• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
  • 引用文献
  • 法律状态
  • 优先权
    • 专利摘要:
    For a grounding device, which not only serves to divert overvoltages in electrical supply lines of buildings, but can also be used to divert so-called electrosmog, at least two pipelines (1, 2) to be grounded are provided, both of which are conically shaped so that is formed essentially conically tapering spiral. One of the pipes runs counterclockwise around its axis towards its spiral tip (Figure pipe 1), the other pipe rotates clockwise around its axis towards its spiral tip (pipe 2). The two pipe spirals are connected to one another in such a way that their base surfaces (4,9) adjoin one another and the spiral tips (5,10) each point in opposite directions. When used in the ground, the left-hand spiral pipe (1) is preferably arranged above the right-hand spiral pipe (2). To increase the discharge of harmful electrical foulers and electrosmog, it is advisable to clean the right-hand spiral pipe (2) with a solution containing distilled water and silicon and the left-hand ...
    公开号:BE1018529A3
    申请号:E2006/0419
    申请日:2006-08-04
    公开日:2011-03-01
    发明作者:
    申请人:Heck Wilfried;
    IPC主号:
    专利说明:

    DESCRIPTION
    Grounding system for buildings
    The invention relates to a grounding device for grounding of buildings, consisting of a connected to a ground wire copper pipe system.
    The grounding device is not only for the derivation of surges in electrical supply lines of buildings, which are generated for example due to defects in-closed electrically operated equipment or by lightning, but also for the derivation of so-called electromagnetic pollution, namely electromagnetic or electrostatic fields that can cause damage to health.
    Such devices are known. A device of this kind is described in Offenegungsschrift DE 103 19 291 A1. 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 designed as a resonator for electromagnetic longitudinal waves device. Acrylic glass tubes are used, of which a centrally guided tube has a tube cross-section which changes periodically over the length of the tube. 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 due to the electrical effects generated by the use of Möbiusschleifen shielding against electrosmog, resulting in particular by selecting specific filler for acrylic pipes, namely by means of a special mineral mixture, a shield even before harmful radiation can affect the human body.
    As a resonance absorption device in the utility model G 9102248.7 also a conically tapered spiral is given.
    The object of the invention is to provide a relatively simple in their technical structure grounding device for the effective dissipation of electrosmog, which is to produce without considerable effort and to handle in a simple manner and can be used expertly.
    This object is achieved in a grounding device of the type mentioned by the features specified in claim 1. Thereafter, the grounding device has at least two pipes to be grounded, which are arranged in the ground and both tapered, each forming a substantially conically tapered spiral, one of the pipes around its axis to its spiral tip counterclockwise, the other pipeline to their axis runs clockwise to their spiral tip. The two pipes are connected to one another such that both base surfaces of the conically tapered pipe spirals adjoin one another and each of the spiral tips point in opposite directions. In this design, it is believed that the helical shape and direction of rotation of the helices positively affect grounding of electric fields and that a building grounded by the device of the present invention is thus kept free of existing interfering electro-static and electromagnetic fields. When used in the soil according to claim 2, the levorotatory pipe spiral is arranged above the clockwise spiral pipe spiral. It can then be assumed that the bottom right-hand spiral pipe substantially acts as a lightning arrester and arrester of creepage currents or reactive current, while the left-hand spiral pipe arranged above the right-handed pipe spiral eliminates electrosmog.
    To reinforce the grounding effect, a grounding rod made of copper is attached to the spiral tip of the clockwise spiral pipe, claim 3.
    Of importance for the protection of the building and a safe dissipation of interfering electric fields is to fill the clockwise spiral with a distilled water and silicon-containing solution, claim 4. Such a solution increases the electrically effective potential of the bottom arranged in the earth right-handed pipe spiral. Preferably, the solution according to claim 5 consists of 2 parts of water and 1 part of silica.
    To support the derivation of electrosmog by the levorotatory pipe spiral this is filled with EM material, claim 6. EM material is an efficient microorganism mixture, which has a pH below 3 and thus has an antioxidant effect. EM material is e.g. in the publication "EM" by Franz Peter Mau, published by Wilhelm Goldmann, 2002. Specifically, the EM material introduced into the levorotatory pipe spiral consists of liquid EM material known as EM1, and EM powder, where 2 Parts EM liquid and 1 part EM powder are mixed together, claim 7. As EM powder in particular EM (x) ceramic powder is used because of its special influence on electrostatic and electromagnetic fields.
