DE20313083U1 - Magnetic field investigation device for detecting, visualizing and documenting the effects of a magnetic field on a metallic test component, e.g. a utility meter, magnetic field sensor or magnetic data medium - Google Patents

Abstract

Device for detecting, visualizing and documenting the effect of a magnetic field on a metallic component comprises an element (24) with permanent magnetic properties that can be applied to the metallic component (22). Typically the element comprises a film in which magnetic metallic particles are embedded or in some other way attached.

Description

Applicant:

Peter Welter GmbH & Co. KG

Device for detecting, visualizing and documenting magnetic influences

The invention relates to a device for detecting, visualizing and documenting magnetic influences on a metallic or magnetic component that can be influenced by a magnetic field or on magnetic field-sensitive sensors. A metallic component is understood to be, for example, the meter of a consumer product. A magnetic component is understood to be, for example, a data carrier such as a magnetic tape. A magnetic field-sensitive sensor is understood to be, for example, a Hall sensor for controlling processes.

Electrical, electronic, magnetic, magnetizable and magnetic field-sensitive components are increasingly used in industry, commerce, computer and medical technology and also in people's private lives.

To the extent that these components, in particular the latter, are also used to store data or to measure, for example to measure the consumption of electricity or water, the possibility and also the temptation to influence these components with the help of permanent magnets and electromagnets in order to falsify or delete stored data or to influence the measurement of electricity or water consumption to the detriment of the supplier and to the benefit of the consumer increases.

Magnetic field-sensitive sensors built into highly sensitive safety systems can be deliberately influenced using permanent or electromagnets. This means that an airbag can be deliberately and maliciously triggered, thereby causing an insurance claim.

There is at least one electricity meter in every household and every business. An electricity meter contains, among other things, a meter disk that rotates when electricity is drawn and is visible from the outside through a window. This is generally made of aluminum. It also contains at least one drive disk that is not visible from the outside. Electromagnets are arranged around its circumference to drive it. When measuring three-phase current, three electromagnets are provided in the phases. When current flows, they generate electromagnetic fields. These act on the drive disk and set it in rotation. The meter disk is subject to the influence of a permanent magnet arranged on its circumference. This is used to adjust the electricity meter. When a permanent magnet approaches the electricity meter, it acts on the electromagnets and the drive disk. The magnetic field it induces overlaps more or less, depending on the saturation of the yoke, with the alternating electromagnetic fields generated by the electromagnets, thereby reducing the drive of the meter disk. For the permanent magnet used for adjustment, the drive disk runs faster or slower depending on its polarity.

An electricity consumer who apparently wants to reduce his electricity consumption moves and shifts at least one permanent magnet on the housing until he detects a decrease in the rotation speed of the meter disk and the electricity meter therefore indicates a lower electricity consumption.

Permanent magnets with high remanence have been on the market for several years. They consist of a high-energy magnetic material. This is a neodymium iron boron compound. Permanent magnets made of these compounds are available on the market at low prices.

The electricity suppliers are interested in means that prevent manipulation of their electricity meters or that can detect manipulation or fraud when reading the consumption on the electricity meter. They prefer a testing device that can be produced inexpensively and without high technical expenditure.

nical and easy to use and provides reliable evidence.

Based on this, the object of the invention is to find a way to prevent manipulation or fraud or to detect manipulation that has taken place or fraud that has been committed.

In solving this problem, the invention makes use of commercially available means. One means is a permanent magnet material, which is sold as a magnetic foil or magnetic molding. A magnetic foil is a plate or strip material based on an elastomer plastic matrix with a sufficiently high filling level of embedded permanent magnet particles. The magnetic foils are sold magnetized or non-magnetized. Magnetized magnetic foils generally have a typical or directed magnetization. The magnetization runs, for example, along straight and parallel lines. Another means is the so-called polar transparent foil. This is a plastic foil with movably embedded metal particles that are visible from the outside, generally nickel particles. When a polar transparent foil is placed in a magnetic field, the metal particles align themselves with it. They show the course of the magnetic field lines. This allows the course and, if necessary, a change in the course of the magnetic field lines to be recognized with the naked eye.

The solution to the problem mentioned is achieved according to the invention in a device of the type mentioned at the beginning by an element (magnetic foil) that is placed on the metallic component to be examined and has magnetically influenceable permanent magnetic properties. This element is magnetized or demagnetized when a person brings a permanent magnet to the component with the intention of disturbing or cheating.

