DE19544474A1 - Controlled access to internal building systems - Google Patents

Abstract

The protection of a building against unauthorised access has the electrical mains network within the building controlled remotely. A master switch is activated by a motor 15 that is remotely operated by an inductive coupling through a wall 17. The coupling has a core element 20 and a secondary coil connected to the motor. The excitation is provided by a primary coil with an input from a supply unit 25. A number of variations are possible.

Description

The invention relates to an electrical building installation system according to the Ober Concept of claim 1.

In electrical building installation systems, especially in house installation systems gen or house junction boxes, are either NH fuses or main fuse vending machines that run across the entire network within the building is guarded and secured. When faults occur in the general supply network and the supply network from the responsible energy supply company to be measured, then it must first be located inside the building mains are switched off because the tests are carried out with high surge voltages be led, the electrical equipment located in the house or in the building damage can.

The house connection boxes, which are usually located in the basement, are often for the employees of the Energy supply companies not accessible, so that in very many cases Power cord to the house junction box outside the house and after the Implementation must be connected again with sleeves. This is very time-consuming.  

There are considerations, the house connection boxes outside the house or the Ge to arrange the building. However, some energy supply companies want this not because such house connection boxes can be damaged, for example.

From DE-PS 43 44 018 is a separation device for electrical house installation become known, which preferably three-pole to unlock the system within of the building. A circuit breaker with a door should act as a disconnecting device nere properties are used, which is remotely operable. The separation device should actuated from the outside of the building by supplying an electrical switching energy can be, which via a Steckan arranged on the outside of the building are supplied by means of a generator, an accumulator or the battery Motor vehicle is applied. A special connector is required which should not be designed as a standard plug device, so that unauthorized persons do not intervene in the circuit inside the building can.

The object of the invention is to provide an electrical building installation system to create the type mentioned above, in which the security against unauthorized interference is improved from the outside.

This object is achieved by the characterizing features of the Claim 1.

According to the invention, the shutdown and reclosure by means of remote-controlled drive carried out outside, the Remote drive can be operated wirelessly and! Or can be supplied with energy.

If an NH fuse is provided within the building installation system, then this NH fuse is assigned a disconnector, which is also by means of Remote drive according to the invention can be operated.  

In the course of modernization work, the NH fuses are becoming more and more so-called main circuit breakers replaced, for example by switches like that Switch S700 from ABB Stotz Kontakt GmbH, Heidelberg.

If such a main circuit breaker inside the building installation system is installed, then it is only necessary to use this main automatic fuse assign a remote operator and this remote operator from outside the building to power and control the.

There is the possibility of wireless energy supply and control of the remote switch to induct the coupling.

This can be done, for example, in that on the inside of the building wall a coil, hereinafter also an inner coil, is provided, which is connected to one from the outside applied coil, hereinafter also called outer coil, cooperates. The Spu len can for example be designed as flat spiral coils with a circular gene or rectangular peripheral surface; it is also possible to use the coils as to form helically wound coils.

The inner coils can be inserted into a recess on the inner wall of the building and be covered in it.

The coupling of the coils, in particular the helical coils, can thereby take place that the building wall is penetrated by a core, which on the In section located on the side of the building wall is encompassed by the inner coil. If the core is rod-shaped, then it is for coupling in the switching energy and / or the control energy is only required, the outer coil via the out of the Au to stick the outer surface of the building wall protruding end of the core; if the Core is U-shaped, then it is assigned to the building wall so that the legs Reach through the building wall or protrude on the outside. For coupling a counter core is provided, which is also U-shaped and its leg ends be placed against the leg ends of the U-shaped inner core.  

Both the core and the outer core can be made of laminated transformer sheet Chen are manufactured.

There is also the option of coupling the energy for switching as well to be achieved by radio waves, see claim 14 or 15.

Further advantageous refinements and improvements of the invention are the see further subclaims.

Using the drawing, in which some embodiments of the invention are shown are, the invention and other advantageous refinements and improvements stations of the invention are explained and described in more detail.

Show it:

Fig. 1 is a schematic representation of a domestic installation system with remote operator,

FIG. 2 to 6 show different embodiments of the coupling-, and

FIGS. 7 and 8 show different embodiments of flat coils.

In a in a housing, such as residential buildings, located network 10 is a main circuit breaker 11, for example a switch with the designation S700 from the company. ABB Stotz contact GmbH, Heidelberg, of a distribution network built 12 with the individual consumers associated circuit breaker 13,14 pre- is switched.

This switch 11 is assigned a remote drive 15 , the z. B. can be designed as a DC motor and is electrically connected via a line 16 to a transmission device 18 accommodated in a house wall 17 , via which the remote drive can be controlled from the outside and can be supplied with energy.

If the EVU network is now to be tested, the remote drive 15 is actuated via the transmission device 18 so that it switches the switch 11 off. As soon as the test in the power supply network has ended, the switch 11 can be switched on again via the remote drive 15 .

Figs. 2 and following now show different Übertra invention disposal facilities.

The house wall 17 is penetrated by an iron core 20 ; it towers over the wall on both the inside (on the left in the drawing) and the outside. An inner coil 22 is wound over the end 21 on the inside, the windings of which are connected to the remote drive 15 . About the protruding from the outer wall 17 end 23 of the core 20 , an outer coil 24 is inserted, which is connected to a feed device 25 , which is provided by the energy supply company.

