DE102005037794B4 - Grounding system for buildings - Google Patents

Abstract

Grounding device for grounding of buildings consisting of a copper pipe system connected to a ground line, characterized in that at least two pipes to be grounded (1, 2) arranged in the ground and both are conically shaped such that each one is cone-shaped tapered Spiral forms, with one of the pipes (1) about its axis (6) towards its spiral tip (5) counterclockwise, the other pipeline (2) about its axis (8) clockwise to its spiral tip (10), and that both pipes (1, 2) are connected to each other so that both base surfaces (4, 9) which is conical tapering Piping spirals (1, 2) adjoin one another and the spiral tips (5, 10) in opposite directions.

Description

The The invention relates to a grounding device for grounding of buildings, consisting from a copper pipe system connected to a ground line.

The grounding device is not used solely for the derivation of surges in electrical Supply lines of gestures, the example connected as a result of defects electrically operated devices or generated by lightning strike, but also for dissipation so-called electrosmogs, namely electromagnetic or electrostatic fields causing health hazards can.

Such devices are known. A device of this kind is disclosed in the publication DE 103 19 291 A1 described. The device specified there has a hollow-walled water chamber and within the water chamber to an air chamber. The hollow wall of the water chamber is formed by copper tubes, which are respectively disposed adjacent and radially aligned with the center of the water chamber. The tubes are filled with water and form a water jacket surrounding the air chamber. The water chamber is connected to a ground line. With this complex in construction, although portable device is a wide range of different types of radiation efficiently absorbed and derived in the soil to cancel the negative effect of the rays.

It is known to protect against electrosmog from the utility model DE 202 13 792 U1 also a device designed as a resonator for electromagnetic longitudinal waves. Pipe made of acrylic glass is used, of which a centrally-guided pipe has a tube cross-section which changes periodically over the pipe length. The shape of the tubular jacket is thus characterized by successive extensions and constrictions, wherein a Möbiusschleife is provided in each case in the region of a maximum and in the region of a minimum diameter of the tubular jacket. All Möbius loops are electrically connected to each other at their crossing points. With this very complex in its construction device is to be achieved in resonance with longitudinal waves and as a result of the generated electrical effects by using the Möbiusschleifen shielding against electrosmog, resulting in particular by selecting specific filling material for acrylic pipes, namely by means of a special mineral mixture, a shield even before harmful radiation can affect the human body.

In US 59 15 998 731 A a grounding device is described in which are used to dissipate electrical surges peak discharges. The guided into the ground ladder have single or more adjacently arranged needle-like ending or sharp-edged trained ladder parts are derived via the stresses in the ground.

As resonance absorption device is in the utility model DE 91 02 248 U1 also indicated a conically tapered spiral.

task The invention is a relatively simple in their technical structure Earthing device for effective dissipation of electrical surges to create that without much effort and in a simpler way Way to handle and is expert can be used.

These Task is in a grounding device of the type mentioned solved by the features specified in claim 1. After that, the grounding device at least two pipes to be grounded on the ground and arranged both are so conically shaped that each one is essentially one conical tapered Spiral forms, with one of the pipelines about its axis to its Spiral tip pointing to the left, the other pipeline around its axis runs clockwise to its spiral tip. The two pipes are connected to each other so that both base surfaces of conical tapering Piping spirals adjoin one another and the spiral tips in each case pointing in opposite directions. In this training will assumed that the spiral shape and the direction of rotation of the Spirals positively influenced the dissipation of electric fields by grounding and that a grounded by means of the device according to the invention building on this way of existing annoying ones electrostatic and electromagnetic fields kept free becomes. When used in the soil according to claim 2, the left-handed Pipe spiral above the clockwise spiral pipe arranged. It is then assumed that the lower clockwise Pipeline spiral essentially as a lightning conductor and arrester from creeks or reactive current acts while the above the clockwise pipe spiral arranged left-handed Pipeline spiral rather eliminates electrosmog.

Around to strengthen the grounding effect, is at the spiral tip of the clockwise spiral pipe a copper grounding rod attached, claim 3.