    The interiors of the pipe spirals are delimited from each other. At their conclusion are the
    To set up the pipe spirals and to facilitate their transport, the spirals run at their base surfaces preferably flat, claim 9. In this case, the base surfaces according to claim 10 has a diameter of at least 50 cm, maximum 100 cm. Also at the spiral tips the pipe spirals are substantially flat, for the last spiral winding a diameter of 25 cm is appropriate, claim 11.
    Preferably, a pitch of at least 8 cm, maximum 15 cm is provided for the pipe spirals according to claim 12. According to claim 13 plastic rods are used to fix the slope between the pipe spirals. Considering the dimensions of the global mesh network known as the Hartmann grid, e.g. in the publication "Radiation fields" by Luise Weidel, Astro mirror publishing house, Stolberg, 2002, the total height of one of the interconnected pipeline spirals amounts to at least 110 cm, so that the complete grounding device with both
    Pipeline spirals after its use in the soil spatially protrudes from a Hartmann cube corresponding Hartmann cube into an adjacent cube area.
    The invention and further advantageous embodiments of the invention will be explained in more detail with reference to an embodiment schematically illustrated in the drawing.
    The drawing shows a grounding device for earthing a building. The earthing device consists of a copper tube system, which in the exemplary embodiment two firmly connected
    Pipes 1,2 has. Each of the pipes forms a conically tapered spiral, analogous to a spiral spring, dikonisch tapers, wherein the pipes extend spatially starting from a base radius of curvature 3 continuously decreasing radii of curvature out. One of the pipelines, in the exemplary embodiment, the pipeline 1, seen from its base surface 4 to the spiral tip 5 is formed counterclockwise about its axis 6 (in the drawing, the direction of rotation of the pipe 1 is marked with reference numeral 7), the other pipeline, the pipeline 2, is formed around its axis 8, which coincides with the axis 6 of the pipeline 1 in the game of execution, viewed from its base surface 9 to the spiral tip 10 in the right direction (in the drawing, the direction of rotation of the pipe 2 is marked by reference numeral 11).
    The two pipes 1, 2 are referred to below as left-rotating pipe spiral 1 or as right-handed pipe spiral 2 in accordance with their shape.
    The base surfaces 4.9 form in the exemplary embodiment free open areas. Both pipe spirals 1,2 run tangentially into their base surfaces.
    In the exemplary embodiment, the axes 6 and 8 of the pipe spirals 1,2 are arranged perpendicular to the base surfaces 4 and 9.
    To form the grounding device, the
    Pipe spirals 1, 2 set against each other at their base surfaces 4, 9 and firmly connected to each other, so that the spiral tips 5, 10 of the pipe spirals 1, 2 respectively in opposite
    Show directions. In this arrangement, the spirals of both pipes with respect to their superimposed base surfaces 4, 9 are mirror images of each other. It is expected that they will work optimally on electrostatic and electromagnetic interference fields.
    If the grounding device is set in the ground, the left-rotating pipe spiral 1 is to be arranged above the clockwise spiral pipe 2. At the spiral tip 10 of the clockwise spiral pipe 2, a grounding rod 12 is mounted, which allows a dissipation of electrical voltages in deeper soil.
    The pipe interiors of both pipe spirals 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 dextrorotatory, lower in the ground lower pipe spiral 2 is filled with an aqueous solution of distilled water and silica, the left-handed upper pipe spiral 1 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 described e.g. described in the already mentioned publication "EM" by Franz Peter Mau, Verlag Wilhelm Goldmann, 2002. EM material is a microorganism mixture which has a pH below 3 and thus an antioxidant effect. Specifically, the EM material introduced into the pipe spiral 1 in the embodiment consists of liquid EM material known as EM1, and EM powder wherein 2 parts of EM liquid and 1 part of 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 coils 1 and 2, all pipe ends left open for filling are closed.
    The mixing ratios and proportions of each of the two pipe coils 1, 2 to be filled material are adjusted substantially in terms of viscosity in order to facilitate the filling of the pipe spirals. Thus, in the dextrorotatory, deeper in the ground lower pipe spiral 2, an aqueous solution of 2 parts of distilled water and 1 part of silica, in the embodiment fumed silica, 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 pipe spiral 1 over longer
    Operating times of the grounding piping system is the
    Piping system sealed gas-tight, oxygen supply to the EM material should be prevented.
    In the exemplary embodiment both have
    Piping 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 1, 2 run out at their base surfaces 4, 9 in each case as a flat support ring 13, 14, so that they can be stacked up. 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 thus 25 cm. At most, the diameters D should not be greater than D = 100 cm. The spiral tips of the pipe spirals run out as flat support rings 15, 16, 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 spiral 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 1.2 plastic rods 17 are used as spacers between the pipe spirals, 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 of 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 x 2.5 x 2.0 m3), with the grounding device preferably being arranged centrally within a Hartmann cube in the ground. The length of the grounding rod 12 is 40 cm in the embodiment.
