WO2019242940A1 - Flexible sheet material for securing items - Google Patents

Abstract

The invention relates to a flexible sheet material (1) for securing items. The flexible sheet material comprises a layer (3) which has a securing structure, and an outer layer (8) which is electrically insulated therefrom. The entire surface of the outer layer (8) consists of an electrically conductive material. The outer layer (8) forms an electromagnetic shield for electrically conductive structures which are formed by the securing structure and/or by electronics units which are surrounded by the flexible sheet material (1).

Description

 Flexible fabric for securing goods

The invention relates to a flexible sheet for securing goods.

Such flexible fabrics are generally used to ensure protection against burglary, theft and vandalism. In general, security structures of the surface element protect against unauthorized access.

An example of such a flexible sheet-like structure is a security packing device, as described in WO 2012/080888 A1. This security packing device essentially consists of a covering which is intended to protect an object such as a suitcase or a bag against unauthorized interference. The cover consists of a cut-resistant textile structure with integrated conductive thread layers. At least two electrically conductive layers are provided, which are separated by an insulation layer. When attempting to cut open, the conductive layers are short-circuited due to the object being pushed into the covering, which triggers an alarm.

DE 10 2014 115 437 A1 discloses a method for producing security structures in a surface element. Using a warp knitting machine or Raschel machine, cut-resistant structures and / or threads forming sensor structures are worked into the surface element as security structures.

The invention has for its object to expand and improve the functionality of a flexible sheet of the type mentioned. The features of the independent claims are provided to achieve this object. Advantageous embodiments and expedient training are described in the dependent claims.

The invention relates to a flexible sheet for securing goods. The flexible fabric comprises a layer with a security structure and an outer layer electrically insulated from it. The outer layer consists of an electrically conductive material. This outer layer forms an electromagnetic shield for electrically conductive structures, which are formed by the safety structure and / or by electronic units enclosed with the flexible flat structure.

The entire outer layer consists of an electrically conductive material or a lattice structure made of an electrically conductive material.

The basic idea of the invention is therefore that the outer layer consisting of electrically conductive material is used to effect an electromagnetic shielding, that is to say it provides effective EMC protection for electrically conductive structures provided by the security structures and / or can be formed by electronics units encased with the flexible sheet-like structure.

A major advantage is that the outer layer is part of the flexible fabric itself, so that no additional external means are required to ensure EMC protection. This means that the effort required to achieve EMC protection can be kept extremely low. It is particularly advantageous here that the outer layer can be applied in the manufacturing process of the flexible fabric, which enables rational, inexpensive production of the EMC protection. In addition to this EMC protection, protection against vandalism is also aimed at. In particular, the shielding protects internal electrical or electronic components against attacks with electric shocks.

In particular, in the event that the security structures themselves form electrically conductive structures, it is essential that the layer with the security structure is electrically insulated from the outer layer consisting of electrically conductive material.

For this purpose, the outer layer forming the electromagnetic shield is advantageously separated from the layer having the security structure by an insulation layer.

According to a first variant of the invention, the outer layer forms a coating on the insulation layer.

The outer layer is formed by spraying, vapor deposition or printing. The outer layer can thus be applied rationally and reproducibly to the insulation layer. It is particularly advantageous that the outer layer applied in this way can have a small layer thickness. Thus, the weight of the flexible fabric is not significantly increased by the outer layer. It is also advantageous that the mechanical properties of the flexible sheet, in particular its flexibility, are not impaired by the outer layer.

According to an alternative embodiment, the outer layer is welded to the insulation layer. In this case, the insulation layer consists of an electrically insulating plastic and the outer layer of an identical or similar plastic, in which electrically conductive particles are incorporated as dopants. Welding of plastics is generally only possible if they are identical or at least of the same type, such as derivatives of a plastic. This condition is met by the fact that the electrically conductive materials of the outer layer in the form of dopings are integrated over the entire surface into a plastic which forms the outer layer and which can be welded or glued to an identical or similar plastic of the insulation layer.

By welding or gluing the insulation layer to the outer layer, which can preferably take place over the entire base area of these layers, a stable composite structure is obtained without impairing the mechanical properties of the individual layers.

In principle, the security structures that form the electrically conductive structures can be applied to a film or paper as a carrier material by printing, spraying or the like.

According to a particularly advantageous embodiment of the invention, the security structure is formed by a textile surface into which electrically conductive threads are incorporated as an electrically conductive structure.

The textile surface is formed by a fabric, a knitted fabric, a knitted fabric or a fleece.

In this case, the electrically conductive threads are worked into a carrier material of the textile surface, which consists of non-conductive threads. The layer formed in this way with the safety structure designed as an electrically conductive structure has a low dead weight and high mechanical flexibility.

This layer is advantageously welded or glued to the security structure with the insulation layer.

The prerequisite for this is that the carrier material and the insulation layer consist of identical or similar plastics.

The layer with the security structure is also advantageously covered with an internal cover layer. As a result, the layer with the security structures is not only covered and protected internally but also internally.

