Technical Field
[0001] The present invention relates to a line for packaging products in bags. The technical
sector to which this invention belongs is that of the lines for packaging products,
for example food, which may be liquid, solid or granular.
Prior Art
[0002] In the technical sector of packaging products in bags there are prior art packaging
lines which, starting from a web of plastic or paper material, produce bags in which
to package the products. More specifically, the web passes through a plurality of
processing stations along the packaging line. Following a feed path of the web, the
line includes a folding station, wherein the web is folded, a sealing station, wherein
at least two flaps of the web (folded) are sealed to each other (for example by heat-sealing)
to define an un-sealed bag, a cutting station, wherein the un-sealed bags are separated
from each other, a filling station (usually a rotary carousel), wherein the bags are
filled with the product, and a sealing station, wherein the bag is sealed.
[0003] In these packaging lines, the feeding of the web is an alternating forward movement
generated by a plurality of motor-driven rollers, each of which may be associated
with (that is, is designed to feed) a respective processing station. Each motor-driven
roller is characterised by a feed step which depends on the productivity of the respective
machine with which the motor-driven roller is associated.
[0004] The patent document EP 3265386 B1 describes a solution to adjust the tension of a web due to its stretching between two processing stations of a same
productivity. This solution comprises having an additional web drawing unit between the two drawing units feeding web to the said processing stations.
[0005] The productivity of the processing stations may be heterogeneous and, consequently,
the feed step of the motor-driven rollers may be different.
[0006] In the lines in which this condition occurs, the difference between the steps of
feeding the motor-driven rollers could cause a loss of tension of the web in the line
or, on the other hand, and excessive tensioning of the web.
[0008] Patent document
EP0999134A2 describes a solution wherein a movable element (connected to the web) responds to
a variation in the tension of the web by varying the position of a piston. The position
of the piston is measured by a control unit which, as a function of the position,
determines a tension of the web. As a function of the tension of the web, the control
unit adjusts the unwinding speed of a reel for feeding the web. However, this solution
does not take into consideration imbalances between the processing stations which
are known before the start of the machine. For this reason, the system adjusts the
tension only after having detected an increase in the tension, thus increasing the
risk that the web can deteriorate.
[0009] Patent document
BO93A000453 illustrates a station including a plurality of rollers on which the web is wound.
However, it does not describes in any way how this solution can overcome the unbalance
generated by heterogeneous steps along the line.
[0010] Patent document
BO94A000073 illustrates an adjustment unit wherein the tension of the web is kept constant by
adjusting the pressure of a negative pressure chamber, in which the web is sucked.
The negative pressure in the chamber is proportional to the tension of the web. This
is a self-regulating solution, for which the system responds to variations in length
of the unwound web by adapting autonomously. However, the adjustment is not precise
and not very reliable, since any failings of the negative pressure pump could adversely
affect the operation. Moreover, the solution of
BO94A000073, having to guarantee a pressure inside the vacuum chamber (delimited by the web),
has serious problems related to the hydraulic seals, which further reduce the degree
of reliability.
Description of the Invention
[0011] The aim of this invention is to provide a line for packaging products in bags and
a method for packaging products in bags which overcomes the above-mentioned drawbacks
of the prior art.
[0012] This aim is fully achieved by the line for packaging products in bags and by the
method for packaging products in bags according to the invention as characterised
in the appended claims.
[0013] According to one aspect of this invention, the method provides a line for packaging
products in bags. The line comprises a feed unit. The feed unit is configured for
receiving a web from a reel. The feed unit is configured for moving the web along
a feed path. In some embodiments it is possible that the web has been divided upstream
and, therefore, the movement unit is configured for moving portions of the web.
[0014] The line comprises a control unit. The control unit is connected to the feed unit
for moving the web. In one embodiment, the control unit is connected to the feed unit
for moving the web intermittently, by a sequence of forward movements of predetermined
spacing.
[0015] According to invention, the line comprises a folding station. The folding station
is configured for folding the web about a folding line. In one embodiment, the folding
line is oriented along the feed path, for superposing a first and a second flap of
the web. In some embodiments the line is also fed with two separate webs, superposed
to form the first and second flap of the web.
[0016] According to invention, the line comprises a sealing station. The sealing station
is configured for sealing the first and second flap (of the folded web). According
to invention, sealing station is configured for sealing the first and second flaps
(of the folded web) along sealing lines oriented transversally to the folding line.
In one embodiment, the sealing station is configured for sealing the first and second
flaps (of the folded web) along sealing lines oriented parallel to the folding line.
[0017] According to invention, the line comprises a cutting station. A cutting station is
configured for cutting the packaging web, for defining a plurality of packaging bags.
[0018] According to invention, the line comprises a filling station. The filling station
is configured for filling with a product the plurality of packaging bags.
[0019] According to invention, the line comprises a sealing station. The sealing station
is configured for sealing the plurality of packaging bags.
[0020] According to invention, the feed unit includes a first motor-driven roller. The first
motor-driven roller is controlled by the control unit. The first motor-driven roller
is configured for moving the web through the folding and/or sealing stations. The
first motor-driven roller is configured for moving the web through the folding and/or
sealing stations, by a first succession of forward movements, with a first feed step.
[0021] According to invention, the feed unit comprises a second motor-driven roller. The
second motor-driven roller is controlled by the control unit. The second motor-driven
roller is controlled by the control unit for moving the web by a second succession
of forward movements
different to that of the first succession of forward movements, with a second feed step. The second feed roller is configured for moving the web
through the cutting station. In one embodiment, the second motor-driven roller is
positioned upstream of the cutting station. The second motor-driven roller is positioned
downstream of the first motor-driven roller. In one embodiment, the first feed step
and the second feed step are different.
[0022] According to invention, the line includes an adjustment unit. The adjustment unit
is positioned between the first and second motor-driven roller. The adjustment unit
is configured for adjusting a tension of the web. The adjustment unit is configured
for varying the length of the feed path.
[0023] According to invention, the adjustment unit includes a tensioning element. The tensioning
element is operatively in contact with the web. The tensioning element is movable
between a first operating position, wherein the feed path has a first length, and
a second operating position, wherein the feed path has a second length. In one embodiment,
the first length is different from the second length. The length of the feed path
means the length of the web unwound starting from the reel up to the point in which
it is cut in the cutting station.
[0024] According to invention, the adjustment unit includes an actuator. The actuator is
connected to the tensioning element for varying a position of the tensioning element,
so as to vary the length of the feed path.
[0025] In this way, by actively controlling the actuator, there is a more precise control
of the tension of the web which will always be kept at an optimum tension value.
[0026] The actuator is connected to the control unit. The actuator is connected to the tensioning
element by a transmission unit. The transmission unit is configured for transmitting
(and, if necessary, transforming) the motion of the actuator into a movement of the
tensioning element along an adjustment direction.
[0027] The control unit is configured for receiving working data. The working data representing
operating parameters of the line. More specifically, they may include information
relating to the work cycle of the bags to be packaged and/or the working times of
each station and/or the starting times of the first and second motor-driven rollers
and/or the number of bags to be produced. According to invention, the working data
represent the first and second succession. According to invention, the control unit
is configured for generating control signals. The control signals are a function of
the working data. The control unit is configured for controlling the actuator by means
of the control signals, thus, as a function of the working data.
[0028] This feature makes it possible to know before the activation of the line the speed
profile (thus the position at any instant) which the tensioning element must follow
(have). For this reason, the control is not a feedback control which has, by its very
nature, a certain delay in the adaptation which sometimes may prove critical.
[0029] In one embodiment, the actuator is configured for moving the tensioning element according
to a predetermined speed profile. In one embodiment, the speed profile is a constant
profile overtime. In one embodiment, the speed profile is a linear profile increasing
or decreasing over time. In one embodiment, the speed profile is a profile which increases
up to a maximum point and then decreases to zero in such a way as to prevent excessive
inertial loads on the tensioning element.
