EP1298064A1 - Process and device for decorating cylindrical packings - Google Patents

Abstract

In a procedure for continuously decorating packages (5) with curved surfaces, each package has a self-rotation superimposed on the transport path(4). The decoration is on a carrier path (7) moving with constant speed tangential to the transport path. The decoration is applied to the packages under pressure and with heat applied to the carrier path, the packages being subject to subsequent heat treatment from a stationary controlled source. <??>The transport and carrier path directions are opposed. The package spacing has the same ratio to the transport speed as the decoration spacing has to the carrier speed. The packages are accelerated in their self-rotation to match the carrier speed.

Description

The invention relates to a continuous process in which the containers with a superimposed self-rotation on a transport path and the decorations on a carrier path are moved at constant speeds and tangentially past a transfer location, where the decorations are successively transferred to the containers under pressure and heat ,
The invention further relates to a corresponding device, which consists of a drivable endless transport path with uniformly spaced, drivable and rotating receiving means for the containers, a drivable endless carrier path with uniformly spaced decorations and a contact area between the transport path and the carrier path designed as a transfer location exists, wherein means for exerting pressure and means for heating the decoration are arranged in the area of the transfer location.
Such methods and devices are used, inter alia, in the food and beverage industry for decorating containers made of paper, plastic, glass or metal.

For various reasons, the thermal transfer process is becoming more popular than others, for example the labeling process, for decorating containers in the manner mentioned at the beginning.
The decorative motif is printed on a carrier web by means of known printing technology in such a way that it is bonded to the carrier web by an adhesive with a lower adhesive force and is coated with another adhesive with a higher adhesive force. A carrier web produced in this way is brought into contact with the containers to be decorated. Pressure and heat in this contact area detach the decor from the carrier web and connect it to the container at the same time. The heat is supplied via the container.
This method can therefore only be used for containers with a high heat capacity, for example glass bottles.
A continuous process and a device for this, in which the thermal transfer process can also be used in containers with low heat capacity, for example plastic containers, are described in DE 44 37 379.1. In this case, the carrier web is separated into individual sections each bearing a print motif and transferred to heated order segments which are arranged at equal intervals on an order conveyor. This order funding temporarily takes over the containers in such a way that a container is assigned to each order segment. The decor is then transferred from the individual section to the container during transport. However, due to a large number of individual operations, this method requires a high level of equipment complexity. Furthermore, there are problems in coordinating the many individual movements of the screw conveyors for the containers, of the application conveyor for the containers and the order segments, of the order segments, of the containers, of the endless conveyor for the decorations and of the cutting unit. This coordination of the individual movements is only possible through complex gear and curve control or can only be realized through appropriate electrical gear.
In addition, the handling of the individual label sections represents a performance limitation of the machine. It is particularly disadvantageous that it is not possible to introduce heat energy into the label material depending on the machine speed. This severely limits the machine's variable performance range, which has an adverse effect on an overall production line. At low speeds there is also a risk of thermal damage to the label material and thin-walled plastic containers.

The containers printed using the thermal transfer process generally require further heat treatment, so that the color image is given a higher gloss, the colors are dried and the adhesion of the surface is improved.
For this purpose, DE 44 27 870.5 describes how to transport the freshly printed structures with the still moist printed image to a separate oven using a separate removal means.
It is also part of the general state of the art to use an open flame in conjunction with a rotation of the container instead of the furnace. However, an open flame places very high demands on the device technology and, on top of that, does not permit use in plastic containers because of the risk of deformation.

There is therefore the task of a procedure and a To create device of the present genus, the with large variable power range and easier Technology works.

On the procedural side, this problem is solved in that the movements of the transport path and the carrier path are opposed are, the distance between the containers on the transport track at the speed of the transport track behaves exactly like the distance between the decorations on the Carrier web at the speed of the carrier web. Farther the container in the area of the transfer location brought a peripheral speed that the speed corresponds to the carrier web and the necessary Heat is supplied to the carrier web.

