DE102017007689B3 - Flexible electrostatically dissipative bulk material container and method for producing a multilayer film for such a bulk material container - Google Patents

Abstract

The invention relates to a flexible bulk material container with a container receiving space bounded by walls, wherein the walls are at least partially constructed of a multilayer film material (multilayer) and at least two film layers consist of a plastic material between which a layer and / or an insert of an electrostatic dissipative material is embedded and at least the bulk material facing inner film layer of the plastic material is provided with a opening to the layer and / or insert of the electrostatically dissipative material perforation. To further improve this it is provided that the perforation is formed as a laser perforation with a perforation hole pattern in which each hole channel in cross-section of the bulk material facing inside of the inner film layer to the layer and / or the insert of the electrostatically dissipative material out rejuvenated.

Description

The invention relates to a flexible bulk material container with a wall bounded by container receiving space, the walls are at least partially constructed multi-layered and at least two film layers of a plastic material between which a layer and / or an insert of an electrostatically dissipative material is embedded and at least the bulk material facing inner layer of the plastic material is provided with a opening to the layer and / or insert of the electrostatically dissipative material perforation.

Furthermore, the invention relates to a method for producing a multilayer film for a flexible bulk material container.

Flexible bulk material containers of the type mentioned are generally known. For example, from the EP 1 796 989 B1 a flexible bulk material container with a bottom, a head part and side walls comprising container body made of a polypropylene material known which is equipped electrostatically conductive. In this case, tapes or threads are embedded in the wall region of an electrostatically dissipative material having a bleeder in such a size that the electrostatic Ableitfähigkeit the flexible bulk goods container is made. In order to ensure this, a perforation is provided in an inner layer in order to open an outer plastic layer via hole channels to the electrostatically dissipative filaments.

In order to use such bulk containers for a variety of purposes, such as a large package container for the chemical industry, complex measures are required. Conventionally, multi-layer or multi-layer films are used for the production of such bulk containers, wherein numerous process steps are required in the production. Thereafter, individual slides (layers) in z. As a lamination process to a multilayer (multilayer) film made. Individual layers of z. B. different plastic materials are necessary so that different requirements such. As strength, resistance, extensibility, etc. of the large pack container combined can be achieved. To produce an electrostatic Ableitfähigkeit, conventionally provided to insert an aluminum foil between individual layers of a plastic material and this aluminum foil through a perforation or through hole channels towards the environment, d. H. to the outer periphery of the outermost film. In order to produce a perforation and thus hole channels from the outer film layer to the aluminum layer, the multilayer film is conventionally subjected to a hot-pin perforation, ie a thermal process in which circular holes are melted into the film by piercing with heated needles. The flat film is perforated over the entire surface with hot needles and then rolled up. A change in the detent has the consequence that a new hot-pin perforating roller is required and thus additional costs and time losses arise.

However, a hot-pin perforation is associated with considerable disadvantages for the production of a multilayer film for the creation of walls of a flexible bulk container, since subsequent processing steps of the perforated film can cause the hole channels of the perforation are closed again with the result that an electrostatic dissipative equipment is no longer given is.

From the DE 44 31 046 A1 is a flexible bulk material container with a wall-bounded container receiving space known, the wall is at least partially constructed of a multilayer film material and provided with a perforation. This perforation is made by laser perforation and has a certain perforation hole pattern. The hole channels have matching diameter over the entire length of a hole channel, which adversely affects the electrostatic Ableitfähigkeit.

From the WO 2006/131104 A2 For example, a multilayer film is known having a dissipative barrier layer and a plastic layer with a reduced electrical resistance, wherein the plastic layer with the reduced electrical resistance forms the middle layer of a coextrusion film consisting of three coexisting layers. Such a film should also be used for lining big bags. The dissipative plastic film is said to have a high proportion of dissipative additives such as carbon. The electrical conductivity of this film is limited.

From the DE 10 2015 010 406 A1 is a dimensionally stable food container made of packaging material laminates with several layers, which are formed by a carrier layer, a barrier layer and a polymer inner layer. As a barrier layer, plastic barrier layers, metal layers or Metal oxide layers are used, which is also in terms of their electrostatic Ableitfähigkeit also for most applications is not sufficient.

