DE202005021735U1 - monitoring device - Google Patents

Abstract

Monitoring device with a protective grid (2, 2 ') which forms part of at least one inductive sensor, wherein the protective grid (2, 2') comprises a plurality of bars (8a-8i, 20a-20l, 10a-10c, 22a-22c) which are electrically connected to each other so that they are electrically connected in series and form a coil-shaped conductor track.

Description

The The invention relates to a monitoring device.

It are grids for the protection of building openings and to the property enclosure known, which are monitored for manipulation.

So grids are common, whose lattice structure is a closed hollow body. forms, which with compressed gas filled or in which a pressurized gas tube system is laid. The gas pressure in the hose system is monitored. The severing a lattice bar leads in these grids to a violation of the hollow body or hose and it an alarm is triggered due to the associated pressure change. adversely can In this arrangement, leaks lead to false alarms, wherein It means a considerable effort to find these leaks and fix it. Other disadvantages of this grid training are the relatively large installation effort when pulling in the hoses in the bars as well as the fact that bending the bars is not necessarily leads to an alarm.

Further is known to clamp wires in hollow bars, their severance also triggers an alarm. A bending of the bars leads to This configuration is not necessarily an alarm. Further is also the laying of wires in the bars relatively labor intensive.

In front In this background, the object of the invention is an improved monitoring device for a Create grids that reliably alert you to manipulation of the grid triggers and has a simple structure.

These The object is achieved by a monitoring device solved with the features specified in claim 1. Preferred embodiments emerge from the subclaims, the following description and the drawings.

The Monitoring device according to the invention has a protective grid. This protective grille forms a part at least one inductive sensor and at least one coil. For this the protective grid has a plurality of bars, which are so electrically connected to each other that they are electrically connected in series and a coil-shaped conductor track form.

The The protective grid itself thus forms the sensor or a part of the Sensors, which allows a very simple construction of the monitoring device. The basic idea of the invention is to provide a metallic protective grid by energizing the bars to generate a magnetic field and an example when cutting or bending of bars as well as the removal of the protective grid occurring change the inductance be detected and reported by means of a suitable evaluation. So allows the monitoring device according to the invention a particularly reliable monitoring for example, of building openings, wherein The protective grid can also be used outdoors as the influence the weather on the inductance negligible is. Another advantage of the invention is the ease of assembly the monitoring device, to lay no lines within the grid structure are because the protective grid used formed as electrically conductive metal grid are such that the grid structure itself, d. H. the the grid structure forming bars, forms an energizable conductor. Accordingly, the protective grid also be made of a solid metal material. The protective grid can simultaneously sensor the monitoring device and be a mechanical barrier. But a mechanical barrier can also be formed by a grid, which is not part of the monitoring device is. In this case, in front of this grid is the guard of the monitoring device arranged. This arrangement allows a lighter construction of the grid, in which the lattice structure for example, of hollow bars or bars with relatively little Cross section can be formed. In addition, the protective grille the monitoring device be placed in front of existing grids for their backup. Especially at big Lattices such as those used for fencing of land It may be advantageous if the protective grid in several adjacent grid sections is divided, wherein the individual grid sections form independent sensors. These Design allows the rapid localization of the area of the protective grid at which a manipulation takes place.

The Protective grid forms at least one coil. For this purpose, the protective grid a grid structure, which at least one wound and / or annular conductor track a coil, in particular a flat coil forms. The energization this coil allows in relation to to a straight conductor significantly larger inductances and inductance during a manipulation of the protective grid. Accordingly, this increases Embodiment advantageous the detection accuracy of the monitoring device.

These grid bars of the protective grid can be arranged, for example, as longitudinal bars and / or transverse bars arranged essentially parallel to one another. Preferably, the bars are gera de trained, but their form is arbitrary within wide limits. For example, the grid bars can also be curved or wave-shaped. Furthermore, the protective grid can have intersecting grid bars. For example, the protective grid may be formed by a plurality of longitudinal bars and a plurality of transversely oriented transverse bars. In this case, the grid bars of the protective grid according to the invention are electrically connected to one another such that they are electrically connected in series and form a coil-shaped conductor track or coil. In a preferred embodiment of the protective grid, all grid bars of the protective grid are electrically connected to one another in the manner described above, which allows complete monitoring of the protective grid with only one evaluation unit.

