ES1221679U - COMBINABLE MAGNETIC CLOSURE SYSTEM (Machine-translation by Google Translate, not legally binding) - Google Patents

Abstract

Combinable magnetic closure system comprising: - a key (1) comprising: - a core (2) with a plurality of housings (21); - a set of coding magnets (5) fixed in the housings (21) of the core (2) according to a determined polarity; - a code reader (4) comprising: - a cavity for receiving the key (1); - a plurality of opening sensors (17) distributed radially and longitudinally with respect to the cavity of the code reader (4), so that, when each opening sensor (17) detects a predefined magnetic field value, a signal is generated to unblock. (Machine-translation by Google Translate, not legally binding)

Description

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COMBINABLE MAGNETIC CLOSURE SYSTEM

DESCRIPTION

Technical field of the invention

The present invention belongs to the field of passive safety mechanisms, more specifically it refers to keys and code readers, for example, for magnetic type locks.

Background of the invention

Magnetic keys are known for rooms of hotels or companies. Usually, they have the form of a plastic card with a magnetic band in which access permits are encoded. The associated locks are electronic and are usually wired to a control unit. One limitation is that the code of the magnetic band of the card needs to be recorded by a specific electronic device.

The magnetic controls are also known, typically for access to garages. These controls are usually flat and contain magnets in different positions that are read by a support. The command code does not need to be recorded by a specific electronic device. Usually, it is enough to have a scheme with its distribution and to open the command and place the magnets. The limitation in this case is that the number of possible combinations is quite small.

In sum, the known solutions based on codes defined from the magnetic field, have certain practical disadvantages, are not versatile or modular.

Brief description of the invention

An object of the invention is a code reader for, for example, a security lock and a configurable key.

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This multi-position key takes advantage of the 3D geometric design, so that, just by changing its position, it establishes different values for the magnetic field, with which the key can be encoded.

As will be appreciated later, it is feasible to vary the power of the magnets, their placement, their polarities, in order to obtain different codes for the key-reader code pairs for a lock or similar.

The key consists of a body, which could be geometrically of different shapes, including one or more longitudinal modules called modular elements that make up a core containing permanent magnets arranged in a predetermined longitudinal and radial position. If the core is prism-shaped, said magnets can be placed radially on the different faces of the prism. Additionally, each magnet can be oriented with the north outward / inward.

The code reader consists, on the other hand, in a body with a cavity for receiving the key and with a series of magnetic sensors distributed longitudinally and radially around the cavity. The material that surrounds the cavity for the key must be of non-ferromagnetic material, so as not to alter the fields generated by the different magnets that have to be properly detected. When the key is placed in the proper position, the sensors detect if there is a magnet and that it is also placed with the correct polarity, and then activate an opening mechanism. Additionally, the key can be rotated as a particular embodiment to achieve the opening.

In general, the object of the present invention is a combinable magnetic closure system as defined in the first claim. On the other hand, dependent embodiments define particular embodiments that can be especially advantageous in various circumstances.

Brief description of the figures

FIG. 1A schematically shows a key in perspective.

FIG. 1B shows the key approaching a lock.

FIG. 1C shows the key inserted in the lock.

FIG. 2A shows three possible geometries to form a single nucleus.

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FIG. 2B shows a composite core with its simple modules assembled longitudinally.

FIG. 3A shows a support without its core introduced.

FIG. 3B graphically shows how the key would be, once inserted in the lock, with respect to the sensors included in the lock.

FIG. 4A shows a longitudinal section of a passive lock in the closed state with the key inserted in an incorrect position.

FIG. 4B shows the same lock in closed state and without key inserted. Detailed description of the invention

For a better understanding of the invention, several examples of embodiment are set forth, without limitation, with reference to the previous figures.

The proposed magnetic closure system comprises two well-differentiated parts, the key and a code reader which in the examples is implemented in a lock.

In FIGS. 1-3, several forms of constitution of the key 1 and its main components can be observed. The key 1 includes a nucleus 2 (simple or with several modules) and a support 3 for it (said support, in certain designs, could be part of the nucleus itself). Both pieces, core 2 and support 3, are made of non-ferromagnetic material. The core 2 has housings for locating the magnets 5. As can be seen in the drawings, the geometrical shape of the core 2 can vary. It can be flat but it is advantageous that it has a larger number of faces to expand the number of possible combinations and facilitate its modularity, all in order to form a robust code and also enable space for magnets 5. The accommodations 21 where they are placed the magnets 5 can be equidistant and evenly distributed around the periphery of the core 2 to facilitate interchangeability.