[0030] In one embodiment, the actuator is an electric actuator.
[0031] Using an electric actuator considerably simplifies the command and control of the
movement of the tensioning element.
[0032] In other embodiments, the actuator may be a pneumatic actuator and/or a hydraulic
actuator and/or an internal combustion engine.
[0033] In one embodiment, the adjustment unit comprises a supplementary tensioning unit.
The supplementary tensioning element is operatively in contact with the web. The supplementary
tensioning element is movable for varying the tension of the web. The supplementary
tensioning element is movable for varying the length of the feed path as a function
of its position. In one embodiment, the supplementary tensioning element is configured
for varying its position automatically with the variation of the tension of the web.
[0034] The presence of a supplementary tensioning element is very advantageous for the reliability
of the system. In effect, it constitutes an important backup for the tensioning element
if the latter is damaged or incorrectly controlled.
[0035] In one embodiment, the supplementary tensioning element is connected to a damping
member. The damping member, in one embodiment, includes an elastic element. The elastic
element is configured for applying an opposing force, opposite to the direction of
a movement of the supplementary tensioning element. In one embodiment, the elastic
element is a spring. In other embodiments it may be a pneumatic cylinder.
[0036] The elastic element includes a first end connected to a frame of the adjustment unit
and a second end connected to the supplementary tensioning element in such a way as
to dampen its movement relative to the frame of the adjustment unit.
[0037] In one embodiment, the adjustment unit comprises a guide. In one embodiment, the
tensioning element includes a slide. The slide may also be part of the adjustment
unit and be rigidly connected to the tensioning element.
[0038] In one embodiment, the tensioning element includes an idle roller.
[0039] The slide of the tensioning element is configured for translating in the guide of
the adjustment unit for moving the tensioning element, along the adjustment direction,
from the first to the second operating position.
[0040] In one embodiment, the tensioning element is oriented parallel to the direction of
the weight force. In one embodiment, the tensioning element is oriented parallel to
a plane perpendicular to the direction of the weight force.
[0041] In one embodiment, the line comprises a tension sensor. The tension sensor is configured
for measuring the tension of the web. The tension sensor is configured for generating
tension signals, representing the tension of the web. In one embodiment, the tension
sensor is configured for sending the tension signals to the control unit. The control
unit is configured for receiving the tension signals. The control unit is configured
for generating at least a part of the control signals as a function of the tension
signals. The control unit is configured for instructing the actuator for moving the
tensioning element.
[0042] The tension sensor may constitute a further secondary system to be used if the tensioning
element is not correctly controlled by the control unit as a function of the working
data previously set.
[0043] In one embodiment, the first motor-driven roller is located downstream of the sealing
station along the feed path.
[0044] In one embodiment, the adjustment unit (the line) comprises a plurality of fixed
rollers. The plurality of fixed rollers is operatively in contact with the web. The
plurality of fixed rollers operates in conjunction with the tensioning element to
define the path of the packaging web inside the adjustment unit.
[0045] According to one embodiment which is not in the scope of the invention, the adjustment
unit includes a tensioning element, operatively in contact with a web and movable
between a first operating position and a second operating position for varying the
length of a feed path followed by the web in the packaging line.
[0046] The adjustment unit includes an actuator, connected to the tensioning element for
varying a position of the tensioning element, so as to vary the length of the feed
path. The actuator of the adjustment unit my be an electric motor or a pneumatic motor.
[0047] The adjustment unit comprises a control unit, configured for generating control signals,
as a function of working data, representing operating parameters of (a first succession
of forward movements of the web and a second succession of forward movements of the
web, performed by) a first motor-driven roller and a second motor-driven roller of
the packaging line. The adjustment unit is configured for being positioned between
the first and the second motor-driven roller of the packaging line wherein the adjustment
unit is integrated. In one embodiment, the control unit is connected to the actuator
to control it, through the control signals, in order to modify the position of the
tensioning element.
[0048] According to one aspect of this invention, a method is provided for the packaging
of products in bags.
[0049] The method comprises steps according to claim 10.
[0050] In one embodiment, during the controlled movement step, the actuator moves the tensioning
element according to a predetermined speed profile. In one embodiment, the actuator
moves the tensioning element with a constant speed. In one embodiment of the, the
method comprises a step of moving a supplementary tensioning element, connected with
the web, for varying, as a function of a supplementary tensioning position, the length
of the feed path.
[0051] In one embodiment, the step of moving the supplementary tensioning element comprises
a damping step. In this damping step, a damping member applies an opposing force on
the supplementary tensioning element. The opposing force is opposite to the direction
of a movement of the supplementary tensioning unit due to a variation of the web tension.
In this way, the web never reaches excessive tension values which might adversely
affect the condition.
[0052] In one embodiment, the step of moving the tensioning element comprises a step of
translation of a slide, connected tensioning element, in a guide of the adjustment
unit.
[0053] In one embodiment, the method comprises a feedback control step. In this feedback
control step, a tension sensor measures a tension value of the web and generates corresponding
tension signals, representing the tension value of the web. In this feedback control
step, the tension sensor sends the tension signals to the control unit. The control
unit generates corresponding control signals, as a function of the tension signals.
The control unit sends the control signals to the actuator for controlling it during
the movement of the tensioning element.
[0054] This and other features of the invention will become more apparent from the following
description of a preferred embodiment of it, illustrated purely by way of example
in the accompanying drawings.
Brief Description of the Drawings
[0055]
Figure 1 schematically illustrates a plan view of a line for packaging products in
bags;
Figure 1A is a plan view of a part of the line of Figure 1;
Figure 2 is a perspective view of a part of the line of Figure 1;
Figures 3A and 3B schematically illustrate a unit for adjusting the line of Figure
1 in a first and in a second operating configuration, respectively;
Figures 4A and 4B schematically illustrate two embodiments of a first succession of
forward movements, performed by a first motor-driven roller, and a second succession
of forward movements, performed by a second motor-driven roller, respectively.
Preferred Forms of Embodiment of the Invention
[0056] With reference to the accompanying drawings, numeral 1 denotes a line for packaging
products in bags. The products may be liquid, solid, gases or granular.
[0057] The line 1 comprises a control unit 10. The control unit 10 is configured for controlling
operating parameters (working parameters) of the line 1. The line 1 comprises a user
interface 10'. The user interface 10' is configured for allowing a user to enter configuration
data, representing operating parameters of the line 1.
[0058] More specifically, the configuration data include working data 101. In one embodiment,
the working data 101 is data which identifies the work cycle of the line. For this
reason, in some embodiments, the working data 101 represents the productivity of each
machine of the line (units processed per unit time).
[0059] The line 1 comprises a feed unit 11. The feed unit 11 is configured for receiving
a packaging web and for moving it in the line 1 along a feed path P. The feed path
P change its direction during the path.
[0060] According to invention, the feed unit 11 is configured for moving the web intermittently.
In short, the feed unit is connected to the control unit for moving the web according
to a succession of forward movements and pauses. Each feed and each pause defines
a feed time and a pause time, respectively.
[0061] In one embodiment, the feed path is included in a plane perpendicular to the direction
of the weight force. In one embodiment, the feed unit includes a plurality of feed
rollers 110. The web is wound around the plurality of feed rollers 110 for being moved
along the line 1. More specifically, the plurality of feed rollers 110 is configured
for conveying the web while keeping it at a predetermined tension value.
[0062] In one embodiment, a part of the plurality of feed rollers 110 is motor-driven, that
is to say, their movement is determined by a driving force transmitted by an actuator.