If the remote drive 15 is now to be actuated, then the appropriately trained and preformed coil 24 is inserted over the end 23 in the direction of arrow E and the remote drive 15 is actuated via this coupling.

Instead of making the core 20 rod-shaped, a U-shaped core 30 , see FIG. 3, can also be provided, around the cross bar 31 of which an inner coil 32 is wound, the free ends of which are connected to the drive 15 . The legs 33 and 34 of the U-shape reach through the wall and each protrude from the wall with one end 35 and 36 . Legs 37 and 38 of an outer core 39 are placed against the ends 35 and 36 , around the web 40 of which an outer coil 41 is wound, which is connected to the supply device 25 provided by the utility company.

As can be seen from FIG. 3, the free end faces of the legs 37 and 38 are placed against the free end faces of the ends 35 and 36 . For simplification, a centering device can be provided both in the arrangement according to FIG. 2 and according to FIG. 3, so that the coil 24 is correctly inserted over the end 23 and the core 39 can be correctly assigned to the core 30 .

FIG. 4 shows a simplified embodiment. On the inside of the building wall 17 , only a coil 42 is provided, the free ends of which are connected to the drive 15 . This coil 42 is assigned an outer coil 43 or brought near it, which is connected to the energy supply device 25 . The energy transfer takes place simply via the field 44 penetrating both coils.

In the arrangement according to FIG. 6, the coil 42 is inserted into an opening 45 on the inner surface of the house wall 17 , so that the distance d between the two coils 42 and 43 is only a fraction of the total thickness of the wall 17 .

As can be seen from FIG. 5, there is also the possibility of providing coils 50 on the inside and 51 on the outside, each of which is wound around a core 52 and 53 . The coil 50 is connected to the remote drive 15 and the coil 51 to the device 25 .

FIGS. 7 and 8 show different coil configurations. Both are spiral-shaped coils, the coil 70 according to FIG. 7 covering a rectangular area and the individual windings 71 being rectangular, whereas the coil 80 is circularly spiral. The coils of FIG. 7 and 8 can thereby be so probably also used as indoor as the outer coils. This is illustrated by the fact that the ends of the coils 70 and 80 can be connected to the drive 15 or to the drive 25 .

To improve the coupling properties, these coils can also have multiple layers be executed.

Is used instead of inductive transmission units for energy and / or control Si gnal microwave units, so the coupling via hollow and / or planaran tennen. Here, such a strong bundling is possible that for outside the Wall standing people a hazard is impossible. Since the actuation from au This only takes place if the EVU representative does not find anyone in the building To drive only little shielding effort inside.

Claims (15)

1. Electrical building installation system, in particular Hausinstallationsan location, with a switchable arrangement or fuse arrangement, with the switching off and on and the protection of the entire network within the building can be carried out, characterized in that the switching off and on again by means of a wireless from outside the Building controllable remote drive ( 15 ) can be actuated and / or can be supplied with energy. 2. Installation system according to claim 1, in which a backup by a A fuse, preferably an NH fuse, is characterized, that the NH fuse is assigned a disconnector, which is by means of the remote operator can be actuated. 3. Installation system according to claim 1, in which the backup fuse by a Main circuit breaker is effected, characterized in that the remote drive is assigned to the main circuit breaker. 4. Installation system according to claim 3, characterized in that on the inside of the building wall ( 17 ) an inner coil ( 22 , 32 , 42 , 50 , 70 , 80 ) is provided, which with an externally applied outer coil ( 24 , 41 , 43 , 51 , 70 , 80 ) interacts. 5. Installation system according to claim 4, characterized in that the Spu len are designed as flat spiral coils ( 70 , 80 ) with a rectangular or approximately circular cross-section. 6. Installation system according to claim 4, characterized in that the Spu len are designed as helically wound coils ( 22 , 24 ; 32 , 41 ; 50 , 51 ). 7. Installation system according to claim 6, characterized in that the middle salmon of the inner and outer coils are aligned. 8. Installation system according to claim 7, characterized in that little least the inner coil ( 42 ) is inserted into a recess ( 45 ) on the inner surface of the building wall ( 17 ). 9. Installation system according to one of the preceding claims, characterized in that the coils ( 22 , 24 ; 32 , 41 ) are coupled by means of a core ( 20 , 30 , 39 ) passing through the building wall ( 17 ). 10. Installation system according to claim 9, characterized in that the core ( 20 ) is rod-shaped and the outer coil ( 24 ) on the outer surface of the wall ( 17 ) projecting end ( 23 ) of the core can be plugged. 11. Installation system according to claim 9, characterized in that the core is divided into two and has a preferably U-shaped inner core ( 30 ) and also preferably a U-shaped outer core ( 39 ), and that the legs of the inner core ( 30 ) the wall ( 17 ) of the building reach through, the legs of the outer core ( 38 ) being able to be placed against the free ends of the legs ( 33 , 34 ) of the inner core. 12. Installation system according to claim 7, characterized in that the cores ( 30 , 39 ) is composed of transformer sheets. 13. Installation system according to one of the preceding claims, characterized records that for the application of the outer coils or the outer cores centering directions are provided. 14. Installation system according to claim 1 or 2, characterized in that the control of the remote drive and the energy supply with radio waves preferably microwaves.   15. Installation system according to claim 14, characterized in that the Coupling of the microwaves via strongly bundling concave and / or planaran tennen takes place.