EP1362817A1 - Device for pushing out printed products stacked on a table - Google Patents

Abstract

The expulsion device (1) expels printed products (3) from a stacking shaft (5) set up for their size. The shaft consists of opposite two side guide walls (6, 7), along which guide battens (8, 9, 10, 11) in opposed pairs can be driven in the expulsion direction (F or F'), These battens form the front and rear boundaries of the shaft.

Description

The invention relates to a device for ejecting a table stacked printed products from one by four Side edges of the printed products determined stacking shaft.

EP 0 153 983 B1 discloses a device at the beginning mentioned type, in which the individually supplied printed products stacked lying in a stacking chute on a table and ejected as a stack.

This facility requires a relatively large amount of effort the setting resp. Switching the one viewed in the loading direction Shaft cross-section and the additional ejection device.

The object of the invention is therefore to establish a to create the kind mentioned at the beginning, which allows the Einund To simplify or change the shaft cross-section. without manual intervention and ejection to combine the stack with the shaft.

According to the invention the object is achieved in that the The stacking shaft in the direction of ejection looks at two opposite ones has lateral guide walls, along which one each, together with the opposite one in front and vertical, forming a rear shaft boundary Guide bar can be driven, and the rear in the ejection direction Guide rail pair is designed as an ejection device. This keeps the stack all the way along the ejection length Stack height led. This can cause stacks to be ejected be carried out from the shaft by himself.

Fig. 1

eine räumliche Ansicht einer erfindungsgemässen Einrichtung,

Fig. 2

eine vergrösserte räumliche Ansicht der einen Stapel aus Druckerzeugnissen bildenden Vorrichtung der erfindungsgemässen Einrichtung,

Fig. 3

eine Draufsicht auf die Vorrichtung gemäss Fig. 2,

Fig. 4

eine räumliche Darstellung einer Antriebsvorrichtung einer Vorrichtung zur Bildung eines Stapelschachts und zum Ausstossen des Stapels aus dem Stapelschacht und

Fig. 5

eine Draufsicht auf die in Fig. 4 gezeigte Antriebsvorrichtung.

Subsequently, the invention will be explained with reference to the drawing, to which reference is made with respect to all details not mentioned in the description, using an exemplary embodiment. The drawing shows:

Fig. 1

3 shows a spatial view of a device according to the invention,

Fig. 2

3 shows an enlarged spatial view of the device of the device according to the invention forming a stack of printed products,

Fig. 3

2 shows a top view of the device according to FIG. 2,

Fig. 4

a spatial representation of a drive device of a device for forming a stacking shaft and for ejecting the stack from the stacking shaft and

Fig. 5

a plan view of the drive device shown in Fig. 4.

1 illustrates a device 1 for ejecting printed products 3 which are stacked on a table 2 at the end of a stacking shaft 5 and which are indicated in the form of a stack 4 with dash-dotted lines. The end of the stacking shaft 5, from which the printed products 3 can be ejected in two opposite directions F, consists — viewed in the ejection direction F, F ′ — of two side guide walls 6, 7 lying opposite one another, which do not necessarily have to be constructed with full walls each of which, in the direction of ejection F, has a vertical guide bar 8, 9, together with the opposite one forming a front and a rear shaft boundary; 10, 11 can be driven, the guide strips 8, 9 in the ejection direction F the front shaft limitation and the guide strips 10, 11 the rear shaft limitation respectively. form an ejector 12; in the opposite direction of ejection F ', the guide strips 8, 9 form the rear stack limit, respectively. the ejector.
As a table 2 for supporting a stack 4, a roller table 2 is provided which consists of several conveyor rollers 14 which are freely rotatably mounted one behind the other in a frame 13 transversely to the direction of ejection F, F 'and which forms a flat supporting surface between the guide walls 6, 7 with lateral support rails 15.

The roller table 2 is on a bogie to be described 16 attached.