In one embodiment, a part of the plurality of feed rollers 110 is idle, that is to
say, their movement is determined by the friction force of the web drawn by the plurality
of motor-driven rollers.
[0063] In one embodiment, each motor-driven roller defines a respective stationary time
and feed time. For this reason, within the feed unit, the feed line may comprise different
pause and feed times. These differences are substantially due to the processing times
of each machine (units worked per unit time).
[0064] The control unit 10 is connected to the feed unit 11 for controlling it as a function
of the working data 101.
[0065] In one embodiment, the line 1 comprises a feed station 12. The feed station 12, in
one embodiment, includes a reel 12A. In one embodiment, the feed station 12 may comprise
a reserve of pre-machined web.
[0066] The feed station 12 is configured for feeding the web to the feed unit 11 to allow
a relative movement along the feed path P.
[0067] According to invention, the line comprises a folding station 13. The term "station"
means a plurality of elements which contribute to the performance of a specific function.
The folding station 13 is configured for folding the web. According to invention,
the folding station 13 is configured for folding the web around folding lines 131,
oriented along the feed path P. The folding station 13 is configured for folding the
web about the folding lines 131, superposing a first and a second flap of the web.
The folded web is thus formed by two flaps connected at the folding line (that part
of the web, in a preferred embodiment, is set up to become the bottom of the packaged
bag). In one embodiment, the folding station 13 is located downstream of the feed
station 12.
[0068] According to invention, the line 1 comprises a sealing station 14. The sealing station
14 is configured for sealing the first and second flap of the web along sealing lines
141. The sealing station 14, in one embodiment, comprises a transversal sealing station
14A, configured for sealing the first and second flap of the web along transversal
sealing lines 141A, perpendicular to the feed path P. The sealing station 14, in one
embodiment, comprises a longitudinally sealing station 14B, configured for sealing
the first and second flap of the web along longitudinal sealing lines 141B, parallel
to the feed path P. In one embodiment, wherein the first and second flaps might come
from two webs separate from each other, the longitudinal sealing lines 141B define
the bottom of the packaged bag. In one embodiment, the transversal sealing lines 141A
define the sides of the packaged bag.
[0069] In one embodiment, the sealing station 14 is configured for sealing at a first working
speed. The sealing station 14, is configured for processing, during a stationary time,
a first length of the web.
[0070] According to invention, the line 1 comprises a cutting station 15. The cutting station
is configured for cutting the web, separating it into a plurality of portions which
define a plurality of packaging bags. The cutting station includes a cutting tool
15'. The cutting tool 15' is configured for cutting the web along cutting lines 151.
In one embodiment, the cutting lines 151 are transversal, perpendicular to the feed
path.
[0071] In one embodiment, the cutting station 15 is configured for sealing at a second working
speed. For example, the cutting station 15 is configured for processing, during a
stationary time, a second length of the web.
[0072] The control unit is configured for receiving the working data 101, representing the
first and second working speeds.
[0073] According to invention, the line 1 comprises a filling station 16. The filling station
16 is configured for allowing the filling of the plurality of packaging bags with
the product. In one embodiment, the filling station 16 includes a filling carousel
161. The filling carousel may include a plurality of suction surfaces 162. The plurality
of suction surfaces 162 is configured for retaining the bags during their filling
by means of a negative pressure generated by a suction of air.
[0074] In one embodiment, the line 1 comprises a conveyor 17.
[0075] The conveyor 17 is configured for picking up the packaging bags from the cutting
station 15 is placing them at the filling station 16. The conveyor 17, in one embodiment,
includes a suction surface 171, on which each packaging bag for is retained during
its conveying to the filling station 16.
[0076] According to invention, the line 1 comprises a sealing station. The sealing station
is configured so as to seal (close) the packaging bags for making them watertight
(preventing escape and entrance of products).
[0077] According to invention the feed unit 11 comprises a first motor-driven roller 11A.
The first motor-driven roller 11A is controlled by the control unit 10. The first
motor-driven roller 11A is configured for moving the web through the folding and sealing
stations. The first motor-driven roller 11A is configured for moving the web through
the folding and sealing stations, by a first succession of forward movements S1, with
a first feed step. In short, the first feed step is a feed step which corresponds
to a feeding of the web of the first length.
[0078] In one embodiment, the first motor-driven roller 11A is located downstream of the
sealing station. In one embodiment, the first motor-driven roller 11A is located upstream
of the sealing station.
[0079] The first motor-driven roller 11A rotates at a first rotation speed. The first motor-driven
roller 11A is rotated for a first feed time T1.
[0080] The first succession of forward movements S1 is spaced by a corresponding first succession
of pauses.
[0081] According to invention, the feed unit 11 comprises a second motor-driven roller 11B.
The second motor-driven roller 11B is controlled by the control unit 10. The second
motor-driven roller 11B is configured for moving the web through the cutting station.
The second motor-driven roller 11B is configured for moving the web through the cutting
station by a second succession of forward movements S2, with a second feed step. In
short, the second feed step is a feed step which corresponds to a feeding of the web
of the second length.
[0082] The second motor-driven roller 11B rotates at a second rotation speed.. The second
motor-driven roller 11B is rotated for a second feed time T2.
[0083] The second succession of forward movements S2 is spaced by a corresponding second
succession of pauses.
[0084] In one embodiment, the second motor-driven roller 11B is positioned upstream of the
cutting station 15. In other embodiments, the second motor-driven roller 11B is positioned
downstream of the cutting station 15. The second motor-driven roller 11B is positioned
downstream of the first motor-driven roller 11A.
[0085] It should be noted that the first feed step and the second feed step are different.
[0086] In one embodiment, the first and second feed steps are different because the first
T1 and the second T2 feed times are different for values of the first and second rotation
speeds which are equal to each other. In one embodiment, the first and the second
feed steps are different because the first and second rotation speeds are different
for values of the first T1 and the second T2 feed times which are equal to each other.
[0087] According to invention, the line 1 includes an adjustment unit 18. The adjustment
unit 18 is configured for adjusting the tension of the web. The adjustment unit 18
is positioned, along the feed path P, between the first motor-driven roller 11A and
the second motor-driven roller 11B. The adjustment unit 18 comprises a frame 180.
[0088] According to invention, the adjustment unit 18 includes a tensioning element 181.
The tensioning element 18 is operatively in contact with the web in order to keep
it at a predetermined tension value. The tensioning element 18 is movable. The tensioning
element 18 is movable between a first operating position P1 and a second operating
position P2 for varying the length of the feed path P. More specifically, a first
length L1 of the feed path P corresponds to the first operating position. A second
length L2 of the feed path P corresponds to a second length of the feed path P, different
from the first feed path length. Since the choice of first and second position is
totally arbitrary, in one embodiment, the first length L1 is greater than the second
length L2. More specifically, in one embodiment, the difference between the first
length L1 and the second length L2 is equal to the difference between the first feed
step and the second feed step. In effect, the travel of the tensioning element 18
makes it possible to balance the line 1 being able to keep the tension of the web
constant with the predetermined value.
[0089] According to invention, the adjustment unit 18 comprises an actuator 182. The actuator
182 is connected to the tensioning element 181 for varying a relative position. This
makes it possible to vary the length of the feed path and to keep constant the tension
of the web. In one embodiment, the control unit 10 is configured for determining control
signals 102 as a function of the working data 101. The working data 101 represents
the first S1 and the second S2 succession of forward movements and, consequently,
the first and second succession of pauses. In one embodiment, the control unit 10
is configured for sending the control signals 102 to the actuator 182 for varying
the position of the tensioning element 181. For this reason, the tensioning element
181 is a controlled element which, by knowing the work cycle of the web, can anticipate
the variations of tension induced by imbalances in the line 1 and may, therefore,
ensure an optimum tension of the web.