    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 vein is at least 30 m, so that any negative influence of the grounding device on the water vein may be kept as low as possible.
    The interconnected pipe spirals are to be introduced into the soil so that the spiral tip 5 of the top left-hand spiral pipe 1 after completion of earthworks can be covered with a minimum of 10 cm, a maximum of 25 cm high layer of soil. After inserting the pipe spirals into the soil 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 and on the grounded network of the building, which is connected to the grounding device according to the invention, can be at least partially avoid metal oxidation, optionally achieve reductions. If stronger electrical and electromagnetic fields are to be dissipated, it may be expedient to arrange several grounding devices adjacent and to connect them in parallel.
    LIST OF REFERENCE NUMBERS
    Pipelines 1,2 thereof left-hand spiral pipe 1 right-handed spiral pipe 2 basic radius of curvature 3 base surface 4 spiral tip 5 axis 6
    Direction of rotation Left 7 Axle 8 Base surface 9 Spiral tip 10 Direction of rotation Right 11 Grounding rod 12 Support rings 13, 14, 15, 16 Plastic rods 17 Overall height 18
    权利要求:
    Claims (20)
    [1]
    1. Erdungsgerät zur Erdung von Gebäuden besthend aus einem an einer Erdleitung angeschlossenen Kupferrohrsystem, dadurch , wobei eine der Rohrleitungen (1) um ihre Achse (6) zu ihrer Spiralspitze (5) hin linksdrehend, that other Rohrleitung (2) um ihre Achse (8) zu ihrer Spiralspitze (10) hin rechtsdrehendend leave, und dass both Rohrleitun 1,2) miteinander so verbunden sind, das both Basicflächen (4, 9) der sich kegelförmig verjüngenden Rohrleitungsspiralen (1,2) aneinander borders und die Spiralspitzen (5, 10) in graftgesetzte Richtungen.
    [2]
    2. Erdungsgerät nach Anspruch 1, dadurch
    charactnzeichnet, dass die linksrehende Rohrleitungsspirale (1) im Erdreich oberhalb der rechtsdrehenden Rohrleitungsspirale (2) angeordnet ist.
    [3]
    3. Erdungsgerät nach Anspruch 2, dadurch
    charactnzeichnet, dass die legend Rohrleitungsspirale (2) an ihrer Spiralspitze (10) einen Erdungsstab (12) aus Kupfer aufweist.
    [4]
    4. Erdungsgerät nach Anspruch 1, 2 or 3, dadurch charactnzeichnet, dass die rendräden Rohrleitungsspirale (2) mit einer Silizium enthaltenden wässrigen Lösung gefüllt ist.
    [5]
    5. Erdungsgerät nach Anspruch 4, dadurch
    charactnzeichnet, dass die Lösung aus 2 Teilen distillation Wasser und 1 TeiI Silizium oxide bestht.
    [6]
    6. Erdungsgerät nach einem der vorhergehenden
    Ansprüche 1 bis 5, dadurch charactnzeichnet, which is left-handed Rohrleitungsspirale (1) mit EM-Material.
    [7]
    7. Erdungsgerät nach Ansprüche 6, dadurch
    characterized, for the Füllung with EM-Material EM1-fluffy and EM-Pulver were spoiled, including 2 Teile EM1-fluffy and 1 Teil EM-Pulver.
    [8]
    8. Erdungsgerät nach einem der vorhergehenden
    Ansprüche, dadurch charactnzeichnet, dass die Rohrleitungsspiralen (1, 2) zum Abschluss ihrer Rohrinnenräume an ihren Enden
    hide sind.
    [9]
    9. Erdungsgerät nach einem der vorhergehenden
    Ansprüche 1 bis 8, dadurch charactnzeichnet, dass die Rohrleitungsspiralen (1,2) an ihren Basisflächen (4,9) in Auflageringe (13,14) auslaufen.
    [10]
    10. Erdungsgerät nach Anspruch 9, dadurch
    charactnzeichnet, dass die Auflageringe (13, 14) einen Durchmesser D aufweisen, der mindestens 50 cm, maximum 100 cm.
    [11]
    11. Erdungsgerät nach einem der vorhergehenden
    Ansprüche, dadurch charactnzeichnet, dass Auflageringe (15,16) an den Spiralspitzen (5,10) der Rohrleitungsspiralen (1,2) a Durchmesser d von 25 cm aufweisen.