It is an object of the present invention to develop a flexible bulk material container of the type mentioned in that an optimal hole channel pattern can be achieved as a perforation in an outer layer in the wall of a flexible container with regard to an optimized, electrostatic Ableitfähigkeit, which should be accompanied by reduced manufacturing costs , Furthermore, it is an object of the invention to provide a method by which it is possible, with reduced costs and Gestehungsaufwand to provide a film material for the wall of such a flexible bulk material container available and to be able to use different materials for the wall.

To solve this problem, the flexible bulk material container of the type mentioned is characterized in that the perforation is formed as a laser perforation with a Perforationslochkanalmuster, in which each hole channel in cross-section of the bulk material facing the inside of the inner layer of the plastic material to the layer and / or the insert from the electrostatically dissipative material tapers.

In order to provide a flexible bulk material container is provided in which can be represented by the hole perforations produced by laser perforation in an optimal manner a hole channel pattern with a hole channel geometry that can be adapted to the optimal electrostatic Ableitfähigkeit such a bulk material container.

The laser perforation is to create an optimal perforation hole pattern with a hole pattern or hole channel image that differs from the geometry with its from the inner circumference of a plastic material layer up to the electrostatically dissipative layer, eg. As the aluminum layer, tapered geometry optimally adapted to be challenged for the required electrostatic Ableitfähigkeit the flexible bulk material container properties. Depending on what the flexible bulk material container otherwise has to meet for properties, the most diverse layer materials, be it in single-layer, two-layer, three-layer or multi-layer plastic material outer layer design, realize and with the laser perforation with the appropriate hole channels in terms of equip the electrical discharge capability. The films provided there can be connected to each other in the laminating process. This can be Extrusionkaschierverfahren but also Kleberkaschierverfahren, with cost two-component adhesive can be used to connect individual film materials use. Nevertheless, by means of the laser perforation, the corresponding hole channel pattern can be provided with corresponding hole channels in the desired number, orientation and hole pattern geometry. Layers of low density polyethylene (LDPE) layers, biaxially oriented polyamide (OPA) layers, biaxially oriented polyethylene terephthalate (PET) layers, biaxially oriented polypropylene (OPP) layers and the like may be used . Be provided more, as specified in detail in the claims 2 to 12 as advantageous embodiments of the specified flexible bulk goods container.

Furthermore, it is proposed a method how such multilayer films (multilayer films) can be produced in order to equip such a bulk material container with corresponding electrostatically dissipative walls. In this case, the Klebekaschierverfahren can be used advantageously. Thereafter, it is envisaged to take a multilayer film with a layer or an insert of an electrostatically dissipative material, which is covered on its outside with at least one layer of a plastic material. On the other side, ie to the side facing the receiving space of the bulk goods container, at least one further layer of a plastic material should also be provided. On the inside, two or more further layers of a suitable plastic material, as specified in claims 2 to 12, may be provided. The electrostatically dissipative material may be a layer of z. B. be an aluminum material. But it can also be threads or ribbons from z. B. an electrostatically dissipative carbon black material, which is embedded in a plastic carrier body. Other electrostatics may also be provided.

According to the inventive method is then the inner layer or the inner layers, which are also via adhesion promoter, for. B. two-component adhesive, are exposed to a laser treatment to produce a laser perforation with corresponding hole channels that penetrate the inner layers and thus without the risk of sticking any Lochkanälen even with the proposed two-component adhesives connect the electrostatic dissipative layer towards the bulk material.

Further advantageous process steps are specified in claims 19 to 30.

• 1 a) bis 1 o): Verschiedene Ausführungen von Wandungen für einen Schüttgutbehälter mit einem unterschiedlichen Schichtaufbau;
• 2 a) bis 2 h): in jeweils drei nebeneinander angeordneten Aufbaubeispielen verschiedene Systemaufbauten einer Vorrichtung, um eine Laserperforation herzustellen, und
• 3: ein Ausführungsbeispiel einer Vorrichtung, um eine Folie mit einem Laser zu perforieren.