Advantageous are the ends of the bars that form the ends of the track, for energizing an electrical Circuit can be connected, which the excitation voltage required to build up the magnetic field supplies. The connection of the power source is accordingly to the Ends of the bars are provided, which form the ends of the trace, which of the preferably is formed in series interconnected grid bars. In this way are preferred all Bars, which form the track over her entire length of an excitation current flows through and can thus be monitored inductively become.

In In a preferred embodiment, the protective grille forms part of a Circuit, which directly or by means of a transformer connected to an oscillator. In this embodiment the coil formed by the protective grid forms at least one partial inductance of the resonant circuit of the oscillator. In a preferred embodiment, the protective grid not directly connected to the resonant circuit but with means of a transformer connected to the resonant circuit, wherein the primary coil of the transformer the coil of the resonant circuit forms and the secondary coil in a common circuit is arranged with the protective grid. The indirect and immediate connection of the protective grille to the resonant circuit of the oscillator lead in a manipulation of the protective grid to a detuning of the resonant frequency of Resonant circuit. This resonance detuning can then from one to the evaluation unit connected to the oscillator and in shape of an alarm.

Advantageous is in the monitoring device according to the invention provided that a plurality of grid bars alternately at their longitudinal ends with each other are connected, so that at least one meandering conductor is formed. In this case, preferably directly adjacent bars, which are aligned substantially parallel to each other, so with each other connected to form the windings of a flat coil.

In a further advantageous embodiment of the monitoring device the bars of the Protective grille as longitudinal bars and as Crossbars formed, the longitudinal bars and the crossbars are isolated from each other and at selected crossing points to Forming a continuous conductor conductive interconnected are. This configuration allows it, that the longitudinal bars are forming a meandering track can be connected to each other, without the cross bars, which cross the longitudinal bars, undesirable Form current paths. In this way it is possible, for example, first one Conductor to form by conductive connection of the longitudinal bars, and then this Track at a first crossing point with a first crossbar conductively connect and starting from this first crossbar all crossbars electrically connect with each other so that they also electrically connected in series, so that all longitudinal and transverse bars a common Forming a track of a flat coil.

Prefers the longitudinal bars are like that conductively connected to each other so that they have a first meandering coil section form and the cross bars electrically connected to each other so that they have a second meandering coil portion form. The first and second coil sections are also interconnected conductively connected and form a common coil. That is how they form interconnected longitudinal bars and the interconnected cross bars two coil sections connected in series, the meandering turns Preferably, the first and second coil sections are normal aligned with each other.

Further can be advantageous the bars be connected to each other in such a way that they are two in one another form gripping coil sections, wherein adjacent bars different Coil sections are in opposite directions flowed through by electricity. hereby creates a bifilar winding of the coil, in the adjacent bars, or Coil windings, with current flowing in the opposite direction so that the magnetic field in these adjacent turns largely canceled and the inductance is low. This embodiment is particularly advantageous when large metal masses in the immediate Near the Coil, d. H. of the protective grid are located. This prevents These metal masses can affect the sensor of the monitoring device undesirable.

Another preferred embodiment of the monitoring device looks at the protective grid at each of the grid mesh formed by the longitudinal and transverse bars before a Stromeinspreisung or coupling before. Thus, a single lattice mesh forms a coil whose inductance or inductance change can be monitored. In this way, it is not necessary to isolate the longitudinal and the cross bars against each other, which makes it possible to use in the context of the monitoring device and conventional metal mesh or the monitoring device to attach to existing grids. By energizing several or all grid meshes of the protective grid independently of one another, the protective grid forms a number of monitoring sections corresponding to the number of meshed meshes of the protective grid. These monitoring sections are expediently energized simultaneously, which ensures complete monitoring of the protective grid. In addition, it is also possible to monitor the monitoring sections alternately. For this purpose, the monitoring sections or grid meshes can be energized, for example, in very small time intervals by means of a suitable switching device and connected to the evaluation, so that even in this embodiment, a substantially complete monitoring of the protective grid when using an evaluation unit is possible. The energization or coupling of the individual grid meshes can be effected for example by means of a ring core placed around a grid bar in the respective grid mesh, on which a suitable feed coil is arranged.

It is possible, Ground the grid at a feed point low impedance. But it can also be beneficial to the protective grid before the ground potential isolate, for example, if, as in a further advantageous Design provided, the protective grid simultaneously an electrode for detecting capacitive field changes forms. In this embodiment, the between the protective grid and monitoring the earth potential existing electric field and disorders this electric field, for example, when approaching a Person to the protective grille or by touching the protective grille of the monitoring device reported.