[0090] In one embodiment, the control signals 102 represent a speed profile, representing
the position of the tensioning element 181 over time. In short, the control signals
are configured for changing operating parameters of the actuator 182 (electrical power,
chemical power, hydraulic power, pneumatic power etc.) in such a way as to obtain
the speed profile required for the tensioning element 181. This allows an overall
control of the movement of the tensioning element 181, which may vary speed and direction
of movement. In one embodiment, the actuator 182 includes an electric motor and/or
an internal combustion engine and/or a pneumatic motor and/or a hydraulic motor.
[0091] In one embodiment, the adjustment unit 18 includes a transfer unit 183. The transfer
unit 183 is designed for transferring the motion of the actuator 182 to the tensioning
element 181.
[0092] In one embodiment, the adjustment unit includes a slider 183', constrained to the
tensioning element 181. In one embodiment, the adjustment unit includes a guide 183",
in which the slide 183' can slide to define a direction R for adjusting the tensioning
element 181.
[0093] In one embodiment, the adjustment unit 18 includes a lead screw 182', integral with
and in rotation with a drive shaft of the actuator 182. The terms integral and in
rotation mean that the lead screw 182' rotates at a speed of rotation which depends
on the speed of rotation of the drive shaft according to the specifications and any
speed reducer.
[0094] The lead screw 182' is coupled with the slide 183' to transform a rotation of the
lead screw 182' into a translation of the slide 183' along the adjustment direction
R. The translation of the slide 183' produces a variation in the position of the tensioning
element 181 and a consequent variation in the length of the feed path P.
[0095] In this embodiment, the slide 183' is movable along the lead screw 182' from a first
position, corresponding to the first operating position P1 of the tensioning element
181, to a second position, corresponding to the second operating position P2 of the
tensioning element 181.
[0096] In one embodiment, the tensioning element 181 is a tensioning roller (idle) on which
the web is wound. In one embodiment. The tensioning roller has a maximum direction
of extension parallel to the direction of the weight force. In a preferred embodiment,
the adjustment direction R belongs to a plane lying perpendicular to the direction
of the weight force. In one embodiment, the direction of adjustment R is parallel
to the direction of the weight force.
[0097] In one embodiment, the adjustment unit 18 includes a plurality of fixed rollers 184.
The plurality of fixed rollers 184 is operatively into contact with the web. The plurality
of rollers fixed 184 operates in conjunction with the tensioning element 181 to define
the path of the web inside the adjustment unit 18.
[0098] In one embodiment, the adjustment unit 18 comprises a supplementary tensioning element
185. The supplementary tensioning element may be a tensioning roller, on which the
web is wound. The supplementary tensioning element 185 is operatively in contact with
the web. The supplementary tensioning element 185 is movable in order to vary, as
a function of a relative position, the length of the feed path P. More specifically,
the supplementary tensioning element 185, in response to any variations in tension
of the web due to faults or failings in the tensioning element 181, is configured
for varying its position, in such a way as to vary the length of the feed path P and
therefore the tension of the web.
[0099] In one embodiment, the supplementary tensioning element 185 is coupled with the frame
180 of the adjustment unit 18 by a prismatic pair. In short, in this embodiment, the
supplementary tensioning element 185 comprises a carriage 185' slidable inside a track
185".
[0100] In one embodiment, the adjustment unit 18 includes a damping member 186, configured
for damping any sudden jolting of tension which the web may undergo in particular
situations. The damping member 186 is connected to the supplementary tensioning element
185 to dampen its movement. The damping member 186 comprises an elastic element 186'
which may be a spring, rather than a pneumatic piston. The elastic element 186' is
configured for applying an opposing force, opposite to the direction of movement of
the supplementary tensioning element 195. This makes it possible to reduce the amount
of movement of the tensioning supplementary element 185 which would otherwise overload
the web.
[0101] In one embodiment, the line 1 comprises a tension sensor 19. The tension sensor 19
is configured for measuring the tension of the web. The tension sensor is configured
for generating tension signals 103, as a function of the tension value of the web.
[0102] In one embodiment, the tension sensor is configured for sending the tension signals
103 to the control unit 10.
[0103] In one embodiment, the control unit 10 is configured for generating the control signals
102 as a function of the tension signals 103.
[0104] The control unit is then configured for sending the control signals 102 to the actuator,
as a function of which the latter is configured for varying the position of the tensioning
element 181.
[0105] This embodiment makes it possible to obtain a feedback signal which allows it, if
there are errors or faults to the normal operation, to continue to work without irreparably
damaging the web.
[0106] According to an embodiment which is not in the scope of the invention, a method is
provided for packaging products in bags. The method comprises a feed step. In the
feed step, a reel 12A feeds a web (consisting of plastic material or of paper material)
to a feed unit 11.
[0107] In the feeding step it is also possible that the web is fed already in a separate
manner, that is to say, in the form of the portions already separated.
[0108] According to an embodiment which is not in the scope of the invention, the method
comprises a step of setting the line 1. The step of setting up the line 1 comprises
a step for receiving, in a control unit 10, working data 101, representing operating
parameters of the line 1.
[0109] The method comprises a step of feeding the web along a feed path, preferably belonging
to a plane perpendicular to the direction of the weight force.
[0110] In the feed step, a plurality of conveyors, for example a plurality of roller conveyors
110, moves the web along a plurality of stations of the packaging line 1.
[0111] In one embodiment, the web is fed to a folding station 13. In this folding station
13, the method comprises a step of folding the web along folding lines 131. The folding
lines 131 are preferably oriented parallel to the feed path P.
[0112] In the folding step, the web is folded to define a first and a second flap.
[0113] The web is then subsequently fed to a sealing station 14. In this sealing station
14, the method comprises a step of sealing the first and second flap of the web. More
specifically, in one embodiment, the sealing step comprises a transversal sealing
step, wherein the first and the second flap are sealed along transversal sealing lines
14A, perpendicular to the feed path P. In one embodiment, the sealing step comprises
a longitudinal sealing step, wherein the first and the second flaps are sealed along
longitudinal sealing lines 14B, parallel to the feed path P.
[0114] The sealing station 14 is characterised by a first productivity P1.
[0115] In one embodiment, the method comprises a step of cutting the web. In this cutting
step, the web is cut along transversal cut lines 151, to define a plurality of packaging
bags. The cutting station is characterised by a second productivity P2.
[0116] In one embodiment, the feed step comprises a first succession of forward movements
S1, carried out by a first motor-driven roller 11A. In one embodiment, the first motor-driven
roller 11A is located upstream of the sealing station 14. In one embodiment, the first
motor-driven roller 11A is located downstream of the sealing station 14.
[0117] In any case, the first motor-driven roller 11A feeds the web to the sealing station
14 feeding it by a first feed step, which is correlated with the first productivity
P1 of the sealing station (that is, the number of seals per unit time). In this first
succession of forward movements P1, the first motor-driven roller 11A unwinds the
web by a first feed length. In this first succession of forward movements P1, the
first motor-driven roller 11A rotates at a first speed of rotation for a first feed
time T1.
[0118] In one embodiment, the feed step comprises a second succession of forward movements
S2, carried out by a second motor-driven roller 11B. In one embodiment, the second
motor-driven roller 11B is located downstream or upstream of the sealing station 14.
In one embodiment, the second motor-driven roller 11B is located downstream of the
cutting station 15. In one embodiment, the second motor-driven roller 11B is located
upstream of the cutting station 15.
[0119] In any case, the second motor-driven roller 11B feeds the web to the cutting station
15 feeding it by a second feed step, which is correlated with the second productivity
P2 of the cutting station (that is, the number of cuts per unit time). In this second
succession of forward movements S2, the second motor-driven roller 11B unwinds the
web by a second feed length. In this second succession of forward movements S2, the
second motor-driven roller 11B rotates at a second speed of rotation for a second
feed time T2.