Of importance for the protection of the building and a safe dissipation of disturbing electrical Fields is to fill the dextrorotatory pipe spiral with a solution containing distilled water and silicon, claim 4. Such a solution increases the electrically effective potential of the lower ground mounted clockwise spiral pipe. Preferably, the solution according to claim 5 consists of 2 parts of water and 1 part of silica.

to support the dissipation of electrical surges through the left-turning pipe spiral, this is with EM material filled, Claim 6. EM material is an efficient microorganism mixture, which has a ph value below 3 and thus has an antioxidant effect. EM material is z. B. in the publication "EM" by Franz Peter Mau described, Verlag Wilhelm Goldmann, 2002. Specifically exists the introduced into the levorotatory pipe spiral EM material from liquid EM material, known as EM1, and EM powder, wherein 2 parts EM liquid and 1 part of EM powder are mixed together, claim 7. As EM powder is especially EM (x) ceramic powder because of its special Influence on electrostatic and electromagnetic fields used.

The inside rooms the pipeline spirals are delimited against each other. To their Conclusion the pipe spirals are closed at their ends, Claim 8. To set up the pipe spirals and To facilitate their transport, the spirals run preferentially at their base surfaces just out, claim 9. In this case, the base surfaces according to claim 10 a Diameter at least 50 cm, maximum 100 cm. Also at the spiral tips the pipe spirals are essentially just trained, for the last spiral winding is a diameter of 25 cm appropriate, Claim 11.

Prefers is for the piping spirals according to claim 12, a slope of at least 8 cm, maximum 15 cm provided. According to claim 13 are for fixing the pitch between the pipe spirals plastic rods used. Considering the dimensions of the global mesh network known as the Hartmann grid, as it is z. B. in the publication "Radiation fields" by Luise Weidel, Astro Mirror Publishing, Stolberg, 2002, the total height is one the interconnected piping spirals at least 110th cm, leaving the complete grounding device with both pipe spirals spatially from a Hartmann grid after its use in the soil corresponding Hartmann cube in an adjacent cube area protrudes.

The Invention and further advantageous embodiments of the invention will be described below with reference to a schematically illustrated in the drawing embodiment explained in more detail.

The drawing shows a grounding device for earthing a building. The earthing device consists of a copper pipe system, which in the exemplary embodiment two firmly connected pipes 1 . 2 having. Each of the pipes forms a conically tapering spiral, analogous to a spiral spring, which tapers conically, wherein the pipes extend spatially starting from a base radius of curvature 3 continuously decreasing radii of curvature out. One of the pipes, in the exemplary embodiment, the pipeline 1 , is from their base area 4 to the spiral tip 5 seen around its axis 6 counterclockwise (in the drawing, the direction of rotation of the pipeline 1 with reference number 7 marked), the other pipeline, the pipeline 2 , is around her axis 8th that in the game of execution with the axis 6 the pipeline 1 coincides, from its base area 9 seen to the spiral tip 10 out clockwise (in the drawing, the direction of rotation of the pipe 2 with reference number 11 marked).

The two pipes 1 . 2 According to their shape, they will be referred to below as left-handed pipe spirals 1 or as a clockwise spiral pipe 2 designated.

The base areas 4 . 9 form in the embodiment open spaces. Both pipeline spirals 1 . 2 each run tangentially into their base surfaces.

In the embodiment, the axes 6 and 8th the pipeline spirals 1 . 2 perpendicular to the base surfaces 4 and 9 arranged.

To form the grounding device, the pipe spirals 1 . 2 at their base surfaces 4 . 9 set against each other and firmly connected together so that the spiral tips 5 . 10 the pipeline spirals 1 . 2 each pointing in opposite directions. In this arrangement, the spirals of both pipes extend with respect to their superimposed base surfaces 4 . 9 mirror images of each other. It is expected that they will work optimally on electrostatic and electromagnetic interference fields.

If the grounding device is grounded, the left-hand spiral is spiral 1 above the clockwise spiral pipe 2 to arrange. At the spiral top 10 the clockwise pipe spiral 2 is a grounding rod 12 attached, which allows a dissipation of electrical voltages in deeper soil.

The pipe interiors of both pipe spi eral 1 . 2 are completed against each other. The pipes form a two-dimensional, non-permeable pipe system. Both piping spirals can be filled independently of each other. In the embodiment, the clockwise, lower in the ground lower piping spiral 2 with an aqueous solution of distilled water and silica, the left-hand top pipe spiral 1 filled with EM material. Silicon oxide in amorphous form can be used to produce the electrically conductive silicon solution. EM material whose essential ingredient is efficient microorganisms is z. As described in the already mentioned publication "EM" by Franz Peter Mau, Verlag Wilhelm Goldmann, 2002. EM material is a microorganism mixture that has a pH below 3 and thus an antioxidant effect. Specifically, this is in the pipe spiral 1 introduced EM material in the embodiment of liquid EM material, which is known under the name EM1, and EM powder, wherein 2 parts EM liquid and 1 part EM powder are mixed together. As an EM powder in particular EM (x) ceramic powder is used because of its special influence on electrostatic and electromagnetic fields.