Especially then, if the protective grid is also provided as a mechanical barrier is advantageously a closed around the protective grid arranged metallic frame. This arrangement ensures that the monitoring device also a complete one Removing the guard can indicate that the removal of the Protective grid to a change the distance between the protective grid and the surrounding frame leads, causing the magnetic field, d. H. the inductance of the protective grid also changed and leads to a corresponding message. The frame is preferably on the one to be protected Space facing inside of the protective grid arranged.

following the invention with reference to embodiments shown in the drawings explained. Show it:

1 a schematic diagram of a monitoring device according to the invention with a protective grid, which forms a coil-shaped conductor track and

2 a schematic diagram of a protective grid with two intermeshing coil sections.

In 1 a monitoring device is shown, in which a protective grid 2 over a transformer 4 on a resonant circuit, not shown, of an evaluation unit 6 connected. Instead of the transformer 4 could also be a direct connection of the protective grid 2 to a suitable evaluation unit 6 be provided.

The protective grid 2 in this example, there are nine parallel longitudinal bars 8a - 8h and three to these longitudinal bars 8a - 8h normally aligned and mutually parallel transverse bars 10a - 10c educated. Except for the crossing point 12a between the longitudinal bar 8h and the crossbar 10c , the crossing point 12b between the longitudinal bar 8a and the crossbar 10c , the crossing point 12c , between the longitudinal bar 8a and the crossbar 10b , the crossing point 12d between the longitudinal bar 8i and the crossbar 10b as well as the crossing point 12e between the longitudinal bar 8i and the crossbar 10a , Which each form a conductive connection between the above-mentioned longitudinal and transverse bars, all other crossing points between the longitudinal and transverse bars are formed isolated.

Starting from the longitudinal bar 8b are the longitudinal bars 8c to 8h connected at their ends via conductive cross-connections with the respective adjacent longitudinal bar. Here is a longitudinal bar 8b - 8h each at one end with the longitudinal bar adjacent to one side 8b - 8h and at its opposite end with the longitudinal bar adjacent to its other side 8b - 8h connected so that the longitudinal bars 8b - 8h connected in series form a meandering conductor track. About the crossing point 12a is the longitudinal bar 8a conductive with the crossbar 10c connected, which in turn starting from the crossing point 12b with the between the crossing points 12b and 12c lying portion of the longitudinal bar 8a the crossbar 10b , between the crossing points 12d and 12e lying portion of the longitudinal bar 8i as well as the crossbar 10a is connected and so another meandering track forms. In this way, the interconnected longitudinal bars form 8b to 8h and also the interconnected cross bars 10a to 10c two serially connected intersecting portions of one of the protective grid 2 formed flat coil.

This flat coil is over the longitudinal bar 8b as well as the crossbar 10a to the secondary coil 14 of the transformer 4 connected and forms a circuit with this. This circuit is via a primary coil 16 of the transformer 4 supplied with a voltage, so by that of the protective grid 2 formed flat coil in a flow direction A, a current flows, wherein the protective grid 2 forms an inductance. This inductance is due to manipulation of the protective grid 2 For example, when sawing a longitudinal or a cross bar and bending a longitudinal or transverse bar changed what the resonant circuit of the evaluation 6 detuned, ie, whose resonant frequency detunes. The detuning of the resonant circuit is via signal lines 18 from the evaluation unit 6 forwarded to a message or alarm unit, not shown in the figure, so that there is a manipulation of the protective grid 2 is shown.

2 shows a protective grid 2 ' , which consists of twelve parallel longitudinal bars 20a - 20l as well as three mutually parallel transverse bars 22a - 22c is formed. Even with the protective grid 2 ' are the longitudinal bars 20a - 20i and the crossbars 22a - 22c electrically isolated from each other at most crossing points. Only the crossing point 24a from longitudinal bar 20a and crossbar 22a , the crossing point 24b from longitudinal bar 20l and crossbar 22a , the crossing point 24c from longitudinal bar 20l and crossbar 22c as well as the crossing point 24d from longitudinal bar 20b and crossbar 22c form electrical connections of the respective longitudinal and transverse bars.