[0120] For this reason, the feed unit performs a first length of forward movement and a
second length of forward movement, different from each other. The difference in length
could cause a loss of tension and therefore a reduction in the quality of the bags.
[0121] In order to solve this problem, in one embodiment the method comprises a step for
adjusting the tension of the web. In this adjusting step, an adjustment unit 18 varies
the length of the feed path P for adjusting the tension of the web. In this adjusting
step, a tensioning element 181 moves along an adjustment direction R for varying the
length of the feed path P and keeping the tension of the web at an optimum value.
The adjustment step includes a step of controlled moving of the tensioning element
181. In this controlled movement step, the control unit 10 sends control signals 102
to an actuator 182 of the adjustment unit 18 for instructing it to move the tensioning
element 181. The control unit generates the control signals 102 as a function of the
working data 101.
[0122] In one embodiment, the actuator 182 moves the tensioning element 181 with a predetermined
speed profile.
[0123] In one embodiment, the variation of the feed path P per unit time due to the movement
of the tensioning element 181 must be equal to the difference between the first rotation
speed of the first motor-driven roller 11A and the second rotation speed of the second
motor-driven roller 11B per unit of time. For this reason, in one embodiment, the
speed profile depends on the first feed step and on the second feed step.
[0124] The drawings illustrate the first S1 and the second S2 succession of forward movements.
An embodiment of a cycle of the method is described below with reference to the drawings.
[0125] The first motor-driven roller 11A feeds the web of the first feed step, rotating
at the first rotation speed for a time equal to the first feed time T1.
[0126] The second motor-driven roller 11B feeds the web of the second feed step, rotating
at the second rotation speed for a time equal to the second feed time T2.
[0127] The first feed time T1 is greater than the second feed time T2, since the sealing
station is able to process simultaneously a greater number of units than the cutting
station. For example, but not necessarily, the sealing station may process four units
for each feed whilst the cutting station may processing two or a single unit for each
feed.
[0128] After the second feed time T2, the second motor-driven roller 11B stops whilst the
first motor-driven roller 11A is still in rotation. The cutting station 15 performs
the cutting step in a cutting time Tt. When the cutting station 15 performs the cutting
step, the second motor-driven roller continues to unwind the web, increasing the quantity
of web interposed between the first motor-driven roller 11A and the second motor-driven
roller 11B. To keep the web under tension, the adjustment unit 18 moves the tensioning
element 181 by means of the actuator 182, in such a way as to increase the length
of the feed path P. When the first motor-driven roller has rotated for a time equal
to the first feed time T1, the latter stops and starts the sealing step. At this instant,
that is to say, when the first motor-driven roller 11A stops, the feed path P has
a first length L1. In one embodiment, the first length L1 is the maximum length of
the feed path P.
[0129] The sealing station 14 performs the sealing step in a sealing time Ts.
[0130] During the sealing step, the second motor-driven roller 11B will continue the second
succession of forward movements S2 thus recalling the web and reducing the length
of the unwound web interposed between the first 11A and the second 11B motor-driven
rollers.
[0131] To keep the web under tension, the adjustment unit 18 moves the tensioning element
181 by means of the actuator 182 in such a way as to reduce the length of the feed
path P.
[0132] In one embodiment, at the end of the sealing step, the first motor-driven roller
11A remains stationary for a stationary time Tf, to allow the cutting station 14 to
cut a number of units equal to the number of units sealed. When the cutting station
15 has cut the units which the sealing station 14 has sealed, the length of the web
interposed between the first 11A and 11B motor-driven roller is at its minimum and
the feed path P has a second length L2. In one embodiment, the second length L2 is
the minimum length of the feed path P.
[0133] In one embodiment, the step of moving the tensioning element 181 includes a translation
step. In the translation step, a slide 183', connected to the tensioning element 181,
translates in a guide 183" along the adjustment direction R.
[0134] The translation, in one embodiment, is generated by a lead screw 182', connected
to and rotating with a drive shaft of the actuator (which in this example embodiment
is rotary).
[0135] The lead screw 182' is coupled with the slide 183' of the tensioning element 181
for transforming the rotary motion of the drive shaft into a translating motion of
the tensioning element 181.
[0136] In one embodiment, the method comprises a step of moving a supplementary tensioning
element 185. In one embodiment, the step of moving the supplementary tensioning element
185 includes a damping step. In this damping step, a damping member 186 dampens movement
of the supplementary tensioning unit 185 due to a variation of the web tension. More
specifically, an elastic element 186' of the damping member 186 applies an opposing
force, in the opposite direction to the direction of movement of the supplementary
tensioning element 185.
[0137] In one embodiment, the elastic element is a spring 186'. In this embodiment, a carriage
185' of the supplementary tensioning element 185 slides inside a rail 185" made on
a frame 180 of the adjustment unit 18. The sliding of the carriage 185' in the rail
185" is opposed by the action of the spring 186'.
[0138] In one embodiment, the method comprises a feedback control step. In this feedback
control step, a tension sensor 19 measures a tension value of the web and generates
corresponding tension signals 103, representing the tension value of the web. The
tension sensor 19 may be located upstream or downstream of the first and/or the second
motor-driven roller 11A, 11. In this feedback control step, the tension sensor 19
sends the tension signals 103 to the control unit. The control unit 10 generates corresponding
control signals 102, as a function of the tension signals 103. The control unit 10
sends the control signals 102 to the actuator 182 for controlling it during the movement
of the tensioning element 181.
| Number |
Feature |
| 1 |
line |
| 11 |
movement unit |
| 12 |
feed station |
| 12A |
coil |
| 10 |
control unit |
| 10' |
user interface |
| 101 |
working data |
| 110 |
plurality of feed rollers |
| P |
feed path |
| 11A |
first motor-driven roller |
| 11B |
second motor-driven roller |
| 131 |
Folding step |
| 13 |
folding station |
| 14 |
sealinq station |
| 14A |
transversal sealinq station |
| 14B |
lonqitudinal sealinq station |
| 141B |
longitudinal sealing lines |
| 141A |
transversal sealinq lines |
| 15 |
cutting station |
| 15' |
cutting tool |
| 151 |
cutting lines |
| 16 |
filling station |
| 161 |
filling carousel |
| 162 |
plurality of suction surfaces |
| 17 |
conveyor |
| 171 |
suction surface |
| 18 |
adjustment unit |
| 181 |
tensioning element |
| 182 |
actuator |
| R |
adjustment direction |
| 183' |
slide |
| 103 |
Tension signals |
| 19 |
Tension sensor |
| 183" |
guide |
| 182' |
lead screw |
| 185 |
Supplementary tensioning element |
| 185' |
carriage |
| 185" |
track |
| 186 |
damping member |
| 186' |
Elastic element |
| 180 |
Adjustment unit frame |
| 184 |
Plurality of fixed rollers |
| T1 |
First movement time |
| T2 |
Second movement time |
| Ts |
Sealing time |
| Tt |
Cutting time |
| S1 |
First succession of forward movements |
| S2 |
Second succession of forward movements |
| Tf |
stationary time |
1. A packaging line (1) for products in bags, comprising:
- a feed unit (11), configured to receive a web to from a reel (12A) and for moving
it along a feed path (P);
- a control unit (10), connected to the feed unit (11) for moving the web intermittently,
by a succession of forward movements of predetermined spacing;
- a folding station (13), configured for folding the web about a folding line (131)
oriented along the feed path (P), for superposing a first and a second flap of the
web;
- a sealing station (14), configured for sealing the first and second flap of the
folded web, along sealing lines (141A) oriented transversely to the folding line (131);
- a cutting station (15), configured for cutting the packaging web and defining a
plurality of packaging bags;
- a filling station (16), configured for filling with a product the plurality of packaging
bags;
- a sealing station, configured for sealing the plurality of packaging bags;
wherein the feed unit (11) includes
- a first motor-driven roller (11A), controlled by the control unit (10) for moving
the web through the folding (13) and sealing (14) stations, by a first succession
of forward movements (S1), with a first feed step;
- a second motor-driven roller (11B), controlled by the control unit (10) for moving
the web by a second succession of forward movements (S2) different to that of the
first succession of forward movements (S1), with a second feed step, the second motor-driven
roller (11B) being positioned downstream of the first motor-driven roller (11A), for
moving the web through the cutting station (15);
- an adjustment unit (18), positioned between the first (11A) and the second motor-driven
roller (11B) and configured for adjusting a tension of the web,
characterised in that the adjustment unit (18) includes:
- a tensioning element (181), movable between a first operating position (P1) operatively
in contact with the web, wherein the feed path (P) has a first length (L1), and a
second operating position (P2) operatively in contact with the web, wherein the feed
path (P) has a second length (L2) different from the first length (L1);
an actuator (182), connected to the tensioning element (181) for varying a position
of the tensioning element (181) between the said first and second operating positions
(P1, P2), so as to vary the length of the feed path (P), and wherein the control unit
(10) is configured for receiving working data (101), representing the first (S1) and
a second (S2) succession of forward movements, and for generating control signals
(102), for controlling the actuator (182) as a function of the working data (101).