The inside cover layer is advantageously made of plastic or an abrasion-resistant textile and is welded or glued to the layer with the security structure. All in all, all layers of the flexible sheet can thus be welded or glued to one another and thus form a stable composite structure which is nevertheless flexible and can be bent and folded so easily.

In principle, the security structure can form a cut-resistant structure, in which case the corresponding threads which form this security structure have a high mechanical stability, which represents efficient protection against being cut open or separated.

According to a particularly advantageous embodiment of the invention, the security structure forms a sensor structure. The security structure is then formed by an electrically conductive structure, in particular by electrically conductive threads in a carrier material. The electrically conductive structures can, if the electrically conductive threads are sufficiently stable, additionally form a cut-resistant structure. A control unit is advantageously assigned to the sensor structure, by means of which interruptions in the sensor structure can be detected.

Interruptions in the electrically conductive structure can be detected with the control unit. If the electrically conductive structures form a close-meshed lattice structure that extends over the entire surface of the flexible sheet, manipulations, that is to say interventions in the flexible sheet, can be detected precisely at any positions. The control unit can advantageously be assigned an alarm device which, when an interruption in the electrically conductive structure is detected, emits an alarm message, in particular an acoustic or optical signal, and thus reports the unauthorized intervention in the electrically conductive structure.

According to a particularly advantageous embodiment, the sensor structure has RFID units, by means of which interruptions in the security structure can be detected, the RFID units exchanging data with a control unit without contact. In general, inductive coil units or NFC (near field communications) units can be provided instead of RFID units.

The invention is explained below with reference to the drawings. Show it:

Figure 1 embodiment of the flexible surface image according to the invention as part of a packaging system. FIG. 2 shows a sectional illustration of the flexible fabric according to FIG. 1. Figure 3a First variant of a textile surface as a component of the flexible fabric according to Figure 1 with associated sensor means

Figure 3b Second variant of a textile surface as a component of the flexible

 1 with assigned sensor means FIG. 4 block diagram for the packaging system according to FIG. 1.

Figure 1 shows an embodiment of the flexible surface structure 1 according to the invention in the form of a tarpaulin. The tarpaulin is part of a packaging system. Goods to be secured are placed on a pallet 2 and then covered with the tarpaulin. Of course, the tarpaulin can also be provided on a trailer, a truck, a trailer or a semi-trailer. In general, the textile fabric can also be seen as a retrofit set on the inside of the tarpaulin. The textile fabric can extend over the entire surface of the tarpaulin or parts thereof.

The flexible sheet 1 has a multilayer structure, as shown in FIG. 2. As an essential element, the flexible sheet 1 has a layer 3 with a security structure. The security structure generally provides protection against damage, in particular puncturing the flexible sheet 1, which results in unauthorized access to the goods secured with the flexible sheet 1. This layer 3 lies between an inner cover layer 4 and an insulation layer 5, which each consist of an insulating, that is, electrically non-conductive material.

An embodiment of this layer 3 with the security structure is shown separately in FIGS. 3a, 3b. The security structure is generally formed by an electrically conductive structure that forms a close-meshed lattice structure that extends over the entire surface of this layer 3. In the present case, the layer 3 consists of a textile surface 6. The textile surface 6 can be formed by a woven, knitted, knitted or non-woven fabric. In the present case, the textile surface 6 consists of a knitted fabric which is produced with a warp knitting machine or Raschel machine. The textile surface 6 has a carrier material 6a consisting of an electrically non-conductive material, which forms the insulation layer 5. The carrier material 6a is formed from plastic threads, which in particular consist of polypropylene or PVC, which form the basic structure of the knitted fabric, into which electrically conductive threads 7 are incorporated during the manufacturing process of the knitted fabric. In the embodiments of FIGS. 3a, 3b, the electrically conductive threads 7 run sinusoidally in the carrier material 6a. The individual threads 7 are worked into the carrier material 6a in such a way that they touch and thus form a conductive grid extending over the entire textile surface 6. Of course, other geometrical arrangements of the electrically conductive threads 7 are also possible. These electrically conductive threads 7 form the electrically conductive structure of layer 3. The electrically conductive threads 7 preferably consist of a metallic material, such as galvanized copper wires. Alternatively, these electrically conductive threads 7 can also consist of a conductive plastic, a stone / basalt fiber or a glass fiber.

The electrically conductive structure of the layer 3 is stored in an electrically insulated manner between the inner cover layer 4 and the insulation layer 5. Since the insulation layer 5, the inner cover layer 4 and the carrier material 6a are formed from the same plastic, these layers can be connected to one another by welding. As can also be seen from FIG. 2, an outer layer 8 is applied to the outside of the insulation layer 5. The outer layer 8, which extends over the entire surface of the insulation layer 5, consists over the entire surface of an electrically conductive material, in particular of a metallic material. Non-metallic materials are also possible. Alternatively, the outer layer 8 can have a lattice structure made of electrically conductive material.