The particular advantage of the invention lies in the extremely high peripheral speed of the containers. As is known, this speed results from the sum of the two speeds of the transport path and the carrier path, but in this case by an addition under the same sign.
The high peripheral speed enables a continuous process since the distances between the containers on the transport path and the distances between the decorations on the carrier path are now independent of one another. It is no longer necessary to cut into individual sections of the carrier web.
The minimal contact time also prevents temperature transfer from the carrier web into the container, which is particularly advantageous for plastic containers. In addition, the two temperature-dependent layers of adhesive on the carrier web remain unaffected.

It is particularly useful if the containers are not separate, but driven by the movement of the carrier web become. This eliminates the otherwise necessary coordination the movements of the container and carrier web. It is advantageous if next to the container to be decorated at the same time that behind it in the direction of movement Container is driven by the carrier web. This enables the container behind Acceleration phase and thus avoids a speed difference between container and carrier web during of the transfer.

It is also beneficial if the necessary heat is supplied before or at the transfer location. there can be in the immediate vicinity of the transmission location it is best to dose the heat supply and the loss Heat can be calculated more precisely.

It is particularly favorable if the heating time is based on the speed of the carrier web and if this regulation takes place automatically.
This has a positive effect on the heat flow and thus on the quality of eds decor transfers.

It is of particular advantage if the containers with the fresh decorations a heat treatment device happen to get a higher color gloss. It is cheap the existing transport track exploit and the containers on a stationary and temperature-controlled heat source.

The object of the invention is thereby device-side solved that the drive means for the transport track and the carrier web for opposing each other Directions of movement are designed and a guide element for the carrier web for the application of pressure and the Heat transfer is formed. The guide element is thereby movable transversely to the direction of movement of the carrier web and biased and designed as a heating element.

It is favorable to freely rotate the receptacles for the containers to execute and to decorate or to decorating and the subsequent packaging by the To drive the carrier web.

But it is also possible. a separate conventional Drive to use. Thereby are means of realization use the same peripheral speeds. It is also possible to combine both drive options. In this way, a speed is achieved via the separate drive on the container smaller than the required Speed generated and the missing differential speed realized by the carrier web. Is to the separate drive with an additional freewheel equip.

In an expedient embodiment, a movable heating element is connected upstream of the guide element for the carrier web. By changing the position of the heating element, the contact area between the heating element and the carrier web can be varied continuously from zero to maximum. The heating time can thus be adapted to the speed of the carrier web in an advantageous manner.
The convex design of the guide surface of the heating element increases the contact ability and improves the heat transfer.
It is expedient to make the heating element pivotable.

It is also advantageous to have the heating element stationary to be carried out and in operative connection with a swivel arm perform. This swivel arm has a deflection roller for the carrier web with which the contact surface of the radiator is changeable with the carrier web.

The heating element or the swivel arm can have its own actuator or can be driven by its own weight if appropriately suspended.
The corresponding regulation can take place automatically.

It is also possible to design the heating element in two parts. The movable heating element takes on the task of a preheater and the print head that of the actual one Heating element.

Special care is taken on a selected heat treatment the decorations to match the colors to give a high degree of gloss and adhesion to the To improve underground. These requirements will be a stationary and electrically operated hot plate or a stationary hot air shower to a high degree. With both facilities will be advantageous Way for the existing transport track of the carousel used the transport of the containers. With the length of the effective heat surface and the speed of the transport track the time of the heat treatment can be clear be determined.

The invention is based on an embodiment are explained in more detail.

Fig. 1:

eine schematische Draufsicht auf die Vorrichtung zum Dekorieren,

Fig. 2:

eine zweckmäßige Ausführung für den Antrieb der Gebinde durch die Trägerbahn,

Fig. 3:

eine zweckmäßige Ausführung für die Heizeinrichtung der Trägerbahn,

Fig. 4:

eine Wärmenachbehandlungseinrichtung und

Fig. 5:

eine andere Wärmenachbehandlungseinrichtung.

Show this

Fig. 1:

1 shows a schematic top view of the device for decorating,

Fig. 2:

an appropriate design for driving the containers through the carrier web,

Fig. 3:

a suitable design for the heating device of the carrier web,

Fig. 4:

a heat treatment device and

Fig. 5:

another heat treatment device.