For further explanation, reference is made to the following description and the drawings. In the drawing show:

• 1 a) to 1 o) : Different designs of walls for a bulk material container with a different layer structure;
• 2 a) to 2 h) FIG. 2: in three construction examples arranged side by side, different system structures of a device for producing a laser perforation, and FIG
• 3 : An embodiment of a device for perforating a film with a laser.

In the drawing, matching parts are given matching names and numbers

As in detail in the 1 can be used as electrostatically dissipative layer 1 Aluminum or a dissipative polymer (eg., <10 ⁶ Ω) may be provided. The respective inner layer or the inner layers are provided with a laser perforation with individual hole channels 2 extending from the outer periphery to the electrostatically dissipative layer 1 Tapered through, resulting in the markings D1 . D2 . D3 and D4 in the 1 a) to o), depending on how many layers above the electrostatically dissipative layer 1 is provided. The abbreviations indicated in the drawings are each explained in more detail in the claims.

In the 2 various system structures are drawn. So is in 2 a) a system structure with one to three lasers from left to right represented with lasers 3 , with one to three scanners 4 , where the working area of the scanner with 5 is numbered. It is also possible to provide more layers and / or more lasers. These scanners are movable along with the lasers, which is indicated by the double arrows 6 is marked. In the embodiment according to 2 B) Again, three variants are shown, with a horizontally aligned laser 3 , a laser beam on a deflecting mirror 7 , or two deflection mirrors 7 in the 2 B) Middle or three deflecting mirrors 7 emanates, which are then deflected, the deflection mirror in the embodiments of 2 B) Middle and right are formed with the specified partial permeability. The embodiment according to 2 c) Basically corresponds to the embodiment according to 2 B) , However, is not movable, so that here the work area of the system is limited. The embodiment according to 2 d) essentially corresponds to the embodiment according to 3 However, here again the work ready similar to the embodiment according to 2 c) is limited.

In the embodiment according to 2 e) is the laser 3 provided with a lens 8th associated with a fixed focal length. In the embodiment according to 2 e) The center and the right are each again two or three lasers with corresponding associated lenses 8th intended.

The embodiment according to 2 f) essentially corresponds to the embodiment according to 2 e) , Here is the laser 3 aligned horizontally and radiates on a deflection mirror 7 , wherein similarly as in the embodiment according to 2 two or three mirrors may be provided with a corresponding partial transmission.

The embodiment according to 2 g) is basically constructed as the embodiment according to 2 f) , Here, however, is a travel path 6 intended.

According to the embodiment 2 h) is in turn a similar structure as in 2 e) shown, but in addition to the travel 6 ,

In the illustration after 3 an embodiment of a device is shown, with which a film can be provided with the laser perforation. The device is generally with 10 numbered, the two roles 11 has, on which the film 12 can be stretched. It is a suction device 13 provided as well as a scanner head 14 as well as a CO ₂ laser 12 , The laser together with the scanner head can be controlled by a linear drive 15 so that the corresponding laser perforation channel pattern is moved to the left and right by the linear drive and by the advancement of the roller 12 can also be produced vertically on the film in continuous operation.

Claims (30)