The manipulated magnetic state can later be detected using a polarizing film. According to the invention, this polarizing film is placed on top of the magnetic film. The polarizing film can be removable or permanently attached to the magnetic film.

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If the owner of the component to be examined and protected, for example a computer, or an electricity meter reader wants to determine whether a person with a permanent magnet has approached the computer or the electricity meter sufficiently to tamper with it, he can use the polarity transparency film to determine whether the original magnetic state of the magnetic film has changed or not.

For an electricity supplier, this means that the electricity meter reader not only recognizes and records the meter reading, but also uses the polarity film to determine whether the customer has tampered with the meter using a permanent magnet. It is up to the electricity supplier whether they give the electricity meter reader a polarity film that they place on the meter or the magnetically influenced element, or whether the polarity film is placed permanently on or in the electricity meter. The electricity meter reader only needs to know whether and what type of magnetization the magnetically influenced element had when the electricity was last read. The invention offers the possibility of installing or attaching the magnetically influenced element to the electricity meter either unmagnetized or after magnetization with a recognizable pattern. When reading the electricity meter, the reader can see whether tampering has taken place by looking at the polarity film.

Irrespective of the application of the invention to a computer, an electricity meter or another magnetically influenced component to be examined, the invention proposes in a particular embodiment that the component to be examined is composed of sections of different remanence, consists of an Fe steel or is used for shielding.

If a component is to be examined and is made up of sections with different remanences, manipulation or influencing with a permanent magnet will have a different effect on each section. The polarizing film therefore shows different deviations from the original magnetization. This allows conclusions to be drawn about the strength of the permanent magnet used by the person who interfered or cheated and the extent of the cheating.

In the particular application of the invention to an electricity meter, the component to be examined is the electric drive of an electricity meter in combination with a magnetic foil attached in front of it. According to the invention, the magnetic foil can rest on the outside or also on the inside of the window of the electricity meter and be attached to it.

Attaching it to the outside is easier. However, anyone can remove the magnetic foil. One of the possibilities offered by the invention is that a magnetic foil and a polarizing film are placed together on the inside of the window. The magnetic foil can also be attached to the housing on its own. It is up to the electricity supplier to permanently store the polarizing film in the meter or to give it to the electricity meter reader. In the first case, the electricity consumer is more deterred from tampering with the meter. The change in the magnetization of the magnetic foil that he has caused can then be recognized immediately by the resulting change in the polarizing film.

Further embodiments of the invention form the subject matter of the subclaims.

The invention is further described using the example of the embodiments shown in the drawing. In the drawing:

Fig. 1 is a schematic perspective view of the basic form of the invention with the component to be examined and a superimposed, magnetically influenced element, in the example shown a magnetized magnetic foil,

Fig. 2 a view similar to Fig. 1 showing an applied interference magnet,

Fig. 3 a view similar to Fig. 1 with additional polarizing foil and representation of the disturbance of the magnetization of the magnetic foil by the

interference magnets,

Fig. 4 is a view similar to Fig. 1 of the embodiment with the polarizing film permanently in place, the solid lines indicating that the polarizing film indicates the magnetization of the magnetic film,

Fig. 5 is a view similar to Fig. 4 showing the disturbance of the magnetization of the magnetic foil by a disturbing magnet,

Fig. 6 is a view similar to Fig. 5 with a component to be examined divided into three sections of different remanence and coercive field strength,

Fig. 7 is a view similar to Fig. 2 with a non-magnetized magnetic foil, i.e. without the lines indicating magnetization,

Fig. 8 is a view of the embodiment shown in Fig. 7 after magnetization of the magnetic foil with the interference magnet and with the polarizing foil on top indicating this magnetization,

Fig. 9 a schematic section through an embodiment with a component made of Fe-steel,

Fig. 10 a view of the component to be examined with a magnetically influenced element made of a metal elastomer film with a permanent magnetic coating,

Fig. 11 a view of the component to be examined with a magnetically influenced element made of steel foil,

Fig. 12 a view of the component to be examined with a magnetically influenced element consisting of steel molded parts,

Fig. 13 a view of the component to be examined with a magnetically influenced element with a printed surface,