2. The line (1) according to claim 1, wherein the actuator (182) is configured for moving
the tensioning element (181) according to a predetermined speed profile.
3. The line (1) according to claim 2, wherein the actuator (182) of the adjustment unit
(18) includes an electric motor.
4. The line (1) according to any one of the preceding claims, wherein the adjustment
unit (18) comprises a supplementary tensioning element (185), operatively in contact
with the web and movable in order to vary, as a function of a relative position, the
length of the feed path (P).
5. The line (1) according to claim 4, wherein the supplementary tensioning element (185)
is connected to a damping member (186).
6. The line (1) according to any one of the preceding claims, wherein the adjustment
unit (18) comprises a guide (183") and the tensioning element (181) includes an idle
roller and a slide (183'), configured for translating in the guide (183") of the adjustment
unit (18) and pulling the tensioning element (181) from the first (P1) to the second
(P2) operating position.
7. The line (1) according to any one of the preceding claims, wherein the tensioning
element (181) is oriented parallel to the direction of the weight force.
8. The line (1) according to any one of the preceding claims, comprising a tension sensor
(19), configured for measuring the tension of the web, and wherein the control unit
is configured for receiving tension signals (103), representing the tension of the
web, from the tension sensor (19), for generating control signals (102), as a function
of the tension signals (103), and for instructing the actuator (182), through the
control signals (102), for moving the tensioning element (181).
9. The line (1) according to any one of the preceding claims, wherein the first motor-driven
roller (11A) is located downstream of the sealing station (14) along the feed path
(P), and/or wherein the second motor-driven roller (11B) is positioned upstream of
the cutting station (15).
10. A method for packaging products in bags comprising the following steps:
- receiving the web from a reel (12A) and intermittent feeding of the web along a
feed path (P) using a succession of forward movements of predetermined spacing;
- folding the web around a folding line (131) oriented along the feed path (P), for
superposing a first and a second flap of the web;
- sealing the first and second flap of the web along sealing lines (141A) oriented
transversely to the folding line (131);
- cutting the packaging web to define a plurality of packaging bags;
- filling the plurality of packaging bags with the product;
- sealing the plurality of bags;
wherein the feeding step includes:
- first succession of forward movements (S1), with a first feed step, using a first
motor-driven roller (11A) arranged for moving the web through the folding and sealing
stations;
- second succession of forward movements (S2) different to that of the first succession
of forward movements (S1), with a second feed step, using a second motor-driven roller
(11B) arranged for moving the web thought the cutting station;
- adjusting the tension of the web by means of an adjustment unit (18) positioned,
on the packaging line, in an intermediate position between the first (11A) and the
second (11B) motor-driven roller along the feed path (P), characterized in that it comprises the following steps:
- controlled movement of a tensioning element (181), connected with the web, between
a first operating position (P1) and a second operating position (P2), by means of
an actuator (182) controlled by a control unit (10), for varying the length of the
feed path (P), wherein in the controlled movement step the control unit (10) receives
the working data (101), representing the first (S1) and a second (S2) successions
of forward movements, generates control signals (102) as a function of the working
data (101) and sends the control signals (102) to the actuator (182), for instructing
it to move tensioning element (181) so as to vary the length of the feed path (P).
11. The method according to claim 10, comprising a step of moving a supplementary tensioning
element (185), connected with the web, for varying, as a function of a position of
the supplementary tensioning element (185), the length of the feed path (P).
12. The method according to claim 11, wherein the step of moving the supplementary tensioning
element (185) includes a damping step absorbing, wherein a damping member (186) applies
an opposing force, opposite to the direction of a movement of the supplementary tensioning
element (185).
1. Verpackungsstraße (1) für Produkte in Beuteln, umfassend:
- eine Speiseeinheit (11), welche dazu ausgebildet ist, eine Bahn aus einer Spule
(12A) zu empfangen und sie entlang eines Speiseweges (P) zu bewegen;
- eine Steuereinheit (10), welche mit der Speiseeinheit (11) verbunden ist, um die
Bahn, mittels einer Reihenfolge von Vorwärtsbewegungen mit vorbestimmtem Abstand,
intermittierend zu bewegen;
- eine Faltstation (13), welche dazu ausgebildet ist, die Bahn über eine Faltlinie
(131), welche entlang des Speiseweges (P) orientiert ist, zu falten, um eine erste
und eine zweite Klappe der Bahn zu überlagern;
- eine Siegelstation (14), welche dazu ausgebildet ist, die erste und die zweite Klappe
der gefalteten Bahn entlang Siegellinien (14A), welche quer zur Faltlinie (131) orientiert
sind, zu siegeln;
- eine Schneidestation (15), welche dazu ausgebildet ist, die Verpackungsbahn zu schneiden
und eine Vielzahl von Verpackungsbeuteln zu definieren;
- eine Füllstation (16), welche dazu ausgebildet ist, die Vielzahl von Verpackungsbeuteln
mit einem Produkt zu füllen;
- eine Siegelstation, welche dazu ausgebildet ist, die Vielzahl von Verpackungsbeuteln
zu siegeln;
wobei die Speiseeinheit (11) Folgendes beinhaltet
- eine erste motorgetriebene Rolle (11A), welche von der Steuereinheit (10) gesteuert
wird, um die Bahn durch die Faltstation (13) und die Siegelstation (14) zu bewegen,
mittels einer ersten Reihenfolge von Vorwärtsbewegungen (S1), mit einem ersten Speiseschritt;
- eine zweite motorgetriebene Rolle (11B), welche von der Steuereinheit (10) gesteuert
wird, um die Bahn mittels einer zweiten Reihenfolge von Vorwärtsbewegungen (S2), welche
unterschiedlich von der ersten Reihenfolge von Vorwärtsbewegungen (S1) ist, mit einem
zweiten Speiseschritt zu bewegen, wobei die zweite motorgetriebene Rolle (11B) stromabwärts
der ersten motorgetriebenen Rolle (11A) platziert ist, um die Bahn durch die Schneidestation
(15) zu bewegen;
- eine Einstelleinheit (18), welche zwischen der ersten (11A) und der zweiten motorgetriebenen
Rolle (11B) platziert ist und welche dazu ausgebildet ist, eine Spannung der Bahn
einzustellen,
dadurch gekennzeichnet, dass die Einstelleinheit (18) Folgendes beinhaltet:
- ein Spannelement (181), welches zwischen einer ersten Betriebsstellung (P1) betriebsfähig
in Kontakt mit der Bahn, in welcher der Speiseweg (P) eine erste Länge (L1) aufweist,
und einer zweiten Betriebsstellung (P2) betriebsfähig in Kontakt mit der Bahn, in
welcher der Speiseweg (P) eine zweite Länge (L2) aufweist, welche unterschiedlich
von der ersten Länge (L1) ist, beweglich ist;
ein Stellglied (182), welches mit dem Spannelement (181) verbunden ist, um eine Stellung
des Spannelements (181) zwischen der genannten ersten und der genannten zweiten Betriebsstellung
(P1, P2) zu variieren, um die Länge des Speiseweges (P) zu variieren, und wobei die
Steuereinheit (10) dazu ausgebildet ist, Arbeitsdaten (101), welche die erste (S1)
und eine zweite Reihenfolge von Vorwärtsbewegungen (S2) darstellen, zu empfangen und
Steuersignale (102), zum Steuern des Stellgliedes (182) in Abhängigkeit von den Arbeitsdaten
(101), zu erzeugen.