The guide strips 8 to 10, which at least reach the stack height, run around the vertical ends of the guide wall ends viewed in the direction of ejection F, F '. For this purpose, the upper and lower ends of a guide bar 8 to 11 are each on an endless toothed belt 17, 18 and. 19, 20 or an articulated chain attached to the driven pulleys 21 to 28 respectively. 21 'to 28' are guided. In this case, at the upper end or lower end of the standing axes assigned to a guide wall 6, 7, there are in each case one of the toothed belts 17 to 20 for the deflection rollers 21 to 28 or 21 ′ which determine the rear stack limitation or the guide strips 8 to 11 forming the front stack limitation. to 28 'arranged on the opposite guide wall 7, 6 (see also Fig. 2). In Fig. 1 as in Fig. 2, the lowest and uppermost deflecting roller 21, 22 and 25, 26 and 26 are respectively with respect to an ejection direction F. 21 ', 22' and 25 ', 26' the guide strips 8, 9 responsible for the front shaft limitation, whereas the guide rollers 21, 22, 25, 26 and. 21 '22' 25 '26' immediately adjacent deflection rollers 23, 24, 27, 28 and. 23 ', 24', 27 ', 28' of the rear shaft boundary respectively. Ejection device 12 are assigned. The to form the front shaft boundary, respectively. rear shaft boundary provided guide strips 8, 9 respectively. 10, 11 or timing belt 17 to 20 respectively. 17 'to 20' are each connected to a drive device 29, 30. The drive devices 29, 30 have a toothed belt transmission 31, 32 and are synchronous, respectively. separately drive-controlled, ie they have drive motors 33, 34 controlled by angle of rotation. 3, the drive devices 29, 30 can also be seen and FIGS. 4 and 5 show the drive device 30 separately.
To the circumferential toothed belt 17 to 20, respectively. In order to be able to use 17 'to 20' optimally, a further guide bar 8 'to 11' is attached to each half of its length, so that the following guide bars 8 'to 11' form a stacking shaft after an ejection process.
A guide wall 6, 7 of the stacking shaft 5 are each at the ends considered in the direction of ejection F, F 'two traction means 17 to 20, respectively, rotating about vertical axes. 17 'to 20' arranged, each of which a pair in the upper and lower end region of the guide strips 8 to 11 respectively. 8 'to 11' is provided. The traction means 17 to 20 respectively. 17 'to 20' run on pulleys 21 to 28 respectively. 21 'to 28' around. The guide strips 8, 9, 10, 11, each forming a front and rear shaft boundary in the direction of ejection F, F ', are drive-connected to both drive devices 29, 30 and can be used synchronously for the ejection process and independently for adjusting the format size in the direction of ejection F, F' , 1 and 2, the deflection rollers 22, 22 'and 26, 26' are firmly connected to the drive shafts 37 ', 38', whereas those with the deflection rollers 22, 22 'and 26, 26' by the traction means 17, 19th , 17 '19' drive-connected deflection rollers 25, 25 'on the shafts 37, 38 are freely rotatable. The drive shafts 37, 38 are firmly connected to the deflection rollers 23, 27 and 23 '27', while those with the traction means 18, 20 and. 18 ', 20' drive-connected deflection rollers 24, 28 and 24 '28' are freely rotatably mounted on the drive shafts 37 '38'.