FIG. 1A shows the key 1 in perspective with an inner core 2 in the form of a dodecahedron (prism of 12 faces) on whose faces the magnets 5 can be installed at different distances. The support 3 of the key 1 that surrounds the core 2 is appreciated to prevent the magnets from falling off 5. In FIG. 1B the key 1 is shown approaching a lock 4. In FIG. 1C the key 1 (simple or modularly composed of several cores) is seen, inserted in the hole of the lock 4 until the

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stop. Notice how the support 3 ends in a projection 31 for better grip. Note that the projection 31 has one of its ends in an arrowhead to allow orienting the key 1 in the turn.

FIG. 2A shows nuclei 2 in the form of prisms of different faces. From left to right you can see a nucleus of 4, 6 and 8 faces that are connectable to form a composite nucleus. Generally, nuclei 2 of the same geometry will be used. This must be conditioned by the arrangement of the sensors in the lock 4. The arrangement is established in both the radial and the longitudinal dimension.

FIG. 2B shows a composite core 2 longitudinally assembled with three modular elements 22 in the form of a rectangular prism. Preferably, to facilitate the longitudinal assembly between cores 2 there is internally a connector magnet 7. Preferably, a core 2 can be inserted into a support 3 by either of its two ends and locate it in any of its possible positions.

Note in the examples that each face contains a given distribution of housings 21 where magnets 5 can be inserted (logically the shape and size of magnet 5 must be compatible with housing 21). The absence or presence of magnets 5 in established and oriented positions with a specific polarity allows to establish a specific code. This code is defined as a sequence of values associated with the detected magnetic field. Identifying this code with a lock 4 is the task of sensors 17, 18 that detect the provided reading that triggers an opening mechanism in case of coinciding with the code established as will be seen, for example, in FIG. 3B.

To register the code, the notation {0; one; -1}, where "0" means absence of magnet, "1" magnet with north pole towards the outside, and "-1" indicates magnet with south pole towards the outside. The combination of magnets 5 placed in their housings 21 determines the exact code to open the lock 4. Clearly, the more housings 21 containing the core 2, the greater the number of combinations available to establish the code.

Returning to FIG. 1B, note that in the key 1, the support 3 is designed so that it partially shows the radial arrangement of the core 2, a dodecahedron. On his face n °

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9 to the right (the 9 is to the left of the nucleus) and position "E" (the fourth of seven possible) in the longitudinal axis of the support. With the key in its correctly positioned support, held by the control, it is inserted in the circular eye of the lock 4 in radial position "2". Even if the key 1 has the correct code if it is not entered in the aforementioned position, the lock 4 will not be activated. Thus the combination 9D-4-2 is obtained.

The cylindrical hollow in the center of the core 2, is to accommodate if necessary a redirecting cylinder 23 of ferromagnetic material, in order to hold, enhance and redirect the magnetic field of the different magnets housed in their holes. It is an internally fixed element but optional in the embodiments. It helps to separate the influences of some magnets in others.

Also, the hollow in core 2 additionally serves as a housing for a connector magnet 7 that connects two cores. Simply, it is a simple way to join and exchange positions of the different cores 2. It is important that the magnet connector 7 can move freely inside its cavity, since that way it can be oriented with the opposite pole to the one that has the nucleus adjacent to the one you want to join. This design is the solution to create a unisex connector, avoiding male and female connector. Logically, if the key 1 only has a single core 2 this magnet connector 7 would be unnecessary.

As in the example of FIG. 2B, a set of modular elements 22 of the same geometry that make up a core 2 composed of three modules, the modular elements 22 are interconnected one after another for example as indicated in the previous paragraph. This coupling multiplies the number of possible combinations. Whereas with a simple nucleus 2 that is square, only eight possible positions are available, with three modular elements for a nucleus 2 that is composed, one can play with more combinations in terms of positions. If it is labeled differently to each modular element 22 to distinguish them, it can be easily checked. For example, the element on the left is labeled as al, the one on the center as a2 and the one on the right as a3. Thus, the following combinations can be generated between modular elements 22:

Combination n ° 1: a1-a2-a3 Combination n ° 2: a2-a1-a3

Combination n ° 3: a2-a3-a1

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Combination n ° 4: a3-a2-a1

Combination n ° 5: a3-a1-a2

Combination n ° 6: a1-a3-a2

In turn, each of the 6 possible combinations must be multiplied by the 8 possible positions of each modular element 22 (4 different radial positions by its rectangular prism geometry plus 2 positions as it is oriented longitudinally). Since there are three, it gives us a result of 6 x 8 x 8 x 8 = 3072 different positions for a core 2 made up of three modular elements 22 (a1, a2, a3).