2. Straße (1) nach Anspruch 1, wobei das Stellglied (182) dazu ausgebildet ist, das Spannelement
(181) gemäß einem vorbestimmten Geschwindigkeitsprofil zu bewegen.
3. Straße (1) nach Anspruch 2, wobei das Stellglied (182) der Einstelleinheit (18) einen
Elektromotor beinhaltet.
4. Straße (1) nach einem der vorhergehenden Ansprüche, wobei die Einstelleinheit (18)
ein supplementäres Spannelement (185) umfasst, betriebsfähig in Kontakt mit der Bahn
und beweglich, um, in Abhängigkeit von einer relativen Stellung, die Länge des Speiseweges
(P) zu variieren.
5. Straße (1) nach Anspruch 4, wobei das supplementäre Spannelement (185) mit einem Dämpfungsglied
(186) verbunden ist.
6. Straße (1) nach einem der vorhergehenden Ansprüche, wobei die Einstelleinheit (18)
eine Führung (183") umfasst und das Spannelement (181) eine leerlaufende Rolle und
einen Schlitten (183') beinhaltet, welche dazu ausgebildet sind, sich in der Führung
(183") der Einstelleinheit (18) zu versetzen und das Spannelement (181) von der ersten
(P1) zur zweiten Betriebsstellung (P2) zu ziehen.
7. Straße (1) nach einem der vorhergehenden Ansprüche, wobei das Spannelement (181) parallel
zur Richtung der Gewichtskraft orientiert ist.
8. Straße (1) nach einem der vorhergehenden Ansprüche, umfassend einen Spannungssensor
(19), welcher dazu ausgebildet ist, die Spannung der Bahn zu messen, und wobei die
Steuereinheit dazu ausgebildet ist, Spannungssignale (103), welche die Spannung der
Bahn darstellen, vom Spannungssensor (19) zu empfangen, Steuersignale (102), in Abhängigkeit
von den Spannungssignalen (103), zu erzeugen und das Stellglied (182) über die Steuersignale
(102) dazu anzuweisen, das Spannelement (181) zu bewegen.
9. Straße (1) nach einem der vorhergehenden Ansprüche, wobei die erste motorgetriebene
Rolle (11A) sich stromabwärts der Siegelstation (14) entlang des Speiseweges (P) befindet,
und/oder wobei die zweite motorgetriebene Rolle (11B) stromaufwärts der Schneidestation
(15) platziert ist.
10. Verfahren zum Verpacken von Produkten in Beuteln, umfassend die folgenden Schritte:
- das Empfangen der Bahn aus einer Spule (12A) und das intermittierende Speisen der
Bahn entlang eines Speiseweges (P) unter Verwendung einer Reihenfolge von Vorwärtsbewegungen
mit vorbestimmtem Abstand;
- das Falten der Bahn um eine Faltlinie (131) herum, welche entlang des Speiseweges
(P) orientiert ist, um eine erste und eine zweite Klappe der Bahn zu überlagern;
- das Siegeln der ersten und der zweiten Klappe der Bahn entlang Siegellinien (14A),
welche quer zur Faltlinie (131) orientiert sind;
- das Schneiden der Verpackungsbahn, um eine Vielzahl von Verpackungsbeuteln zu definieren;
- das Füllen der Vielzahl von Verpackungsbeuteln mit dem Produkt;
- das Siegeln der Vielzahl von Beuteln;
wobei der Speiseschritt Folgendes umfasst:
- eine erste Reihenfolge von Vorwärtsbewegungen (S1), mit einem ersten Speiseschritt,
unter Verwendung einer ersten motorgetriebenen Rolle (11A), welche dazu angeordnet
ist, die Bahn durch die Falt- und Siegelstation zu bewegen;
- eine zweite Reihenfolge von Vorwärtsbewegungen (S2), welche unterschiedlich von
der ersten Reihenfolge von Vorwärtsbewegungen (S1) ist, mit einem zweiten Speiseschritt,
unter Verwendung einer zweiten motorgetriebenen Rolle (11B), welche dazu angeordnet
ist, die Bahn durch die Schneidestation zu bewegen;
- das Einstellen der Spannung der Bahn mittels einer Einstelleinheit (18), welche,
auf der Verpackungsstraße, in einer Zwischenstellung zwischen der ersten (11A) und
der zweiten motogetriebenen Rolle (11B) entlang des Speiseweges (P) platziert ist,
dadurch gekennzeichnet, dass es die folgenden Schritte umfasst:
- das gesteuerte Bewegen eines Spannelements (181), welches mit der Bahn, zwischen
einer ersten Betriebsstellung (P1) und einer zweiten Betriebsstellung (P2), mittels
eines Stellgliedes (182), welches von einer Steuereinheit (10) gesteuert wird, um
die Länge des Speiseweges (P) zu variieren, verbunden ist, wobei im Schritt des gesteuerten
Bewegens die Steuereinheit (10) die Arbeitsdaten (101), welche die erste (S1) und
eine zweite Reihenfolge von Vorwärtsbewegungen (S2) darstellen, empfängt, Steuersignale
(102) in Abhängigkeit von den Arbeitsdaten (101) erzeugt und die Steuersignale (102)
zum Stellglied (182) sendet, um es anzuweisen das Spannelement (181) zu bewegen, um
die Länge des Speiseweges (P) zu variieren.
11. Verfahren nach Anspruch 10, umfassend einen Schritt des Bewegens eines supplementären
Spannelements (185), welches mit der Bahn verbunden ist, um, in Abhängigkeit von einer
Stellung des supplementären Spannelements (185), die Länge des Speiseweges (P) zu
variieren.
12. Verfahren nach Anspruch 11, wobei der Schritt des Bewegens des supplementären Spannelements
(185) einen Dämpfungsschritt beinhaltet, wobei ein Dämpfungsglied (186) eine Gegenkraft
aufbringt, welche zur Richtung einer Bewegung des supplementären Spannelements (185)
entgegengesetzt ist.