    [12]
    12. Erdungsgerät nach einem der vorhergehenden
    Ansprüche, dadurch charactnzeichnet, dass die Rohrleitungsspiralen (1,2) with a steigung von mindestens 8 cm, maximum
    [13]
    13. Erdungsgerät nach Ansprüche 12, dadurch charactnzeichnet, das zur Fixierung der Steigung zwischen den Rohrleitungsspiralen Kunststoffstäbe (17).
    [14]
    14. Erdungsgerät nach einem der vorhergehenden
    Ansprüche 1 bis 13, dadurch charactnzeichnet, dass die Gesamthöhe (18) einer der miteinanderen Rohrleitungsspiralen (1,2) mindestens 110 cm.
    [15]
    15. Erdungsgerät nach einem van de vorhergehenden
    Ansprüche 1 bis 14, dadurch charactnzeichnet, dass die miteinander and Rohrleitungsspiralen (1,2) im Erdreich in einer
    Entfernung von mindestens 10 m vom zu erdenden Gebäude entfernt angeordnet und am Erdungskabel angeschlossen sind.
    15 cm away.
    [16]
    16. Erdungsgerät nach einem der vorhergehenden
    Ansprüche 1 bis 15, dadurch charactnzeichnet, dass die miteinander and Rohrleitungsspiralen (1,2) im Erdreich nördlich des zu erdenden Gebäudes angeordnet sind.
    [17]
    17. Erdungsgerät nach einem der vorhergehenden
    Ansprüche 1 bis 16, dadurch charactnzeichnet, dass die miteinander and Rohrleitungsspiralen (1,2) im Erdreich in einer
    Entfernung von mindestens 30 m von einer Wasserader entfernt angeordnet sind.
    [18]
    18. Erdungsgerät nach einem der vorhergehenden
    Ansprüche 1 bis 17, dadurch charactnzeichnet, dass die miteinander erbundenen Rohrleitungsspiralen (1,2) im Erdreich zentral im Hartmanngitterkubus angeordnet sind.
    [19]
    19. Erdungsgerät nach einem der vorhergehenden
    Ansprüche 1 bis 18, dadurch charactnzeichnet, dass die miteinander and Rohrleitungsspiralen (1,2) im Erdreich derart eingesetzt
    sind, dass die Spiralspitze (5) der oberen linksdrehenden Rohrleitungsspirale (1) mit einer mindestens 10 cm, maximum 25 cm when Erdreichschicht is covered.
    [20]
    20. Erdungsgerät nach einem der vorhergehenden Ansprüche 1 bis 19, dadurch charactnzeichnet, dass beim Einsetzen der miteinander verbunden Rohr-leitungsspiralen (1,2) ins Erdreich dem Schüttgut EM-Mikroorganismen were stopped.
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    同族专利:
    公开号 | 公开日
    FR2891407A1|2007-03-30|
    DE102005037794B4|2008-07-31|
    DE102005037794A1|2007-02-15|
    引用文献:
    公开号 | 申请日 | 公开日 | 申请人 | 专利标题
    DE8333190U1|1983-11-18|1984-04-12|Specker, Bernhard, 8000 München|RADIATION NEUTRALIZATION DEVICE|
    DE4014118A1|1990-05-02|1991-11-14|Schulte Uebbing Ernst Dr|Electromagnetic radiation screening or suppressing equipment - comprising conductive coils for diverting natural and artificial radiation|
    DE9102248U1|1991-02-26|1991-08-29|Specker, Bernhard, 8000 Muenchen, De|
    US5998731A|1997-01-16|1999-12-07|Etsuko Takamura|Absorbed type lightning rod and absorbed type lightning discharging apparatus|
    DE10319291A1|2002-05-03|2003-11-20|Lhk Anstalt Eschen|Earth radiation suppression device comprises a spherical cap mounted over a tank shaped element with the cap connected to an earthing cable for deflecting away interfering radiation originating from crossing sub-soil water flows|
    DE20213792U1|2002-09-04|2002-11-28|Edelmann Gabriele|Protection against electrosmog|
    WO2004103464A1|2003-05-21|2004-12-02|Savo Radovic|Device for continual neutralization of broad electromagnetic spectrum radiation|
    DE8524009U1|1985-08-21|1985-10-10|Michael Geiseler DBF Vertriebs-GmbH, 8000 München|Radiation interceptor|
    法律状态:
    2014-02-28| RE| Patent lapsed|Effective date: 20130831 |
    优先权:
    申请号 | 申请日 | 专利标题
    DE200510037794|DE102005037794B4|2005-08-07|2005-08-07|Grounding system for buildings|
    DE102005037794|2005-08-07|
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