Flexible bulk material container with a container receiving space bounded by walls, wherein the walls are at least partially constructed of a multilayer film material (multilayer) and at least two film layers consist of a plastic material between which a layer and / or an insert of an electrostatically dissipative material is embedded and at least the bulk material facing inner film layer of the plastic material is provided with a opening to the layer and / or insert of the electrostatic dissipative material perforation, characterized in that the perforation is formed as a laser perforation with a Perforationslochmuster, in which each hole channel in cross section from the bulk material facing inside of the inner film layer to the layer and / or the insert from the electrostatically dissipative material tapers. Flexible bulk container after Claim 1 , characterized in that the layer provided with the laser perforation consists of an LDPE layer (low-density polyethylene layer), which is aligned to the bulk material of the bulk material container and that facing the outside of the container receiving space, a layer of a biaxially oriented polyethylene terephthalate (PET layer) is provided, which is connected via an adhesion promoter with an aluminum layer as electrostatically conductive layer. Flexible bulk container after Claim 1 , characterized in that the bulk material of the container receiving space aligned layer of the plastic material consists of an LDPE material (low-density polyethylene layer), which is connected via an adhesion promoter with an electrostatically dissipative aluminum layer, and that to the outside of the container receiving space a biaxially oriented polyamide layer (OPA) is provided, which is connected via a bonding agent with the aluminum layer. Flexible bulk container after Claim 1 , characterized in that the layer provided for the bulk material of the container receiving space is constructed in two layers of an LDPE layer (low-density polyethylene layer), which is connected via a bonding agent with an OPA layer (biaxially oriented polyamide layer), which is connected via an adhesion promoter with an aluminum layer, wherein the outside of the container receiving space, the aluminum layer is connected via a bonding agent with a biaxially oriented polyethylene terephthalate (PET). Flexible bulk container after Claim 1 , characterized in that the aligned to the bulk material of the container receiving space, provided with the laser perforation layer is formed in two layers with an outer LDPE layer (low-density polyethylene layer), via a bonding agent with a biaxially oriented polyamide layer (OPA) which is connected via an adhesion promoter with an aluminum layer, which in turn is connected to the environment aligned with a bonded via a bonding agent biaxially oriented polypropylene layer (OPP). Flexible bulk container after Claim 1 , characterized in that the aligned to the bulk material of the container receiving space, provided with the laser perforation layer is formed of two layers of an outer LDPE layer (low-density polyethylene layer), via a bonding agent with a biaxially oriented polyamide layer (OPA ), which in turn is connected via an adhesion promoter with an aluminum layer, which is connected via a bonding agent to the environment aligned with a biaxially oriented polyamide layer (OPA). Flexible bulk container after Claim 1 , characterized in that the layer formed to the bulk material of the container space, with the laser perforation is formed in three layers in an outer LDPE layer (low-density polyethylene layer), which is connected via a bonding agent with a biaxially oriented polyamide layer (OPA) which, in turn, is bonded to an EVOH layer (ethylene-vinyl alcohol copolymer layer) bonded via a primer to an aluminum layer, which in turn is oriented towards the environment via a biaxially oriented polypropylene (OPP) adhesion promoter. connected is. Flexible bulk container after Claim 1 , characterized in that the bulk material of the container receiving space aligned, provided with the perforation wall is formed in three layers of an outer LDPE layer (low-density polyethylene layer), which via a bonding agent with a biaxially oriented polyamide layer (OPA) bonded to an EVOH layer (ethylene-vinyl alcohol copolymer layer) bonded via an adhesion promoter to an aluminum layer, which in turn is bonded to the environment with a biaxially oriented polyethylene terephthalate (PET) layer is. Flexible bulk container after Claim 1 , characterized in that the aligned with the bulk material of the container receiving space, provided with the perforation layer is formed in three layers with an outer LDPE layer (low-density polyethylene layer), via a bonding agent with a biaxially oriented polyamide layer (OPA) bonded to an EVOH layer (ethylene-vinyl alcohol copolymer layer) bonded via an adhesion promoter to an aluminum layer, which in turn is connected to the environment aligned with a biaxially oriented polyamide (OPA) layer. Flexible bulk container after Claim 1 , characterized in that the bulk material oriented towards the wall is formed of a single layer LDPE layer (low-density polyethylene layer), which is connected to an electrically dissipative polymer layer (<10 ⁶ Ω) to the environment with a biaxial Oriented polyethylene terephthalate -SIOX layer (PET-SIOX layer) is connected. Flexible bulk container after Claim 1 , characterized in that the facing to the bulk material, provided with the laser perforation layer is formed in three layers with an outer LDPE layer (low-density polyethylene layer), which is connected via a bonding agent with a biaxially oriented polyamide layer (OPA) which in turn is bonded to an EVOH layer (ethylene-vinyl alcohol copolymer layer) bonded to an electrically dissipative polymer layer (<10 ⁶ Ω), which in turn has an adhesion promoter with a PET (polyethylene terephthalate) -SIOX layer connected to the environment. Flexible bulk container after Claim 1 , characterized in that the facing to the bulk material, provided with the laser perforation layer is formed in two layers with an outer LDPE layer (low-density polyethylene layer), which is connected via a bonding agent with a biaxially oriented polyamide layer (OPA) , which in turn is connected to an electrically dissipative polymer layer (<10 ⁶ Ω), which in turn is connected via a bonding agent to the environment aligned with a PET (polyethylene terephthalate) SiOX layer. Flexible bulk container after Claim 1 , characterized in that the laser perforation has a hole channel diameter of ≥ 10 microns. Flexible bulk container after Claim 1 , Characterized in that Perforationsgeometrien are provided in the stripe pattern in the cross pattern in the hole pattern, in the arrow pattern in the circuit pattern and / or in the square pattern.