Fig. 14 a view of the component to be examined with a magnetically influenced element having recesses,

Fig. 15 a view of the component to be examined with a magnetically influenced element made up of sections of different remanence,

Fig. 16 is a schematic front view of an electricity meter designed according to the invention with a special representation of the drive disk and an interference magnet,

Fig. 17 a view into the interior of the housing of the electricity meter, seen essentially along the section line XVII - XVII in Fig. 16,

Fig. 18 is a partial view essentially of the polarizing film in the direction of arrows XVIII- XVIII in Fig. 17 and

Fig. 19 is a view similar to Fig. 18 in the case of a disturbance of the magnetic field.

Figures 1 to 3 show the same embodiment with the component 22 to be examined, with the magnetically influenced element, a magnetized magnetic foil 24, with the dashed, invisible magnetization lines 26, with the interference magnet 28 and with the polarization film 30 with a magnetically disturbed area 32 that can be seen in Fig. 3. It is assumed that the component 22 to be examined is a metallic plate, for example the housing base of a computer hard disk. The magnetic foil 24 resting on it is magnetized to form the parallel lines 26. When the interference magnet 28 is placed on it and pushed back and forth along the arrows shown in Fig. 2, the magnetization of the magnetic foil 24 is disturbed. The polarization film 30 shows the disturbed area 32 that is created. In practice, the processes take place in such a way that a stranger touches the interference magnet 28.

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over the component 22 to be examined and thus over the magnetic foil 24. This disturbance or impairment of the functioning of the component 22 can be recognized later by its owner or the owner of a PC by placing the polarizing foil 30 and displaying the disturbed area 32.

Figures 4 and 5 show the embodiment with the polarizing film 30 firmly attached to the magnetic film 24. The magnetization lines 34 are visible in this. They indicate the pre-magnetization of the magnetic film 24. Fig. 4 shows its undisturbed magnetization. Fig. 5 shows the magnetization after a magnetic disturbance with the formation of the magnetically disturbed region 32. Fig. 6 shows an embodiment derived from the embodiment according to Figures 4 and 5, in which the component 22 to be examined consists of three sections 36, 38 and 40 of different remanence. Fig. 6 also shows a magnetically disturbed region 32. This is created after the disturbance magnet (not shown) is moved over the polarizing film 30 in the direction of the dashed arrows.

Fig. 7 shows an embodiment with the component 22 to be examined and the magnetic foil 24 on top. This is not magnetized. Therefore, magnetization lines are not shown. Fig. 7 shows a disturbance magnet 28. A person moves this back and forth in the direction of the arrows. This magnetizes the magnetic foil 24. The polarization foil 30 placed on top in Fig. 8 shows this magnetization as a disturbed area 32.

Fig. 9 shows an embodiment made of a Fe-steel 44, a magnetic foil 24 lying on top of it and a polarizing foil 30 lying on top of it.

Figures 10 to 15 show a component 22 to be protected with a magnetically influenced element in various embodiments. In the embodiment according to Fig. 10, this consists of a metal elastomer film 46 with a permanent magnetic coating, for example a magnetic film 48. In the embodiment according to Fig. 11, it consists of a steel film 50 with an adhesive 52 attached to its underside and the magnetic film 48 attached to the top. In the embodiment according to Fig. 12,

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It consists of steel molded parts 54 that are a short distance apart from one another, again with the magnetic foil 48 attached to the top. The steel molded parts 54 are attached to the component 22 to be examined with an adhesive 52. There are predetermined breaking points 56 between the steel molded parts 54. These make manipulation more difficult. An attempt to pull off the magnetically influenced element, for example the magnetic foil 48, is immediately recognized. In the embodiment according to Fig. 13, the magnetically influenced element, for example again a magnetic foil 48, has a printable surface 58. In the embodiment according to Fig. 14, the magnetically influenced element, the magnetic foil 48, has recesses 60. In the embodiment according to Fig. 15, it consists of sections 62 of different remanence.