1. Ligne d'emballage (1) pour produits dans des sacs, qui comprend:
- une unité d'alimentation (11), configurée pour recevoir une bande pour former une
bobine (12A) et pour la déplacer au long d'un trajet d'alimentation (P);
- une unité de contrôle (10), connectée à l'unité d'alimentation (11) pour déplacer
la bande de manière intermittente, au moyen d'une succession de mouvements d'avancée
à séparation prédéterminée;
- une station de pliage (13), configurée pour plier la bande autour d'une ligne de
pliage (131) orientée au long du trajet d'alimentation (P), pour superposer des rabats
premier et deuxième de la bande;
- une station de scellage (14), configurée pour sceller les rabats premier et deuxième
de la bande pliée, au long de lignes de scellage (141A) orientées de manière transversale
à la ligne de pliage (131);
- une station de coupe (15), configurée pour couper la bande d'emballage et définir
une pluralité de sacs d'emballage;
- une station de remplissage (16), configurée pour remplir avec un produit la pluralité
de sacs d'emballage;
- une station de scellage, configurée pour sceller la pluralité de sacs d'emballage;
dans laquelle l'unité d'alimentation (11) comprend
- un premier rouleau actionné par moteur (11A), contrôlé par l'unité de contrôle (10)
pour déplacer la bande à travers les stations de pliage (13) et de scellage (14),
au moyen d'une première succession de mouvements d'avancée (S1), avec une première
étape d'alimentation;
- un deuxième rouleau actionné par moteur (11B), contrôlé par l'unité de contrôle
(10) pour déplacer la bande au moyen d'une deuxième succession de mouvements d'avancée
(S2) différents de ceux de la première succession de mouvements d'avancée (S1), avec
une deuxième étape d'alimentation, le deuxième rouleau actionné par moteur (11B) étant
positionné en aval du premier rouleau actionné par moteur (11A), pour déplacer la
bande à travers la station de coupe (15);
- une unité d'ajustement (18), positionnée entre les rouleaux actionnés par moteur
premier (11A) et deuxième (11B) et configurée pour ajuster une tension de la bande,
caractérisée en ce que l'unité d'ajustement (18) comprend:
- un élément de tension (181), mobile entre une première position opérationnelle (P1)
en contact opérationnel avec la bande, dans laquelle le trajet d'alimentation (P)
a une première longueur (L1), et une deuxième position opérationnelle (P2) en contact
opérationnel avec la bande, dans laquelle le trajet d'alimentation (P) a une deuxième
longueur (L2) différente de la première longueur (L1);
un actionneur (182) connecté à l'élément de tension (181) pour faire varier une position
de l'élément de tension (181) entre lesdites positions opérationnelles première et
deuxième (P1, P2), de façon que l'on fait varier la longueur du trajet d'alimentation
(P), et dans laquelle l'unité de contrôle (10) est configurée pour recevoir des données
de travail (101) qui représentent les successions de mouvements d'avancée première
(S1) et deuxième (S2) et pour générer des signaux de contrôle (102) pour contrôler
l'actionneur (182) en fonction des données de travail (101).
2. Ligne (1) selon la revendication 1, dans laquelle l'actionneur (182) est configuré
pour déplacer l'élément de tension (181) selon un profil de vitesse prédéterminé.
3. Ligne (1) selon la revendication 2, dans laquelle l'actionneur (182) de l'unité d'ajustement
(18) comprend un moteur électrique.
4. Ligne (1) selon l'une quelconque des revendications précédentes, dans laquelle l'unité
d'ajustement (18) comprend un élément de tension (185) complémentaire, en contact
opérationnel avec la bande et mobile dans le but de faire varier, en fonction d'une
position relative, la longueur du trajet d'alimentation (P).
5. Ligne (1) selon la revendication 4, dans laquelle l'élément de tension (185) complémentaire
est connecté à un élément d'amortissement (186).
6. Ligne (1) selon l'une quelconque des revendications précédentes, dans laquelle l'unité
d'ajustement (18) comprend un guide (183") et l'élément de tension (181) comprend
un rouleau fou et un élément de glissement (183'), configurés pour se déplacer dans
le guide (183") de l'unité d'ajustement (18) et tirer l'élément de tension (181) depuis
la première position opérationnelle (P1) jusqu'à la deuxième position opérationnelle
(P2).
7. Ligne (1) selon l'une quelconque des revendications précédentes, dans laquelle l'élément
de tension (181) est orienté en parallèle à la direction de la force du poids.
8. Ligne (1) selon l'une quelconque des revendications précédentes, qui comprend un capteur
de tension (19), configuré pour mesurer la tension de la bande, et dans laquelle l'unité
de contrôle est configurée pour recevoir des signaux de tension (103), qui représentent
la tension de la bande, à partir du capteur de tension (19), pour générer des signaux
de contrôle (102), en fonction des signaux de tension (103), et pour indiquer à l'actionneur
(182), à travers les signaux de contrôle (102), qu'il déplace l'élément de tension
(181).
9. Ligne (1) selon l'une quelconque des revendications précédentes, dans laquelle le
premier rouleau actionné par moteur (11A) est situé en aval de la station de scellage
(14) au long du trajet d'alimentation (P) et/ou dans laquelle le deuxième rouleau
actionné par moteur (11B) est positionné en amont de la station de coupe (15).
10. Méthode pour emballer des produits dans des sacs qui comprend les étapes suivantes:
- recevoir la bande à partir d'une bobine (12A) et alimenter de manière intermittente
la bande au long d'un trajet d'alimentation (P) en utilisant une succession de mouvements
d'avancée à séparation prédéterminée;
- plier la bande autour d'une ligne de pliage (131) orientée au long du trajet d'alimentation
(P) pour superposer des rabats premier et deuxième de la bande;
- sceller les rabats premier et deuxième de la bande au long de lignes de scellage
(141A) orientées de manière transversale à la ligne de pliage (131);
- couper la bande d'emballage pour définir une pluralité de sacs d'emballage;
- remplir la pluralité de sacs d'emballage avec le produit;
- sceller la pluralité de sacs;
dans laquelle l'étape d'alimentation comprend:
- une première succession de mouvements d'avancée (S1), avec une première étape d'alimentation,
utilisant un premier rouleau actionné par moteur (11A) disposé pour déplacer la bande
à travers les stations de pliage et de scellage ;
- une deuxième succession de mouvements d'avancée (S2) différents de ceux de la première
succession de mouvements d'avancée (S1), avec une deuxième étape d'alimentation, utilisant
un deuxième rouleau actionné par moteur (11B) disposé pour déplacer la bande à travers
la station de coupe ;
- ajuster la tension de la bande au moyen d'une unité d'ajustement (18) positionnée,
sur la ligne d'emballage, dans une position intermédiaire entre les rouleaux actionnés
par moteur premier (11A) et deuxième (11B) au long du trajet d'alimentation (P),
caractérisée en ce qu'elle comprend les étapes suivantes:
- mouvement contrôlé d'un élément de tension (181), connecté avec la bande, entre
une première position opérationnelle (P1) et une deuxième position opérationnelle
(P2), au moyen d'un actionneur (182) contrôlé par une unité de contrôle (10), pour
faire varier la longueur du trajet d'alimentation (P), dans laquelle, dans l'étape
de mouvement contrôlé, l'unité de contrôle (10) reçoit les données de travail (101)
qui représentent les successions de mouvements d'avancée première (S1) et deuxième
(S2), génère des signaux de contrôle (102) en fonction des données de travail (101)
et envoie les signaux de contrôle (102) à l'actionneur (182) pour lui indiquer qu'il
déplace l'élément de tension (181) de sorte à faire varier la longueur du trajet d'alimentation
(P).
11. Méthode selon la revendication 10, qui comprend une étape de déplacement d'un élément
de tension (185) complémentaire, connecté avec la bande, pour faire varier, en fonction
d'une position de l'élément de tension (185) complémentaire, la longueur du trajet
d'alimentation (P).
12. Méthode selon la revendication 11, dans laquelle l'étape de déplacement de l'élément
de tension (185) complémentaire comprend une absorption par étape d'amortissement,
dans laquelle un élément d'amortissement (186) applique une force d'opposition, opposée
au sens d'un mouvement de l'élément de tension (185) complémentaire.