In case of using two cores of eight faces, there would be: 2 x 16 x 16 = 512 different positions.

For this example of modular elements 22 for forming a composite core 2 in line, the support 3 can be dispensed with since the different modular elements 22 of the core 2 can be held together by the force of the magnetic field provided by internal magnets 7 in the ends of each nucleus 2.

These internal magnets 7 only serve to join the different nuclei 2 and allow to easily change their position by turning their faces. This is possible thanks to the fact that the internal magnet 7 can move freely inside its inner room, in order to be able to turn and place the north pole with the south pole of the adjacent core. This mechanism is also very useful when you want to store a key 1 distributed in different places, as many as nuclei 2. Therefore, to open the lock 4 it will be necessary to gather all the pieces and place them in the proper order. To achieve this order, the present embodiment is helped by symbols, icons, letters, numbers, colors, which will be printed on the sleeve that wraps each core or stamped on the core itself. The notation used can be easily replaced by the user without having to change anything other than a printed paper or film.

The support 3 serves as a control for the key 1. It is a piece made entirely of non-ferromagnetic material that houses the core 2. It can have different geometrical shapes, preferably of cylindrical shape, since it favors the insertion in a 4-cylinder lock hole.

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In FIG. 3A, an embodiment with a slightly different design is shown for inserting a simple core 2 in the support 3. With this design, through the window enabled in the upper part, the selected position can be read. It is designed with an arrowhead to indicate the position in which we are introducing it. And it has seven cylindrical portions along to place the coding iimanes 5 of the core 2 in any of them.

In FIG. 3B is an exploded view with the location of the opening sensors 17, and auxiliary safety sensors 18, belonging to a lock 4 with respect to the coding magnets 5 of the key 1 with its support 3 and housings 21. In this FIG. 3B are marked with letters from "A" to "G" the possible positions of the core 2 in the support 3 and with Roman numerals "VIII", "IX" for the faces of the nucleus where the coding magnets can be placed 5. This it is just one example among many other possible ones.

On the other hand, the lock 4 can be active or passive. The active lock 4 requires a power supply, either connected to an electrical network or through a battery. In contrast, the passive lock does not require any current to operate.

In FIG. 4A a section of the interior of the passive lock 4 is shown. There are a series of opening sensors 17 based on the measurement of the magnetic field, in line and separated from each other by the same distance to which the magnets 5 are separated inside the core 2. The lock 4 is opened when the correct code is identified. That is, when the combination of magnets 5 are located in front of the appropriate sensors. Any other position is detected by the opening sensors 17 as erroneous and the opening of the lock 4 is not activated.

In the event that the lock 4 is active, it can implement circuitry to enable a protection protocol that prevents the lock 4 from reading another intrusion attempt until a predetermined timeout elapses. It would be an additional security measure to prevent an intruder with the original key 1 from opening the lock 4 by testing all the combinations for an entire night.

As seen in previous examples, this core 2 can be realized with different geometries. In these three examples, type "a" would have 2x4 = 8

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different positions, in the hollow of the lock 4, the type "b" will have 2x6 = 12 and the "c" of 2x8 = 16.

The lock 4 has the capacity to read the code of the key 1 introduced. To undertake this task, basically two realizations are proposed. It can be carried out as an active lock, which requires electrical power, or, by means of a passive lock, without associated consumption.

Active lock

The active lock, depending on the technique used for the detection of the magnetic field, can be implemented with and without polarity:

- With polarity: with detectors, such as by means of aperture sensors 17. For example, hall effect sensors are able to obtain a positive or negative signal depending on the polarity of the detected magnetic field.

- No polarity: simply, a device is used that is capable of detecting the intensity, but not the polarity of the field. This can be implemented either through another hall sensor without polarity detection, or a reed switch among others. The important thing is a device that detects the magnet 5 of the key 1 only when it is in the proper position in front of it and, at the same time, that said magnet 5 does not activate any other sensor of opening 17 close when the key 1 is introduced. For this reason, the distances between magnets and sensors are crucial.

