of the preceding claims, characterized in that the adjusting device (12-15, 25, 26) comprises a brake (26) by means of which the second drive member (17) on a frame of the item transport means (6-8) can be fixed. Drive according to the preceding claim in combination with one of claims 9 and 10, characterized in that the brake (26) has a rotationally rigid with the shaft (14) connected to the brake half. Drive according to one of the preceding claims, characterized in that a sun gear and a ring gear of a planetary stage form the drive members (16, 17). Drive according to one of the preceding claims, characterized in that a planet carrier of a planetary stage forms the output member (18/19). Drive according to one of the preceding claims, characterized in that the drive comprises a control member (9) for an automatic changeover of the adjusting device (12-15, 25, 26). Drive according to the preceding claim, characterized in that the changeover is carried out while the folding machine is running, preferably during production. Drive according to claim 15, characterized in that the conversion is carried out at a stationary folder. Drive according to one of the preceding claims, characterized in that the specimen transport device (6-8) comprises the paddle wheel (6), the copy conveyor (8) and a clock delivery (7) by means of the printed copies in the blades of the paddle wheel (6) Exemplarabförderer (8) can be stored, and that the output member (18/19) drives the paddle wheel (6). Drive according to the preceding claim, characterized in that the output member (18/19) also drives the clock delivery (7). Drive according to one of the two preceding claims, characterized in that the driven member (18/19) also drives the copy conveyor (8).

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