The deflection rollers 24, 28 and 24 '28' could of course also be connected on the one hand to the drive shafts 37 '38' etc.
The toothed belt countershaft 31, 32 of the drive devices 29, 30 are on the underside of the bogie 16 by means of bearing supports 35, 36 and about two drive shafts 37, 38, 37 ', 38' of the guide rails 8 which run around two axially opposite axes in the direction of ejection F, F ' to 11 resp. 8 'to 11', with which deflection rollers 39, 40, 39 ', 40' are each drive-connected. A toothed belt 41, 42 carrying, freely rotating support rollers 43, 44 are mounted on the bearing supports 35, 36, 35 '36'.
The drive motors 33, 34 of the toothed belt transmission 31, 32 are attached by an intermediate gear 45, 46 to a support 47 (not visible), 48 connected to the bogie 16. The supports 47, 48 are in turn connected to a support frame 49, each of which has a support 50, 51 assigned to a guide wall 6, 7, in which the drive shafts 36, 36 '37, 37' of the guide strips 8 to 11 are mounted and on two guide rods (not shown), which are arranged transversely to the direction of ejection F, F 'and are anchored about the bogie 16, of a guide arrangement are slidably mounted. 2 shows bores 53, 53 ', 54, 54', which are penetrated by the guide rods fastened in the bogie 16 for displacing the carriers 50, 51. The carriers 50, 51, of the support frame 49 are driven to change or distance from one another by means of a spindle drive 55 in order to change the distance between the guide walls 6, 7. For this purpose, a telescopically drivable guide device 56, 57 is provided, each of which consists of two guide parts 58, 59 and 58 '59' which can be pushed together, one of which 58, 58 'has a guide groove for receiving the other. The guide parts 58, 59 and 58 ', 59' are connected to the support frame 49 and guide part 58, 58 'is suitable for fastening the supports 47, 48, on which the drive motor 33, 34 of a drive device 29, 30 is suspended, so that the toothed belts 41, 42 remain tensioned by compensation when adjusting the guide walls 6, 7.
The spindle drive 55 is provided for the adjustment of the guide walls 6, 7 so that there is a uniform lateral distance from the ejection axis of the stack 4 (see FIGS. 1 to 3). This consists of a geared motor 60 attached to the bogie 16, with which a shaft 61, which is oriented transversely to the direction of ejection F, F 'and is mounted on the turntable 16, is drive-connected (FIG. 3). On this shaft 61 a pulley 62, 63 is fastened for the lateral adjustment of the guide walls 6, 7 and the stacking shaft 5, which are drive-connected by means of a toothed drive belt or chain 64, 65 to a spindle rod 66, 67 moving the guide walls 6, 7, wherein the spindle rods 66, 67 have oppositely acting threads or a left-hand or right-hand thread. Due to the opposite movements of the guide walls 6, 7 and. Carrier 50, 51 of the support frame 49, the toothed belt 41, 42 guided over a compensation loop remains tensioned.

1 further shows the device 1 designed as a stacker, on the underside of which a drum 72 is provided which is fixedly connected to the bogie 16 and is mounted in a machine frame 73 and is drive-connected to a stationary electric motor 74. The partial stacks, which are alternately piled up by 180 ° to form a stack, can be pressed before being ejected by lifting the roller table 2 against the counterpressure elements 75 which can be displaced into the stacking shaft 5 by the guide walls 6, 7. For this purpose, the roller table 2 can be raised and lowered.
On the sides of the guide strips 8 to 11 facing away from a stack 4 of printed products 3 located in the stacking shaft 5, support members 76 are fastened at the top and bottom, which when the stack 4 is ejected from the stacking shaft 5 on the side of the guide walls 6 facing the stack 4 , 7 run.
The drive shafts 37, 38 'and 37', 38 respectively assigned to a guide wall 6, 7 are each supported at their upper end in a plate 77 connecting the drive shafts.

Claims (20)