Fig. 16 shows the electricity meter 64 with the housing 66, a window 68 provided in it and the shaft 70 running vertically in the housing. This carries the meter disk 72 visible through the window 68 and the invisible drive disk 74. Fig. 17 also shows the two bearings 76 of the shaft 70. Fig. 17 also shows one of the adjustment magnets 78 arranged on the circumference of the meter disk 72 and enclosing it and the electromagnets 80 in the three phases for driving the drive disk 74. Fig. 17 also shows a magnetic foil 24 attached to the outside of the housing 66 and a polarity transparency foil 30 attached above it. An electricity consumer who wants to manipulate his electricity meter 64 moves the interference magnet 28 back and forth in the direction of the arrows shown in Fig. 16 until he notices that the meter disk 72 is rotating more slowly. Then the magnetic field emanating from the interference magnet 28 is superimposed on the alternating electromagnetic field of the electromagnets 80 in such a way that the drive disk 74 rotates more slowly.

Fig. 18 shows a top view of the polarity film 30 and the drive disk 74 located behind it before a disturbance by the disturbance magnet 28. Fig. 19 shows the same after a disturbance with the disturbance magnet 28. The magnetization lines of the polarity film 30 are bulged and indicate a disturbance and thus manipulation by the power consumer.

Claims (25)

1. Device for detecting, visualizing and documenting the magnetic influence of a metallic component or a metallic component that can be influenced by a magnetic field, characterized by an element ( 24 ) resting on the metallic component ( 22 ) to be examined and having magnetically influenceable permanent magnetic properties. 2. Device according to claim 1, characterized by a polarizing film ( 30 ) resting on the element ( 24 ). 3. Device according to claim 2, characterized in that the polarizing film ( 30 ) is removable. 4. Device according to claim 2, characterized in that the polarizing film ( 30 ) is firmly attached. 5. Device according to claim 1, characterized in that the component ( 22 ) is not magnetized. 6. Device according to claim 1, characterized in that the component ( 22 ) is magnetized with a recognizable pattern. 7. Device according to one or more of claims 1 to 6, characterized in that the component to be examined ( 22 ) is composed of sections ( 36 , 38 , 40 ) of different remanence and coercive field strength. 8. Device according to one or more of claims 1 to 7, characterized in that the component to be examined consists of Fe steel ( 42 ). 9. Device according to one or more of claims 1 to 8, characterized in that the component to be examined ( 22 ) is a counting device for a consumable product with a housing ( 66 ) in combination with an element ( 24 ) resting on the latter and capable of being influenced magnetically. 10. Device according to one or more of claims 1 to 9, characterized in that the magnetically influenceable element ( 24 ) is a magnetic foil. 11. Device according to one or more of claims 1 to 9, characterized in that the magnetically influenceable element is a metal elastomer film ( 46 ) with a permanent magnetic coating ( 48 ). 12. Device according to one or more of claims 1 to 9, characterized in that the magnetically influenceable element is a steel foil ( 50 ) with an adhesive ( 52 ) provided on its underside. 13. Device according to one or more of claims 1 to 9, characterized in that the magnetically influenceable element consists of molded steel parts ( 54 ). 14. Device according to one or more of claims 1 to 9, characterized in that the magnetically influenced element ( 24 ) has predetermined breaking points ( 56 ). 15. Device according to one or more of claims 1 to 9, characterized in that the magnetically influenced element ( 24 ) has a printable surface. 16. Device according to one or more of claims 1 to 9, characterized in that the magnetically influenced element ( 24 ) has recesses ( 58 ). 17. Device according to one or more of claims 1 to 9, characterized in that the magnetically influenced element ( 24 ) has sections ( 62 ) of different remanence. 18. Device according to claim 9, characterized in that the housing ( 66 ) has a window ( 68 ) and the magnetically influenced element ( 24 ) rests on the latter. 19. Device according to claim 18, characterized in that the magnetically influenced element ( 24 ) rests on the inside of the window ( 48 ). 20. Device according to claim 18, characterized in that the magnetically influenceable element ( 24 ) rests on the outside of the window ( 48 ). 21. Device according to claim 19, characterized in that the magnetically influenceable element ( 24 ) rests together with a polarizing film ( 30 ) on the inside of the window ( 48 ). 22. Device according to claim 18, characterized in that the magnetically influenceable element ( 24 ) is fixedly mounted on the window ( 48 ). 23. Device according to claim 9, characterized in that the counting device is an electricity meter ( 64 ). 24. Device according to claim 9, characterized in that the counting device is a gas meter. 25. Device according to claim 9, characterized in that the counting device is a water meter.