The device for decorating mainly consists of a transport device for the containers and a transport device for the decorations, both of which have a common interface for the transfer of the decorations to the containers.
For this purpose, according to FIG. Transport device for containers designed as a rotatable carousel 1. The. Carousel 1 has a drive (not shown), an input station 2, an output station 3 and a transport path 4 for the containers 5. On the transport path 4, receiving means 6 for the containers 5 to be decorated are arranged at equal intervals. These receiving means 6 are designed to rotate freely.
The transport device for the decorations consists of a carrier web 7, which is pulled by a drive, not shown, and corresponding guide elements for this carrier web 7. The carrier web 7 is designed in a known manner and carries decorations arranged at equal intervals by means of an adhesive with less adhesive force. The surfaces of the decorations are covered with another adhesive with greater adhesive strength.
The guide elements consist of at least one deflection roller 8, a pivotable heating element 9 and a print head 10 which can be displaced in the direction of the container 5. The pivotable heating element 9 has an outer guide surface 12, which is expediently convex and has an upper pivot point. The heating element 9 can be pivoted about this pivot point by a drive of a conventional type in the direction transverse to the direction of movement of the carrier web 7. This results in a contact surface which is different in size and is dependent on the swivel angle, between the guide surface 12 and the carrier web 7. The print head 10 also has an outer, preferably flat guide surface 11 and is driven in the direction of the carousel 1 by a prestressed compression spring or by another conventional drive system. The transport path 4 for the packs 5 and the carrier path 7 for the decorations touch each other in the area of the print head 10, the movements of the transport path 4 and the carrier path 7 being opposite. Thus, in this area there is direct contact between the carrier web 7 and the containers 5 and thus also with the freely rotatable receiving means 6.

As shown in Fig. 2, in a special way Direction of movement of the carrier web 7 after the print head 10 a deflection roller 13 may be arranged. Here lies the Location of the deflection roller 13 outside the transport path 4 at a distance from the printhead 10 that is greater than the distance of the container 5, which makes it to contact the Carrier web 7 freed from the decor and the next container 5 is coming.

3, the guide element for the carrier web 7 consists of the print head 10 'and the heating element 9'. Both are fixed to each other. The print head 10 'has an outer guide surface 11', a mechanical presetting device 14 and a pneumatic drive 15.
The heating element 9 'is equipped with an outer, convex guide surface 12' and has an operative connection with a swivel arm 16. This swivel arm 16 is equipped on its head with a deflection roller 17 and with a spacer roller 18. The swivel arm 16 also has a drive, not shown, with which the position of the deflection roller 17 relative to the heating element 9 'can be changed. This position is set as a function of the speed of the carrier web 7 and determines the size of the contact area between the heating element 9 'and the carrier web 7. At a slow speed, the deflection roller 17 positions itself closer and at a fast speed further from the print head 10'. The spacer roller 18 keeps the carrier web 7 away from the heating element 9 'in the region in front of the deflection roller 17.
The carrier web 7 'shows the state when the roll with the carrier web 7 has run off.

4 consists of a fixed and electrically operated heating plate 19 and a controller 20 that can be set to a setpoint temperature. The heating plate 19 can be equipped with a flat or with a concave heating surface 21, which should depend on whether the Transport direction of the container 5 describes a linear or a circular path. If, for example, the transport path 4 of the carousel 1 is also used for the heat treatment of the containers 5, a concave heating surface 21 is advantageous. With the correct choice of the shape of the heat surface 21, a specific heat treatment time can be defined over the length of the heat surface 21.
As a drive for the rotation of the containers 5, the friction that occurs between the moving containers 5 and the stationary heating plate is preferably used again.

5 mainly consists of a nozzle head 22, a temperature-controlled hot air generator 23, a quantity-controlled bypass valve 24 and a temperature and quantity regulator 25.
The containers 5 are again on a linear or circular path. A separate drive is required for the rotation of the containers 5.