To improve the security of the lock, additional auxiliary sensors 18 are also placed which are responsible for detecting if the key has been introduced in an invalid position. These auxiliary sensors 18 would be used for those embodiments with more demanding safety requirements. A measure that could be implemented is, for example, after three attempts, even if it is inserted in the correct position, lock 4 would not open. These auxiliary sensors 18 associated with a circuit can activate a delay in the opening of the lock 4. A waiting time can be fixed in some specific embodiment before enabling the opening of the lock 4 in case of correctly introducing the key 1 again.

The opening sensors 17 (and optionally the auxiliary sensors 18) can be grouped and form a set of sensors, preferably placed in line and spaced the same distance as the magnets 5 in the key 1 is called the aligned assembly 19.

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If it is desired to further increase safety, it is possible to add to the first aligned assembly 19, a second aligned assembly 20 of opening sensors 17 (and optionally with auxiliary sensors 18), the aligned assemblies 19, 20 are spaced apart from each other, the same degrees that the degrees of placement of the magnets 5. For example, in a key 1 with a square prism, the magnets can be every 90 °, so we can align sets 19, 20 of sensors placed at different angles, for example: 0 °, 90 °, 180 °, 270 °. As seen in FIG. 3B, for example, the assemblies 19, 20 can be placed in two lines, one at 0 ° (aligned set 19) and another at 90 ° (aligned set 20). This configuration is more than sufficient in the vast majority of cases.

Passive lock

The lock 4 is simply activated before a magnetic field without the need for any current.

- With polarity: it can be done by opening sensors 17 that can be implemented as cylindrical magnets.

- Without polarity: with simple cylinders of ferromagnetic material.

This technique is similar to the classic bombin with five pistons that go up and down to position all in line and allow turning the key. The difference lies in that in this embodiment they would be magnets 5 that would attract a first sensor 17 in order to unblock the closure.

In the event that the combination is not successful and a magnet 5 of the key 1 is placed in a position that does not correspond to it, then a second auxiliary sensor 18 would block the closure. In this way, it is guaranteed that, by simply placing a powerful magnet in the keyhole, all the mobile elements will activate, such as the first sensor 17 and, therefore, anyone will open the lock without the code.

The movable elements mentioned: one or more first sensors 17 and one or more second sensors 18 would generally be a cylinder of ferromagnetic material (piston without polarity) or a cylindrical magnet with the poles at its ends (for locks with polarity).

The push button 10 only moves when all the first sensors 17 are unlocking the bar 11, as a consequence of entering the key 1 with the correct combination.

The return magnets 12 ensure that the mobile elements associated with the sensors 17 and 18 return to their original state once the key 1 of the lock 4 is removed. The magnetic bridge 13 is fixed from a ferromagnetic material, which provides a bridge to the magnetic field, so that it reaches the second sensor 18, which in its resting state is not blocking the bar 11.

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The other moving elements, which in their resting position if they are blocking the displacement of the bar 11, do not require this component. In closed position or rest, the first sensors 17 are in the vicinity of the magnets 5 and therefore are able to move. On the other hand, the second sensor 18 is far away and 15 needs a transmitter to send it the magnetic field of the coding magnet 5.

The spring 15 allows the push-button 10 to return to its rest position, so that the sensors 17 re-block the bar 11, when removing the key 1.

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The attenuation piece 14, between the return magnet 12 and the sensor 17, is to prevent the force of attraction from being excessive and then the magnet 5 of the key is not able to move the first sensor 17.

Finally, several advantages of the invention that can be implemented in the embodiments described above are indicated:

- Versatility to have the possibility of adopting multiple opening combinations for different locks with a single key. It avoids the need to carry a keychain with a multitude of keys, each to open its own lock. Is

30 possible to configure so that the closing position is the same for all the locks, reducing the number of positions to be memorized.

- On the other hand, the sensor or sensors of the lock can be configured to read different codes. This way you could open the lock by just entering a key configured with one of the accepted codes of the lock.

- The key and the lock are fully operational under extreme climatic conditions, cold, heat or humidity, even when submerged in fresh or salt water.

- Both the key and the lock, in the absence of physical contact do not suffer deterioration or fatigue, which extends its useful life.

- The closing system is safe.