Device (1) for ejecting printed products (3) stacked on a table from a stacking chute (5) determined by four side edges of the printed products (3), characterized in that the stacking chute (5) looks at two in the ejection direction (F, F ') has opposite lateral guide walls (6, 7) along which a vertical guide bar (8 to 11 and 8 'to 11'), together with the opposite one forming a front and a rear shaft boundary, can be driven, and that in the ejection direction (F , F ') rear pair of guide strips (10, 11 or 10', 11 'or 8, 9 or 8', 9 ') is designed as an ejection device (12). Device according to claim 1, characterized in that the pairs of guide strips (10, 11 or 10 ', 11' or 8, 9 or 8 ', 9') are each driven by traction means which are driven around toothed belts or articulated chains and which rotate around vertical axes (17 to 20 or 17 'to 20') are attached. Device according to claim 2, characterized in that the guide strips (8 to 11 and 8 'to 11') in the ejection direction (F, F ') of the front and rear shaft boundaries each have an upper and a lower end on the traction means (17 to 20 or 17 'to 20') are attached. Device according to claim 3, characterized in that a lower end resp. an upper end of a guide bar (8 to 11 or 8 'to 11') provided for a front or a rear shaft boundary has adjacent traction means (17 to 20 or 17 'to 20'). Device according to one of claims 1 to 4, characterized in that to form the front resp. rear shaft limitation, certain pairs of guide rails (8, 9 or 10, 11 or 8 ', 9' or 10 ', 11') are each assigned to a drive device (29, 30) which are drive-controlled synchronously or separately. Device according to claim 5, characterized in that on a drive shaft (37, 38, 37 ', 38') which has a standing axis, in each case two traction means (17 to 20) which are fixedly connected to the drive shaft (37, 38, 37 '38') , 17 'to 20') each with two freely rotatable deflection rollers (24, 28, 24 ', 28', 21, 25, 21 ', 25') of a drive shaft (37, 38, 37 '38') deflection rollers (22, 26, 22 ', 26'; 23, 27; 23 ', 27') are arranged. Device according to one of claims 2 to 6, characterized in that on the for the front resp. traction means provided at the rear shaft boundary (17 to 20 or 17 'to 20'), two guide rails (8 to 11 or 8 'to 11') assigned to a guide wall (6, 7) are fastened at regular intervals. Device according to one of claims 2 to 7, characterized in that to form the front resp. rear shaft boundary along the guide walls (6, 7) of the stacking shaft (5) traction means (17 to 20 or 17 'to 20') or. Guide strips (8 to 11 or 8 'to 11') are each drive-connected to one of the drive devices (29, 30). Device according to claim 8, characterized in that the guide strips (8 to 11 or 8 'to 11') as the ejection device (12) or the guide strips (8 to 11 or 8 'to 11') as the front shaft limitation are driven (29, 30) is assigned. Device according to one of claims 8 or 9, characterized in that the drive devices (29, 30) having a motor (33, 34) are designed as toothed belt drives (31, 32) rotating around vertical axes. Device according to one of claims 2 to 10, characterized in that the vertical axes of the guide strips (8 to 11 and 8 'to 11') running along a guide wall (6, 7) respectively. Traction means (17 to 20 or 17 'to 20') viewed in the ejection direction (F, F ') are arranged at the ends of the guide wall (6, 7). Device according to claim 10, characterized in that two respective axes of circumferential guide strips (8 to 11 or 8 'to 11'), which lie opposite one another transversely to the ejection direction (F, F '), are assigned to a drive device (29, 30). Device according to one of claims 8 to 12, characterized in that the respective axes assigned to a guide wall (6, 7) for changing the distance of the guide walls (6, 7) on a transverse to the ejection direction (F, F ') in a guide arrangement adjustable carrier (50, 51) of a support frame (49) are arranged. Device according to claim 13, characterized in that the carriers (50, 51) of the supporting frame (49) are each drive-connected to a spindle drive (55) having oppositely acting spindle rods (66, 67). Device according to one of claims 8 to 14, characterized in that the motor (33, 34) of a drive device (29, 30) of the guide strips (8 to 11 and 8 'to 11') each with a on the support frame (49) attached and connected parallel to the movement of the carrier (50, 51) telescopic guide arrangement. Device according to claim 15, characterized in that the motor (33, 34) of a drive device (29, 30) connected to a carrier (50, 51) of the supporting frame (49) by means of a countershaft (64,) connected to the spindle drive (55). 65) is displaceable in proportion to the change in distance of the guide walls (6, 7). Device according to claim 16, characterized in that the support frame (49) is fastened by the guide arrangement to a bogie (16) which can be driven about a vertical axis. Device according to one of claims 6 to 17, characterized in that the motor (33, 34) of a drive device (29, 30) by a toothed belt transmission (31, 32) with the opposite axes transverse to the direction of ejection (F, F ') each for the front resp. rear shaft boundary certain drive means (17 to 20 or 17 'to 20') or guide rails (8 to 11 or 8 'to 11') is drive-connected. Device according to claim 18, characterized in that the toothed belt transmission (31, 32) with deflection rollers (39, 40 or 39 ', 40') of the guide strips (8 to 11 or 8 'to 11') and on the bogie (16) mounted rollers (68, 69) or. Support rollers (43, 44) is drive-connected. Device according to one of Claims 18 and 19, characterized in that a section of a toothed belt (41, 42) connecting two opposing axes and a section of the toothed belt (connecting a standing axis to the drive wheel (71) of the motor (33, 34) 41, 42) forms a belt compensation loop (70) which can be changed as a function of the distance between the guide walls (6, 7).

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