The setpoint of the temperature for the controller 20 or for the temperature and quantity controller 25 is taken into account to specify the material of the container 5. container 5 made of plastic therefore require a special one Attention. To avoid undesirable deformations it may be appropriate to use container 5 made of plastic additionally with injected compressed air stabilize.

The operation of the device is explained with reference to FIG. 1.
The carousel 1 and the carrier web 7 are driven at desired but constant speeds. The movements are oriented in opposite directions. The containers 5 placed on the receiving means 6 by the input station 2 are transported on the transport path 4 in the direction of the print head 10. At the same time, the decorations heated on the heating element 9 to the necessary temperature on the carrier web 7 move in the opposite direction towards the print head 10.
The contact that occurs between each container 5 and the carrier web 7 in the region of the print head 10 results in the rotation of the container 5 that can freely rotate on the receiving means 6. A peripheral speed of the size of the speed of the carrier web arises on the container 5 7 a. The container 5 rolls on the carrier web 7 under the pressure emanating from the print head 10. The decor detaches from the carrier web and adheres to the container 5.
The containers 5 then pass through one of the heat treatment devices.

List of reference numbers

1

carousel

2

input station

3

output station

4

transport path

5

container

6

receiving means

7, 7 '

support web

8th

idler pulley

9, 9 '

heating element

10, 10 '

printhead

11, 11 '

Guide surface of the print head

12, 12 '

Guide surface of the heating element

13

idler pulley

14

presetting

15

pneumatic drive

16

swivel arm

17

idler pulley

18

spacer roll

19

hotplate

20

regulator

21

heating surface

22

nozzle head

23

Hot air generator

24

bypass valve

25

Temperature and volume controller

Claims (28)