It is not feasible to read the opening code by means of magnetic field detection techniques, with X-rays, etc. He is also invulnerable to ganzou.

- In the event of losing the key or being robbed, the lock could not be opened without knowing the correct position for opening.

- Resistance to vandalic acts that seek to cancel its use, introducing sticks or silicone in it, it will always be much easier to get rid of the obstacle. In contrast, for a common lock you would have to discard the bombin or the entire lock.

15 - Comfort. The key can be kept subject to the magnetic field of the

key.

- Cost Both the key and the lock can be produced for little money and little investment in machinery. For example, using a 3D printer.

- Upgrade. The same user could change the opening combination and even the access code, as many times as he wants, without cost.

- Bidirectionality. The key can be inserted on both sides of the lock, with the same key and using the same sensor system, without having to duplicate it as it currently happens with the current locks or locks.

- Control. If the user is not in full mental faculties, it will be much more difficult to open the lock, than with a conventional key.

Other considerations:

- In the case of an embodiment in which the key is allowed to enter the two sides of the lock, there is a consideration about the width thereof. Must be

30 a multiple of the distance between two consecutive positions of the system used in the key holder. That way we guarantee reversibility.

- With respect to the previous embodiment, if having a hole passing from side to side is inconvenient, then a piece can be arranged inside the passage displaceable from one side to the other when being pushed by the key itself.

- In prototypes made the key object of the invention is similar in volume to a conventional key. The code reader present in the lock can be miniaturized to be similar to a traditional lock.

5 Numerical references

1 Key

2 Nucleus.

3 Support

4 Lock.

10 5 Coding magnet.

7 Internal magnet.

10 Push button.

11 Barra.

12 Return magnet.

15 13 Magnetic bridge.

14 Part of attenuation.

15 Dock.

17 Opening sensor.

18 Auxiliary sensor.

20 19 First aligned set of sensors

20 Second aligned set of sensors

21 Accommodation.

22 Modular core element.

23 Cylinder redirector of the magnetic field.

25 31 Highlight

Claims (11)

5 10 fifteen twenty 25 30 35 1. Combinable magnetic closure system comprising: - a key (1) comprising: - a core (2) with a plurality of housings (21); - a set of coding magnets (5) fixed in the housings (21) of the core (2) according to a certain polarity; - a code reader (4) comprising: - a cavity for receiving the key (1); - a plurality of opening sensors (17) distributed radially and longitudinally with respect to the cavity of the code reader (4), so that, when each opening sensor (17) detects a predefined magnetic field value, a signal is generated to unblock. 2. The magnetic closure system according to claim 1, wherein the core (2) is composed and comprises a plurality of modular elements (22) engageable and interchangeable with each other. 3. The magnetic closure system according to claim 2, wherein the coupling is magnetic. 4. Magnetic closure system according to claim 2 or 3, wherein the core has prism geometry, with the housings (21) located on at least one of the side faces. 5. Magnetic closure system according to claim 4, wherein the housings (21) of the core (2) are evenly distributed. 6. The magnetic closure system according to claim 4, wherein the core (2) has at least one connector magnet (7) on one of the front faces. 7. Magnetic closure system according to any one of the preceding claims, further comprising a support (3) that fixes the position of at least one core (2) and the set of coding magnets (5). 8. Magnetic closure system according to claim 7, wherein the support (3) ends in a projection (31) that marks the orientation of the key (1) inside the code reader (4) . 9. Magnetic closure system according to any one of the claims above, where the code reader (4) is passive, without associated electrical consumption, comprises a plurality of auxiliary sensors (18) to block an opening drive bar (11). 10. Magnetic closure system according to any one of the claims previous 1 to 8, wherein the code reader (4) is active and comprises a plurality of auxiliary sensors (18) to activate a delay circuit that delays the unlocking. The magnetic closure system according to claim 9 or 10, wherein the opening sensors (17) are magnets for discriminating the polarity of the coding magnets (5) on the key (1) when entering the code reader (4). 12. Magnetic closure system according to any one of the claims above, wherein the housings (21) are arranged in a rotating structure. twenty 13. Magnetic closure system according to any one of the claims above, which includes a lock where the code reader (4) is installed. image 1 31 two 5 two 31 3 Fig. 1A Fig. 1C Fig. 1B image2 2. 3 Fig. 2A two image3 image4 Fiq. 3A 19 c image5 image6 Fig. 4A image7