After filling the pipe spirals 1 and 2 All pipe ends left open for filling are closed.

The mixing ratios and proportions of each in the two pipe spirals 1 . 2 material to be filled are adjusted substantially in terms of viscosity in order to facilitate the filling of the pipe spirals. Thus, an aqueous solution of 2 parts of distilled water and 1 part of silica, in the exemplary embodiment fumed silica, in the dextrorotatory upper pipe spiral in the dextrorotatory, lower in the ground lower pipe spiral 2 in the left-handed upper pipe spiral 1 a mixture of 2 parts of liquid EM material, EM1, and one part of EM powder, in particular EM (x) ceramic powder filled. To stabilize the organic EM material in the pipeline spiral 1 even over longer periods of operation of the grounding piping system, the piping system is sealed gas-tight, an oxygen supply to the EM material should be prevented.

In the exemplary embodiment, both pipe spirals 1 and 2 an outer diameter of 18 mm, the wall thickness of the tubes is 1.5 mm. On the one hand, the pipelines are dimensioned so that they can be filled with the intended fillers without considerable effort. In particular, the highly viscous silicon solution is to be considered here. On the other hand, the ductility of the pipelines must be ensured to conically tapered pipe spirals. This is why pipelines with smaller outside diameters, for example 16 or 12 mm, are also suitable.

To fasten both pipe spirals together the pipe spirals run 1 . 2 at their base surfaces 4 . 9 each as a flat support ring 13 . 14 out, so that they are aufrechetzbar. The support rings are not executed completely closed in the embodiment. The pipe spirals are brazed together for attachment. The bearing rings 13 . 14 have a diameter D of at least 50 cm, the base radius of curvature 3 is therefore 25 cm. At most, the diameters D should not be greater than D = 100 cm. The spiral tips of the pipe spirals run as a flat Auflageringe 15 . 16 from, their diameter d is 25 cm in the embodiment.

In the exemplary embodiment, the individual spirals of the piping systems have a pitch of 10 cm in the axial direction. At least the pitch of the pipe spirals is 8 cm in order to be able to bring in sufficient soil between the spiral turns. Maximum should not be more than 15 cm slope. To fix this slope are between the pipe spirals 1 . 2 Plastic rods 17 used as spacers, which are clamped between the pipe spirals. For fixing the spacers to the pipe spirals, simple pipe clamps can be used. The total height 18 one of the pipe spirals from the support ring to the spiral tip is 110 cm. The interconnected piping spirals therefore project beyond the dimensions of a Hartmann cube (dimension about 2.5 × 2.5 × 2.0 m ³ ), wherein the grounding device in the ground is preferably arranged centrally within a Hartmann cube. The length of the grounding rod 12 in the exemplary embodiment is 40 cm.

From the building to be grounded grounding device according to the invention in the ground at a distance of at least 10 m away and connected to the ground wire of the building. In this way, a feedback and re-influencing the building to be grounded is to be avoided. If larger distances from the building are chosen for the arrangement, the grounding cables must have a correspondingly lower electrical resistance in order to facilitate the accelerated discharge of building up electrical voltages. Preferably, the grounding device is used in the ground north of the building to be grounded. The distance to a water core is at least 30 m, so that any negative influence of the grounding device on the water core may be minimized can.

The interconnected pipe spirals are to be introduced into the soil so that the spiral tip 5 of the upper left-hand spiral pipe spiral 1 After completing the earthworks, cover with a layer of earth at least 10 cm thick and no more than 25 cm high. After inserting the pipe spirals into the ground bulk material to be filled around and in the space between the pipe spirals EM microorganisms and especially at the bottom of adsorptive and catalytic charcoal added to the activity of the microorganisms in the soil in the vicinity of the grounding device again to liven up. It is also advantageous for environmental reasons, when the required excavation for insertion of the grounding device when inserting again filled in the same layers around the pipe spirals and sandwiched in layers.

in the and the grounded network of the building connected to the grounding device according to the invention is, can be at least partially avoid metal oxidation, if necessary, achieve reductions. Shall be stronger electric and electromagnetic Fields are derived, it may be appropriate to several grounding devices adjacent to arrange and switch in parallel.