Process for the continuous decoration of containers with curved surfaces, in which the containers (5) are fed in a rotatable manner on a transport path means (4) and the decorations on a carrier path (7, 7 '), which extends from a supply roll to a winding device, tangentially be moved past a transfer location, the decorations being transferred successively using heat and / or pressure, the method comprising the steps of: Rotating the packs (5) at a peripheral speed which corresponds to the speed of the carrier web (7, 7 ') in the region of the transfer location, and Moving the transport path (4) and the carrier path (7, 7 ') in opposite directions. Method according to claim 1,
characterized in that the carrier web (7, 7 ') has image-transmitting decorations. Method according to at least one of claims 1 or 2,
characterized in that the ratio of the distance between the packs on the transport path (4) to the speed of the transport path (4) behaves in exactly the same way as the ratio of the distance between the decorations on the carrier path (7, 7 ') to the speed of the carrier path (7, 7 '). Method according to at least one of the preceding claims,
characterized in that the containers (5) in the area of the transfer location with a superimposed self-rotation on the transport path (4) and the decorations on the carrier web (7, 7 ') are moved at constant speeds past the transfer location, where the decorations on the containers be transmitted; the carrier web (7, 7 ') is pulled from the supply roll in a pulling manner; in the area of the transfer location, the movement of the sections of the transport path (4) and the carrier path (7, 7 ') are opposite and the movements of the containers (5) and the carrier path (7, 7') are the same direction; and the necessary heat is applied to the carrier web (7, 7 '). Method according to at least one of the preceding claims,
characterized in that the drive for the rotation of the containers (5) is effected by the movement of the carrier web (7, 7 '). Method according to claim 5,
characterized in that each container (5) is accelerated by the carrier web (7, 7 ') before the point of transmission. Method according to at least one of the preceding claims,
characterized in that the necessary heat is fed into the carrier web (7, 7 ') before or at the point of transmission. Method according to claim 7,
characterized in that the heating time of the carrier web (7, 7 ') depends on the speed of the carrier web (7, 7'). A method according to claim 8,
characterized in that the heating time of the carrier web (7, 7 ') is regulated automatically. Method according to at least one of the preceding claims,
characterized in that the plastic containers (5) are stabilized by blown compressed air. A device for continuously decorating containers with curved surfaces, which comprises: a drivable transport path (4) with evenly spaced rotatable receiving means (6) for the containers (5), a storage roll and a winding device and drive means for operating at least the roll and / or the device for feeding a continuous carrier web (7, 7 ') of uniformly spaced decorations past a contact area, the contact area forming a transfer location, Means for exerting pressure on the decorations on the carrier web (7, 7 ') in the direction of the containers (5), the drive means for the transport web (4) and the storage roller and the winding device for opposite directions of movement of the carrier web (7, 7') ) and the transport path (4) are formed on the contact area. Device according to claim 11,
characterized in that the means for exerting pressure is formed by a guide element which is movable transversely to the direction of movement of the carrier web (7, 7 '). Device according to at least one of claims 11 or 12,
characterized in that the receiving means (6) for the packs (5) can be driven; the contact area between the transport path (4) and the carrier path (7, 7 ') is formed; the means for exerting pressure are arranged in the area of the transfer location and in front of or at the transfer location means for heating the decorations; the carrier web (7, 7 ') can be unrolled and pulled off the roll; the drive means for the transport path (4) and the carrier path (7, 7 ') are designed for opposite directions of movement of the sections of the transport path (4) and the carrier path (7, 7') located at the point of transmission; the drive means for the containers (5) are designed for a direction of movement in the same direction as the carrier web (7, 7 '), and the means for exerting pressure and means for heating are designed as guide elements. Device according to claim 13,
characterized in that the guide element is movable and biased transversely to the direction of movement of the carrier web (7, 7 ') and is designed as a heating element. Device according to at least one of claims 11 to 14,
characterized in that the receiving means (6) for the containers (5) are designed to rotate freely and each receiving means (6) can be driven by the carrier web (7, 7 ') via the container (5). Device according to claim 15,
characterized in that the carrier web (7, 7 ') is guided such that it is in contact with at least one further container (5) with an area freed from the decor. Device according to at least one of claims 11 to 16,
characterized in that the receiving means (6) for the containers (5) have a separate drive. Device according to at least one of claims 11 to 17,
characterized in that the receiving means (6) have a separate drive for a speed lower than the required and the required speed is generated by the contact of the container (5) with the carrier web (7, 7 '). Device according to at least one of claims 13 or 14,
characterized in that the guide element is preceded by a movable heating element (9, 9 ') with a contact surface, the size of the contact surface between the heating element (9, 9') and the carrier web (7, 7 ') being continuously variable between zero and maximum is. Device according to claim 19,
characterized in that the contact surface of the heating element (9, 9 ') is convex. Device according to claim 20,
characterized in that the movable heating element (9, 9 ') is designed to be pivotable and has an actuator for a pivoting path which is dependent on the speed of the carrier web (7, 7'). Device according to claim 21,
characterized in that the swivel path is automatically adjustable. Device according to at least one of claims 19 to 22,
characterized in that the movable heating element (9, 9 ') is designed with a lateral pivot point and with a contact surface underneath and the swivel path is based on the ratio of the inherent mass of the heating element (9, 9') and the speed-related buoyancy of the carrier web (7, 7 ') results. Device according to at least one of claims 20 to 23,
characterized in that the print head (10, 10 ') is designed as a heating element and the movable heating element (9, 9') as a preheater. Device according to at least one of claims 11 to 24,
characterized in that a heat source of an aftertreatment device consists of an electrically operated heating plate (19) with a flat or concave heating surface (21) and a controller (20) adjustable to a setpoint temperature. Device according to claim 25,
characterized in that the flat heating surface (21) relates to a linear transport path and the concave heating surface (21) relates to a circular transport path of the packs (5) and the length of the effective heating surface (21) is defined for a target reheating time. Device according to claim 25 or 26,
characterized in that the containers (5) are arranged in a freely rotating manner on the transport path of the aftertreatment device and are driven by the stationary heating plate (19). Device according to at least one of claims 11 to 27,
characterized in that a heat source of an aftertreatment device consists of a nozzle head (22), a temperature-controlled hot air generator (23), a quantity-controlled bypass valve (24) and a temperature and quantity regulator (25) and the container (5) a separate drive for the rotation have.

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