Apparatus for storing a continuous web of material made from packaging material

An apparatus including a material accumulator (10) which is used, in conjunction with a packaging machine, for temporarily storing a continuous web (11) of material. Accurate operation of the material accumulator (11) is achieved by pivoting at least one deflecting roller (12, 13) of the material accumulator (10) about a rotational axis (38), which is directed transversely relative to the longitudinal axis of the web (11), to adjust the relative position of the web of material.

BACKGROUND OF THE INVENTION 
The invention relates to an apparatus for storing a continuous web of 
material made from packaging material, especially paper or foil, having a 
web of material accumulator comprising two groups of deflecting rollers 
which are movable relatively to one another and on which the web of 
material is guided in loops. 
Web of material accumulators are used for example in conjunction with 
packaging machines for temporarily storing a continuous web of material. 
Conventionally, a first group of deflecting rollers is moved relatively to 
a second group of deflecting rollers for increasing or reducing the 
contents of the accumulator. Fluctuations in the operation of the 
packaging machine can be compensated in this manner. Web of material 
accumulators are often used in conjunction with a device for joining a 
running-off web of material to a new web of material in connection with 
the exchange of a reel. The content of the accumulator of the web of 
material accumulator is increased before joining the webs of material, so 
that the web of material can be withdrawn from the web of material 
accumulator during the exchange of the reels (DE-41 07 254 A1). 
SUMMARY OF THE INVENTION 
The invention relates to increasing the possibilities for using the web of 
material accumulator. The object of the invention is to provide an 
apparatus which ensures a more accurate operation of the web of material 
accumulator. 
To attain this object, the apparatus is characterized in that at least one 
of the deflecting rollers of the web of material accumulator can be 
pivoted about an axis which is transverse relative to the longitudinal 
axis of the web of material for adjusting the relative position of the web 
of material. Preferably, the axis extends in a central longitudinal plane 
of the web of material. 
The web of material can thus be stored and, at the same time, adjusted with 
respect to its relative position by means of the apparatus according to 
the invention. Additional members for adjusting the relative position of 
the web of material are not required. The constructive effort and the 
required space of the apparatus according to the invention are thus 
reduced to a minimum. 
Expediently, the web of material accumulator is provided with two upright 
guide rods arranged parallel to one another. A holder is arranged at the 
upper end of the guide rods for the first group of deflecting rollers. A 
carrier for the second group of deflecting rollers is slidably guided on 
the guide rods in a vertical plane. TIle tension of the web of material 
can thus be kept constant as the result of the carrier's own weight. In 
such a web of material accumulator, the adjustment of the relative 
position of the web of material can advantageously be effectuated by 
pivoting the holder and/or the carrier. It is particularly advantageous if 
the web of material accumulator is pivotable as a whole, for example about 
an axis of rotation which extends in a central longitudinal plane of the 
web of material. 
Further features of the invention become apparent from a study of the 
claims and, in particular, relate to the design of the web of material 
accumulator, and to sensors for determining the filling level of the same. 
The invention is explained in more detail hereinbelow with reference to the 
drawings. In these:

DESCRIPTION OF PREFERRED EMBODIMENTS 
Web of material accumulators 10 are used in conjunction with packaging 
machines for temporarily storing a continuous web of material 11. In the 
web of material accumulator 10, the web of material is guided in loops 
over deflecting rollers 12 and 13. The respective deflecting rollers are 
combined to form a group 14, 15 of deflecting rollers 12, 13. The first 
group 14 of deflecting rollers 12 is arranged on a holder 16 so as to be 
freely rotatable. The deflecting rollers 12 are mounted in the holder 16 
and project therefrom on one side. 
The other group 15 of deflecting rollers 13 is also arranged so as to be 
freely rotatable on a carrier 17 which is movable relative to the holder 
16. The deflecting rollers, on their part, are mounted on the carrier 17 
and project therefrom on one side. 
As indicated by the double arrow 18, the carrier 17 is slideably arranged 
on two upright guide rods 19, 20 which are arranged parallel to one 
another. To this end, the carrier 17 is provided with two bores 21, 22 
arranged at a distance from one another through which the carrier 17 is 
guided on the guide rods 19, 20. The tension of the web of material is 
defined by the gravity of the carrier 17. 
The guide rods 19, 20 are connected to one another at their upper ends by 
means of the holder 16 and, on the opposite side, by means of a crosspiece 
23. For this purpose, the holder 16 and the crosspiece 23 are fixedly 
connected to the guide rods 19, 20. The latter are thus arranged at a 
fixed distance from one another. 
The deflection rollers 24 and 25 are assigned to the input and output side 
of the web of material accumulator 10, respectively, the deflecting 
rollers 24, 25 being arranged at a common level. Adjoining the output 
deflecting roller 25, the web of material 11 is guided around a pair of 
drawing rollers 26 in a Z-shaped manner. At least one of the two drawing 
rollers 27 is drivable so that the web of material 11 is transported 
through the pair of drawing rollers at a constant speed. 
Furthermore, the web of material accumulator 10 is assigned sensors 28, 29, 
30, 31. These sensors 28 to 31 serve for controlling the filling level of 
the web of material accumulator 10, and for controlling the feed and 
discharge rate of the web of material 11 to or from the web of material 
accumulator 10. The sensors 28 to 31, in the present case, take the form 
of inductive detectors which interact with a plate 32 on the carrier 17. 
The plate 32 is made from a magnetizable material. The sensors 28 to 31 
are arranged on a bracket 33 and fixedly connected to the machine stand 34 
by means of said bracket 33 (FIG. 3). 
The sensors 28 to 31 operate as follows: 
The web of material accumulator is in the normal operating position if the 
carrier 17 and thus the plate 32 is situated between the sensor 28 and the 
sensor 29. The distance between sensor 28 and sensor 29 thus corresponds 
to the fluctuation range of the position of the carrier 17. 
If the sensor 28 detects the presence of the plate 32, more web of material 
11 has been discharged from the web of material accumulator 10 than was 
fed thereto. In this case, at least one processing station for the web of 
material 11, or the pair of drawing rollers 26, is stopped. However, it 
may also be sensible to stop the entire system as a reaction to a signal 
from sensor 28, in order to check the system for operative failures. 
If only the sensor 29 is triggered, more material has been fed to the web 
of material accumulator 10 than was discharged therefrom. In this case, 
the feed rate of the web of material is reduced. If the carrier 17 still 
keeps lowering, sensor 29 and sensor 30 are also triggered. In this case, 
the feed of the web of material 11 to the web of material accumulator 10 
is stopped altogether. As can be seen from FIG. 1, the distance between 
the sensors 29 and 30 corresponds approximately to the length of the plate 
32. 
Should the web of material tear off, the carrier 17 lowers onto the 
crosspiece 23. This is detected by the sensor 31 and the entire system is 
stopped. 
In order to buffer the impact of the carrier 17 on the crosspiece 23, for 
example if the web of material 11 tears off, a shock absorber 35 is 
arranged on the carrier 17. A ram 36 of the shock absorber 35 rests on the 
integral nose 37 of the crosspiece 23. 
For adjusting the relative position of the web of material 11, the web of 
material accumulator 10 is pivotably arranged on the machine stand 34. In 
particular, the crosspiece 23, and thus the web of material accumulator 
10, can be pivoted about an axis of rotation 38 which extends in a central 
longitudinal plane of the web of material 11 according to FIG. 1, and, at 
the same time, in the plane of the incoming piece of web 39 of the web of 
material 11. The piece of web 39 is defined by the arrangement of the 
deflecting roller 24 on the input side and the one of the deflecting 
rollers 13 which is within the web of material accumulator 10 in the 
conveying direction. Preferably, the axis of rotation 38 furthermore 
extends parallel to the direction of motion of the carrier 17 along the 
guide rods 19, 20. 
For the accommodation of a bearing, the crosspiece 23 extends up to a 
lateral region of the axis of rotation 38 and has a transversely directed 
leg 40 there. This leg 40 is, coaxially relative to the axis of rotation 
38, provided with a downwardly directed bearing bolt 54, the bearing bolt 
54 being accommodated in a pivot bearing 55 arranged below the leg. 
Similar to the design and arrangement of the crosspiece described 
hereinabove, the upper holder 16 is provided with a transversely directed 
leg 56 which carries a bearing bolt 58 rotating in a bearing 57. 
The bearings 55 and 57 are positioned in cantilever arms 59, 60. These 
cantilever arms 59, 60 are assigned to the machine stand 34 and extend 
approximately parallel to the legs 40, 56. 
The crosspiece 23 has an extension 41 at the end opposite of the guide rod 
19 or the leg 40. With this extension 41, the crosspiece 23 projects 
beyond the region of the guide rod 20. A screw drive engages with the end 
of the extension 41, which is constructed as follows. 
A fork-shaped spindle nut 42 is arranged on the extension 41. The spindle 
nut 42 is articulated to the extension 41 of the crosspiece 23 by means of 
an upright bearing bolt 43. 
Furthermore, the spindle nut 42 is provided with a threaded bore 44 which 
interacts with an external screw thread 45 of a spindle rod 46. By 
rotating the spindle rod 46 about its longitudinal axis, the spindle nut 
42 is displaced in the direction of the double arrow 47 in FIG. 2, so that 
the web of material accumulator 10 is pivoted about the axis of rotation 
38. 
The pivoting of the web of material accumulator 10 can be effectuated 
manually or by means of a motor. Manual operation is shown in more detail 
in FIG. 2. In this case, the spindle rod 46 is provided with a handwheel 
48 at its free end. In a region adjacent to the handwheel 48, an axial 
bearing 49 is arranged, by means of which the spindle rod 46 is rotatably 
mounted in a holder 50. 
An operation by motor is shown in more detail in FIG. 3. In this case, the 
handwheel 48 is replaced by a servo motor 51. This servo motor 51 is 
flanged to the spindle rod 46, and connected to the holder 50 with its 
housing. 
An edge sensing member 52 serves for automatically controlling the pivoting 
movement of the web of material accumulator 10. This edge sensing member 
52 may be designed as a so-called forked light barrier, as described in DE 
33 41 539 C2. Via a line 53, the edge sensing member 52 is connected to a 
control device which, on its part, actuates the servo motor 51.