The outer layer 8 thus forms an EMC protection, which protects the electrically conductive structure and, if appropriate, electronics units arranged with the flexible sheet-like structure 1 arranged from the inside against external EMC influences, that is to say the outer layer 8 forms an electromagnetic shielding.

The outer layer 8 can be applied as a coating on the insulation layer 5. For example, the outer layer 8 can be applied to the insulation layer 5 by spraying, vapor deposition or printing.

Alternatively, the outer layer 8 can be formed from a plastic that is identical or at least similar to the plastic of the insulating layer 5, the plastic forming the outer layer 8 being doped with electrically conductive particles. In this case, the outer layer 8 can be welded or glued to the insulation layer 5.

As shown in FIGS. 3a, 3b, the electrically conductive threads 7 of the textile surface 6 together with RFID units 11 form a sensor structure.

Instead of RFID units 11, inductive coil units or NFC units can generally also be used. In the embodiment according to FIG. 3a, electrically conductive threads are connected to two RFID units 11. By comparing the signals of these RFID units 11 it can be determined whether the lattice structure formed by the electrically conductive threads 7 has been interrupted by a manipulative intervention. The embodiment according to FIG. 3b shows that only at least one RFID unit 11 is provided on an edge of the textile surface 6. In this case, the RFID unit 11 is not only connected to one end of an electrically conductive thread 7, but via an electrical line 12 in the form of a thread, etc. to a further end of an electrically conductive thread 7. In this case, by comparing the Signals at the two connections of the RFID unit 11 interruptions in the grid structure formed by the electrically conductive threads 7 are detected.

Figure 4 shows a block diagram with the components of the sensor structures of Figures 3a, 3b.

The signals generated by the RFID units 11 are sent to a control unit 9 without contact and evaluated there. If an interruption in the lattice structure formed by the electrically conductive threads 7 is detected, the control unit 9 controls an alarm device 10 so that it generates an alarm message.

Relytex GmbH & Co. KG

84030 Landshut, DE

LIST OF REFERENCE NUMBERS

(1) flexible fabric

(2) pallet

 (3) layer with security structure

(4) internal top layer

(5) insulation layer

 (6) textile surface

 (6a) substrate

 (7) conductive threads

 (8) outer layer

 (9) control unit

 (10) alarm device

 (11) RFID unit

 (12) Electric wire

Claims

claims

1. Flexible flat structure (1) for securing goods, comprising a layer (3) with a security structure and an outer layer (8) electrically insulated therefrom, this outer layer (8) consisting of an electrically conductive material, so that it Outer layer (8) forms an electromagnetic shield for electrically conductive structures, which are formed by the security structure and / or by electronic units enclosed with the flexible surface structure (1).

2. Flexible sheet (1) according to claim 1, characterized in that the outer layer (8) consists of an electrically conductive Ma material or of a lattice structure made of an electrically conductive material.

3. Flexible flat structure (1) according to claim 2, characterized in that the outer layer (8) forming the electromagnetic shielding is separated from the layer having the security structure (3) by an insulation layer (5).

4. Flexible sheet (1) according to claim 3, characterized in that the outer layer (8) forms a coating on the insulation layer (5).

5. Flexible sheet (1) according to one of claims 2 to 4, characterized in that the outer layer (8) is formed by spraying, vapor deposition or printing.

6. Flexible sheet (1) according to one of claims 2 or 3, characterized in that the outer layer (8) is welded to the insulation layer (5).

7. Flexible sheet (1) according to claim 6, characterized in that the insulation layer (5) consists of an electrically insulating plastic, and that the outer layer (8) consists of an identical or similar plastic, in which metallic particles as a are incorporated.

8. Flexible fabric (1) according to one of claims 1 to 7, characterized in that the security structure is formed by a textile surface (6), in which electrically conductive threads (7) are incorporated as an electrically conductive structure, the textile surface (6) is formed in particular by a fabric, a knitted fabric, a knitted fabric or a nonwoven.

9. Flexible sheet (1) according to claim 8, characterized in that the electrically conductive threads (7) are incorporated in a carrier material (6a) of the textile surface (6), which consists of non-conductive threads (7).

10. Flexible sheet (1) according to one of claims 2 to 9, characterized in that the layer (3) with the security structure is welded to the insulation layer (5).

1 1. Flexible sheet (1) according to one of claims 9 or 10, characterized in that the carrier material (6a) and the insulation layer (5) consist of identical or similar plastics.

12. Flexible fabric (1) according to one of claims 1 to 11, characterized in that the layer (3) with the security structure is covered with an inner cover layer (4).

13. Flexible sheet (1) according to claim 12, characterized in that the inner cover layer (4) consists of plastic and is welded or glued to the layer (3) with the security structure.

14. Flexible fabric (1) according to one of claims 1 to 13, characterized in that the security structure forms a sensor structure.

15. Flexible fabric (1) according to claim 14, characterized in that the sensor structure is assigned a control unit (9), by means of which interruptions in the security structure can be detected, or that the sensor structure has RFID units (11), by means of which Interruptions in the security structure can be detected, the RFID units (11) exchanging data with a control unit (9) without contact.