Unlike the in 1 illustrated protective grid 2 are at the protective grid 2 ' not all longitudinal bars 20a - 20l successively connected in series. Thus, to form a first meandering coil section, the longitudinal bars 20k . 20h . 20g . 20d . 20c and 20a each connected in series by means of cross connections and form a first coil section. The skipped longitudinal bars 20b . 20e . 20f . 20i and 20j are also connected in series by means of transverse connections and form a second coil section, which engages in the first coil section. Starting from the crossing point 24a form the crossbar 22a , the longitudinal bar 20l as well as the crossbar 22c over the crossing point 24d a conductor track for the conductive connection of the first and second coil section.

The protective grid 2 ' is about the free end 26 of the longitudinal bar 20k and about the free end 28 of the longitudinal bar 20j to an in 2 not shown circuit (eg., A transformer 4 , as in 1 ) and is flowed through in the flow direction A '. From the figure it becomes clear that, due to the line connection of the first and second coil sections, the turns of the second coil section are traversed by current in opposite directions to the turns of the first coil section. For example, the one of the interconnected longitudinal bars 20k and 20i formed coil winding of the first coil portion in the clockwise direction and the interconnected longitudinal bars 20j and 20i formed coil winding of the second coil section, which engages in the winding of the first coil section, energized counterclockwise. This embodiment is particularly advantageous when large metal masses, such as a heavy metal mesh, which mechanically protects a building opening, in the immediate vicinity of the protective grid 2 ' are arranged, as in the above-described energization of the protective grid 2 ' largely cancel out the magnetic fields of adjacent turns of the first and second coil sections and those of the protective grid 2 ' formed coil has a correspondingly lower inductance overall.

2, 2 '

guard

4

exchangers

6

evaluation

8a-8i

longitudinal bar

10a-10c

cross bar

12a-12e

intersection

14

secondary coil

16

primary coil

18

signal line

20a-20l

longitudinal bar

22a-22c

cross bar

24a-24d

intersection

26

The End

28

The End

A, A '

Flow direction

Claims (11)

Monitoring device with a protective grid ( 2 . 2 ' ), which forms part of at least one inductive sensor, wherein the protective grid ( 2 . 2 ' ) a plurality of bars ( 8a - 8i . 20a - 20l . 10a - 10c . 22a - 22c ), which are electrically connected to each other so that they are electrically connected in series and form a coil-shaped conductor track. A monitoring device according to claim 1, wherein the ends of the grids forming the track ( 8a . 8b . 20k . 20j ) to an electric current circle are connectable. Monitoring device according to one of the preceding claims, wherein the protective grid ( 2 . 2 ' ) Forms part of a circuit which, directly or by means of a transformer ( 4 ) is connected to an oscillator. Monitoring device according to one of the preceding claims, wherein a plurality of bars ( 8a - 8i . 20a - 20l . 10a - 10c ) are alternately connected to each other at their longitudinal ends, so that at least one meander-shaped conductor track is formed. Monitoring device according to one of the preceding claims, wherein the grid bars are in the form of longitudinal bars ( 8a - 8i . 20a - 20l ) and cross bars ( 10a - 10c . 22a - 22c ) are formed and wherein the longitudinal bars ( 8a - 8i . 20a - 20l ) and the cross bars ( 10a - 10c . 22a - 22c ) are isolated from each other and at selected crossing points ( 12a - 12e . 24a - 24d ) are conductively connected together to form a continuous conductor. Monitoring device according to claim 5, wherein the longitudinal bars ( 8a - 8i ) are conductively connected to one another such that they form a first meander-shaped coil section and the transverse bars ( 10a - 10c ) are electrically conductively connected to each other so as to form a second meandering coil portion and wherein the first and the second coil portion are conductively connected to each other and form a coil. Monitoring device according to one of the preceding claims, wherein the grid bars ( 20a - 20l . 22a - 22c ) are so conductively connected to each other, that they form two intermeshing coil sections, wherein adjacent bars of different coil sections are in opposite directions flowed through by electricity. Monitoring device according to one of the preceding claims, wherein on the protective grid ( 2 . 2 ' ) is provided at each of the grid meshes formed by the longitudinal and transverse bars a power supply. Monitoring device according to one of the preceding claims, wherein the protective grid ( 2 . 2 ' ) is grounded low impedance. Monitoring device according to one of the preceding claims, wherein the protective grid ( 2 . 2 ' ) forms an electrode for detecting capacitive field changes. Monitoring device according to one of claims 3 to 7, wherein the protective grid ( 2 . 2 ' ) A closed metallic outer frame is arranged.