DE19856005A1 - Security device has netting contg. conducting mesh and signalling device that applies different potentials to netting and detects capacitance and/or inductance change - Google Patents

Abstract

The security device has netting (1) made at least partly of an electrically conducting mesh, to which at least two different electrical potentials (11,12) can be applied that are active over its area, and a signalling device (3) that applies the potentials to the netting and detects a capacitance and/or inductance change. An Independent claim is also included for a net for a safety arrangement.

Description

The invention relates to a safety device, in particular for securing Clear against unauthorized entry.

When monitoring rooms against unauthorized access or counter stands in such rooms it is known as a so-called safety device use capacitive detectors that respond to the change in capacity when approaching or register when someone passes through. For example Known walls that are equipped with security technology to prevent penetration should, with mutually insulated metal plates or metal grids provided to apply different capacities and capacitively monitor. In the case of penetration of the wall with, for example, a Drill changes the capacity of the facility. The connected kapaziti ve detector registers this as a frequency change and gives a corresponding one Signal that triggers an alarm or other suitable measures.

Such safety devices are simple in construction, usually work Stable over long periods of time and yet react very sensitively to faults of the electric field.

The object of the present invention is to work according to this principle Safety device also for other purposes, especially for large areas Room boundaries such as windows, skylights and glass roofs too create where the view and the incidence of light are disturbed as little as possible should be.  

According to the invention, this is done by a safety device with the in Features specified claim 1 solved. Accordingly, a network is designed hen that is at least partially formed from electrically conductive mesh yarn and that is designed so that at least two different electrical potentials can be applied and are effective over its area. This network is then connected to one well-known notification device, for. B. connected to a capacitive detector the network is charged with two electrical potentials and a capacitance and / or change in the inductance of the network, as is the case, for example, with Penetration or destruction of the same takes place.

The safety device according to the invention is simple in construction and can be used for surfaces of practically any size are therefore particularly suitable for buildings with large skylights, glass roofs or other glazing The technical outlay is comparatively low, since corresponding networks Manufactured by the manufacturer and only attached and connected on site Need to become. Depending on the requirements, the networks can be thin, hardly visible net yarn and large mesh size are formed. It can on the other hand, stable networks are used that are also mechanical Functions include, for example, as safety nets or one give some mechanical protection against penetration. The assembly of this Nets are very simple and can be done by assistants, it is only on proper wiring to the signaling device, what is in the Practice also presents no problems.

The signaling device is preferably designed as a capacitive detector, so that it is a Outputs AC voltage signal, which is applied to a conductor of the network, with at least one other conductor in the network, the then connected to earth potential. The change in capacity, for example in Penetration of the network is done by changing the frequency of the AC voltage signal detected.  

It is particularly advantageous if two conductors of the network are connected to different ones Potentials are present that each stand out from the earth potential. Then through corresponding capacitive evaluation not just a capacitive change like it be detected when penetrating the network, but also when off against the earth potential also the capacitive change that is caused by Approach to the network results. Such an arrangement enables a very extensive monitoring without complicating the structure of the network.

An essential part of the safety device according to the invention is a appropriately trained network, which makes it possible an electric field as evenly as possible over the entire area of the network, so too a change in the electrical field when penetrating or destroying the Detect network or when approaching the network.

To this end, the invention provides for a special network consisting of at least two Yarn is formed, at least one of which is electrically conductive. Are there the yarns are processed into a network in such a way that at least two are connected to each other insulated conductors that extend over substantially the entire area of the Extend network. It is understood that such an arrangement is also due to this can be achieved that electrical conductors through substantially linear the network is routed and connected at the end accordingly.

It is advantageous if the network alternates between conductive and non-conductive Yarn is formed because then the electrical conductors over the non-conductive yarns are electrically isolated from one another and also fixed at the same time.

Alternatively, the network according to the invention can also be made exclusively of electricity conductive yarn are formed if, for example, part of the lines is isolated. Instead of insulated wires, it is sufficient to use appropriate ones Provide isolators in the area of the intersections, which, however, also the  The wires should be fixed to each other in order to ensure that the structure of the Ensure network.