1, 2

Pipelines thereof left-handed piping spiral 1 clockwise spiral pipe 2

3

Base curvature radius

4

footprint

5

spiral tip

6

axis

7

direction of rotation Left

8th

axis

9

footprint

10

spiral tip

11

direction of rotation Right

12

ground rod

13 14, 15, 16

Support rings

17

Plastic rods

18

total height

Claims (20)

Grounding device for grounding buildings consisting of a connected to a ground wire copper pipe system, characterized in that at least two pipes to be grounded ( 1 . 2 ) are arranged in the ground and both are conically shaped such that each forms a conically tapered spiral, wherein one of the pipelines ( 1 ) about its axis ( 6 ) to its spiral tip ( 5 ) counterclockwise, the other pipeline ( 2 ) about its axis ( 8th ) to its spiral tip ( 10 ) clockwise, and that both pipes ( 1 . 2 ) are interconnected so that both base surfaces ( 4 . 9 ) of conically tapered pipeline spirals ( 1 . 2 ) and the spiral tips ( 5 . 10 ) in opposite directions. Grounding device according to claim 1, characterized in that the levorotatory pipe spiral ( 1 ) in the soil above the clockwise spiral ( 2 ) is arranged. Grounding device according to claim 2, characterized in that the clockwise-rotating pipeline spiral ( 2 ) at its spiral tip ( 10 ) a grounding rod ( 12 ) of copper. Grounding device according to claim 1, 2 or 3, characterized in that the right-handed spiral pipe ( 2 ) is filled with a silicon-containing aqueous solution. grounding device according to claim 4, characterized in that the solution of consists of two parts of distilled water and one part of silica. Grounding device according to one of the preceding claims 1 to 5, characterized in that the levorotatory pipe spiral ( 1 ) is filled with EM material. grounding device according to claim 6, characterized in that for the filling with EM material EM1-liquid and EM powder can be used, in particular two parts EM1 liquid and a part of EM powder. Grounding device according to one of the preceding claims, characterized in that the pipeline spirals ( 1 . 2 ) are closed at the end of their pipe interiors at their ends. Grounding device according to one of the preceding claims 1 to 8, characterized in that the pipeline spirals ( 1 . 2 ) at their base surfaces ( 4 . 9 ) in support rings ( 13 . 14 ) leak. Grounding device according to claim 9, characterized in that the support rings ( 13 . 14 ) have a diameter which is at least 50 cm, at most 100 cm. Grounding device according to one of the preceding claims, characterized in that Auflageringe ( 15 . 16 ) at the spiral tips ( 5 . 10 ) of the piping spirals ( 1 . 2 ) have a diameter of 25 cm. Grounding device according to one of the preceding claims, characterized in that the pipeline spirals ( 1 . 2 ) with a gradient of at least 8 cm, maximum 15 cm. Grounding device according to claim 12, characterized in that for fixing the pitch between the pipeline spirals plastic rods ( 17 ) serve. Grounding device according to one of the preceding claims 1 to 13, characterized in that the total height ( 18 ) of one of the interconnected piping spirals ( 1 . 2 ) is at least 110 cm. Grounding device according to one of the preceding claims 1 to 14, characterized in that the interconnected piping spirals ( 1 . 2 ) located in the ground at a distance of at least 10 m from the building to be grounded and connected to the grounding cable. Grounding device according to one of the preceding claims 1 to 15, characterized in that the interconnected piping spirals ( 1 . 2 ) are arranged in the ground north of the building to be grounded. Grounding device according to one of the preceding claims 1 to 16, characterized in that the interconnected piping spirals ( 1 . 2 ) are located in the ground at a distance of at least 30 m from a water vein. Grounding device according to one of the preceding claims 1 to 17, characterized in that the interconnected pipeline spirals ( 1 . 2 ) are arranged in the ground centrally in Hartmanngitterkubus. Grounding device according to one of the preceding claims 1 to 18, characterized in that the interconnected piping spirals ( 1 . 2 ) are inserted in the soil such that the spiral tip ( 5 ) of the upper left-rotating pipe spiral ( 1 ) is covered with at least 10 cm, maximum 25 cm high soil layer. Grounding device according to one of the preceding claims 1 to 19, characterized in that when inserting the interconnected piping spirals ( 1 . 2 ) are added into the soil to the bulk EM microorganisms.