Flexible bulk container after Claim 1 , characterized in that the electrostatically dissipative insert is formed by strips, tapes, layers of an electrostatically dissipative carbon black material or a metallic material or other electrostat. Flexible bulk container after Claim 1 , characterized in that the layers of a plastic material have a thickness of 40 microns to 60 microns. Flexible bulk material container according to one of the preceding claims, characterized in that a grid spacing of the hole channels formed by the laser perforation in the range of 5 mm x 5 mm to 10 mm x 10 mm is provided. Method for producing a multilayer film with a layer or insert of an electrostatically dissipative material which is covered on one side by at least one layer of a plastic material and on another side also by at least one layer of a plastic material, wherein the layer and / or the insert of an electrostatically dissipative material is connected to its outside with hole channels produced by a perforation, characterized in that tapered hole channels are produced by a laser perforation and these hole channels through Laser pulses are created, the respective Lochkanaldurchmesser is adjustable by adjusting the laser pulse energy and laser pulse duration. Method according to Claim 18 , characterized in that with one or more lasers and a scanner, a specific work area is aligned on a multilayer film and a hole channel is generated with a Lochkanalquerschnittgeometrie which tapers depending on the laser pulse energy to the layer of the deposit of the electrostatically dissipative material. Method according to Claim 18 and 19 , characterized in that one or more lasers act on the multilayer film in the vertical direction. Method according to Claim 19 and 20 , characterized in that a laser is aligned in the horizontal direction, that the laser beam is deflected by a mirror by 90 ° and applied to the multilayer film material via a scanner. Method according to Claim 21 , characterized in that two or more partially transmissive mirror deflect a laser beam on a scanner and on the film material to be processed. Method according to one of Claims 18 to 22 characterized in that two or more lasers in parallel with associated scanners process the laser perforated multilayer film material with a limited system work area. Method according to one of Claims 18 to 23 , characterized in that the at least one laser is associated with a lens having a fixed fixed focal length or with different fixed focal lengths. Method according to one of Claims 18 and 24 , characterized in that the films of the multilayer film (multilayer) are interconnected by an extrusion lamination. Method according to one of Claims 18 to 24 , characterized in that the films to be joined together are made of a plastic material and a film or a liner made of an electrically conductive material by means of a Klebekaschierung. Method according to Claim 26 , characterized in that in a Kleberkaschierung the films to be joined together, an adhesive is applied to a film web as a two-component adhesive based on polyurethane with an initial viscosity of 700 to 1500 mPa / s. Method according to one of Claims 18 to 27 , characterized in that a multilayer film is stretched over two rollers in a device and a scanner head, which is associated with a CO ₂ laser, is moved by means of a linear drive with a vertical spacing over a film and the film is exposed to laser beams, via a Control the laser pulses are set to produce a desired laser pulse energy for the production of hole channels with a tapered from outside to inside towards a layer or insert of an electrostatically dissipative material cross-sectional geometry. Method according to Claim 28 , characterized in that the linear drive moves the scanner head with the associated CO ₂ laser transversely to the feed direction of a multilayer film to be lasered. Method according to Claim 28 or 29 , characterized in that above the clamped film suction takes place via a suction hood.

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