However, the network according to the invention is preferably formed by nodes, since then the production can take place on conventional machines and at the same time also high mechanical stability is guaranteed. First attempts have shown that it is favorable to ver as steel and plastic ropes as mesh yarns knot in such a way that the plastic rope fixes and insulates the conductors to each other or spaced. Both steel ropes and plastic ropes can high mechanical forces absorbed with a comparatively low thread count become. In order to improve the conductivity of the steel cable, it is advantageous this with a copper core or another highly conductive material as the core to provide. Alternatively, the network can also be formed metal-free if as Conductor of electrically conductive plastic fibers such as carbon fibers or the like are used.

The network according to the invention can not only be used to monitor glass with ge Protect openings, but also for monitoring walls, com plicated spatial structures or even in summer for the purpose of ventilation open doors or windows. Can also with the network according to the invention Targeted object monitoring takes place within a room if the Object covered with the network, for example with the help of a Wooden frame and the network is connected to a capacitive detector. Alternatively, the network can also be monitored by an inductive detector, the conductors of the network are then to be connected appropriately.

The invention is described below with reference to the drawing management examples explained in more detail. Show it

Fig. 1 in a highly simplified representation of a network according to the invention in a first circuit arrangement and

Fig. 2 shows the network of FIG. 1 in a second circuit arrangement.

Fig. 1 shows a safety device consisting of a network 1 and a notification device 2. The network 1 is alternately formed from a conductive yarn 3 and a non-conductive yarn 4 , the yarns being firmly connected to one another by knots 5 . In the embodiment shown in Fig. 1, the conductive yarn consists of a 3 mm steel cable with a (not shown) copper insert, which serves to improve the conductivity. The non-conductive yarn 4 is formed by a plastic rope, as is the net frame 10 surrounding the net, which is used for fastening. The net 1 shown has a mesh size of 10 cm, the yarns 3 , 4 used have a breaking load of at least 200 kg. This network can for example be attached to the ceiling below a skylight.

As can be seen from the illustration in FIG. 1, each mesh 7 of the network has two conductive legs 8 and two opposing non-conductive legs 9 . The conductive and non-conductive legs lie essentially in a line 10 , which also forms the main running direction of the net yarn. If one considers the conductive or non-conductive legs 8 , 9 in the main running direction (in the direction of line 10 ) of the yarn, it follows that two adjacent conductive yarns 3 are fixed, spaced and insulated by an intermediate non-conductive yarn 4 . The interconnection of the conductive yarns 3 takes place along the main running direction in lines 10 , whereby every other line of the conductive yarn 3 is electrically conductively connected to one another and to the signaling device 2 . The signaling device 2 according to FIG. 1 has a connection 11 to which an AC voltage is present. The other terminal 12 is at ground potential. In this way, there is a network 1 , which is alternately in the main running direction by a conductive yarn 3 , which is connected to the AC voltage connection 11 , a non-conductive yarn 4 , a conductive yarn 3 , which is connected to the earth potential, a non-conductive yarn 4 , a conductive yarn 3 , which is applied to the AC voltage connection 11 , etc. Such a network forms an elec trical alternating field, which is when this is changed, for example, when penetrating an object or body. This change requires a change in capacitance, this in turn a change in the frequency of the applied signal, which is detected within the signaling device 2 , as is known per se in the case of capacitive detectors of this type.

As indicated in FIG. 1, the signaling device 2 has the usual structure of a capacitive detector. The connections 11 and 12 are connected to the secondary winding of a transformer 15 , the primary winding of which is part of an oscillating circuit 16 to which a frequency meter 17 is assigned, the output signal of which is fed to an electronic evaluation device 18 , which is part of an alarm system, which is not described in detail here becomes.

The embodiment according to Fig. 2 differs from the above only in the signaling device and in the wiring of the network. The signaling device marked with 13 has, in addition to the ground connection 12 and the AC voltage connection 11, a second AC voltage connection 14 , so it provides two different and different potentials from the ground potential and monitors not only a field change between the connections 11 and 14 , but also with respect to the earth potential. This circuit he enables not only to monitor penetration of the network 1 , but also an approach to the network. Since the conductors of the network 1 represent a capacitance in relation to the environment, the electrical field formed thereby will change when a person approaches the network 1 , which in turn is detected by the signaling device 13 .

The connection of the network 1 according to FIG. 2 is therefore basically as described with reference to FIG. 1, but the conductors are alternately connected to the connections 11 and 14, which have different potentials from one another and from the earth potential.

The networks 1 shown in FIGS. 1 and 2 are formed by knotting the network yarns 3 , 4 , but it is also possible to use a woven network or to provide the crossing points of the conductors by means of fixing insulators, which can be produced in a simple manner as a plastic injection molded body . In addition, even with a knotted net, it is only possible to build it up from electrically conductive yarns if these are provided with an insulating jacket. The wiring then takes place in the same way as described with reference to FIG. 1, but omitting the non-conductive yarns 4th

Reference list

1

network

2nd

Notification facility

3rd

conductive yarn

4th

non-conductive yarn

5

node

6

Mesh frame

7

mesh

8th

conductive thigh

9

non-conductive leg

10th

Line / main running direction of the net yarn

11

Connection / AC voltage

12th

Connection / earth

13

Notification facility after

Fig.

2nd

14

further connection / AC voltage

15

transformer

16

Resonant circuit

17th

Frequency meter

18th

Evaluation device

Claims (11)

1. Safety device with the following features:

• - There is a network ( 1 ) is provided, which is at least partially formed from electrically conductive mesh yarn ( 3 ),
• - The network ( 1 ) is designed such that at least two different electrical potentials ( 11 , 12 ; 11 , 14 ) can be applied and are effective over its surface,
• - A signaling device ( 2 ; 13 ) is provided, which applies two electrical potentials ( 11 , 12 ; 11 , 14 ) to the network ( 1 ) and detects a change in capacitance and / or inductance of the network.

2. Safety device according to claim 1, characterized in that at least one AC voltage signal ( 11 , 14 ) is applied to the network ( 1 ) and the frequency change of this signal is detected. 3. Safety device according to one of the preceding claims, characterized in that two different electrical potentials ( 11 , 14 ) are applied to the network ( 1 ), which stand out from the earth potential ( 12 ). 4. Network for a safety device according to one of the preceding claims, characterized in that the network ( 1 ) is formed from at least two yarns ( 3 , 4 ), at least one of which is electrically conductive. 5. Network according to claim 4, characterized in that the network ( 1 ) of alternating conductive and non-conductive yarns ( 3 , 4 ) is formed. 6. Network according to one of the preceding claims, characterized in that the network yarn ( 3 ) is formed from electrically insulated wires. 7. Network according to one of the preceding claims, characterized in that the network ( 1 ) made of steel cable ( 3 ) and plastic cable ( 4 ) is formed as a yarn, with the plastic cable ( 4 ) passing through the network ( 1 ) steel cables ( 3 ) are kept at a distance such that at least two lines which are electrically insulated from one another are formed and extend flatly and without conductive contact over the network ( 1 ). 8. Network according to one of the preceding claims, characterized in that the steel cable ( 3 ) has a core made of copper or another electrically highly conductive material. 9. Network according to one of the preceding claims, characterized in that the network yarn ( 3 , 4 ) is connected by nodes ( 5 ). 10. Network according to one of the preceding claims, characterized in that the network ( 1 ) is formed by electrically conductive wires ( 3 ) which are spaced and fixed at their intersections by insulators. 11. Network according to one of the preceding claims, characterized in that the network ( 1 ) is designed such that opposite mesh legs ( 8 , 9 ) with different potential ( 11 , 12 ; 11 , 14 ) can be acted upon.