FR2631366A1 - IMPROVED LOCKING CYLINDRICAL LOCK WITH MAGNETIC PUMP - Google Patents

Abstract

In order to prevent the passage inside the seal of external or internal impurities resulting from internal friction and occurring during the use of the cylinder seal of a pump lock, and to ensure the rotation of the rotor cap in the exact open position, the locking element bears punctually against the wall of the locking bar groove 9 in each contact cross section, and is at least shaped to fit in a cross section of the opening 18 and movable in the opening 18. Application to assemblies consisting of a lock cylinder with a magnetic pump housed in a lock barrel.

Description

Improved cylinder lock lock with magnétimu pump

  The invention relates to an improved cylindrical lock seal with magnetic pump, comprising at least one cylinder or closing cylinder, sealingly insulated in a standardized housing, rotatably arranged and connected to a twisting drive element of a lock containing the cylindrical lock seal with magnetic pump, the closure cylinder containing on the one hand a key channel, in which a key containing a magnetized magnetic disk in a rope or diametrically with a north-south polarity engages; that is, a wrench containing key magnets, on the other hand a cavity surrounding the key channel on both sides and in which rotor caps acting as rotor supports, disposed in the cavities and cylindrically completing the cylinder of closing, are recessed rotating, 'the number and axis of rotation of the capsule rotors corresponding to the key-magnets of the key introduced into the channel key and a rotor magnet being fixed in each rotor capsule and being magnetized identically to the key magnet, one or more cavities being further provided on the face of the rotor capsule opposite to the magnet of the rotor. rotor, and forming a tongue channel or locking bar in operative relation with the key inserted into the rotor magnets placed in the open state; an opening covering the locking bar channel being formed in the rotor support, as well as a locking bar groove which covers this opening in the inner wall of the housing, a locking element being guided and mounted movably inside. of said groove in the basic position of the lock cylinder, an elastically biased spar reinforcement being further provided, which determines the relative position of the lock cylinder with respect to the housing or barrel, which holds in the key channel the key inserted when it is placed out of the basic position and prevents drilling by drilling

cylindrical lock barrel.

  The cylindrical magnetic pump lock seal, improved according to the invention, can be applied to devices providing increased security, O particularly to make locks for doors and gates, either in replacement of old locks or as a constituent part a new lock structure. Magnetic pump cylindrical locks supplant traditional cylindrical lock fittings and are used in an ever wider field, due to the high number of variants and their high security in many versions. A cylindrical lock seal with a magnetic pump, whose structure is detailed in the introduction, is described in FR-A 2548720, the important details from the point of view of the cylindrical lock lock with pump according to

  the invention being shown in FIGS. 1 to 7.

  In a housing or standard barrel 1 there is a cylinder or rotary closure cylinder 2, which can be rotated in the open position shown in FIG. 4, from its basic position, shown in FIG.

  Figure 2, using a corresponding key, appropriate 3.

  If the locking cylinder is then further rotated, a slider drive member thus connected moves the latch and / or latch of the assembly. lock, making the lock open. From its basic position, the locking cylinder can only be rotated with the corresponding key 3. In the body of the key 3, as well as in several cavities of circular shape, generally three, and on both sides of the key 3, each time is mounted a magnetically encoded disc permanently. The code is made so that a north-south bipolar magnetic field divided by a neutral dividing line is formed in the round magnetic disk, that is to say in the key magnet 12, as illustrated by FIG. Figure 6. The neutral separation line develops from 0 within an angular range of 360, so that, relative to the point 0, it is possible to realize, at different angles, bipolar magnetic fields with north polarity. south, depending on the number of variants planned. Therefore, with an angular division at 60, ensuring the highest resolution in the current state of the art, one can realize six different bipolar magnetic fields. Six bipolar magnetic fields embedded in a key

  produce 66 = 46,656 variants.

  On both sides of the key 3 located inside the locking cylinder 2, in the rotor supports 4, there are provided three rotor capsules 6, each containing magnetic disks and magnets.

of rotors 5.

  These rotor magnets 5 are made from the same material as that of the magnetic discs existing in the key 3 and key magnets 12 and are magnetized in an identical manner. The rotor caps 6 are mounted in such a way that they can be rotated about a rotor axis 7 and they are already rotated under the effect of a low torque. On the rear side of the rotor capsule 6, a cavity is provided arranged on a rope, which may advantageously have a cross-section in the form of a truncated cone, and which receives the locking element of the locking cylinder 2. If the corresponding key 3 is introduced into the key channel of the closure cylinder 2, the magnetic fields

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  Bipolar existing in the key magnets 12 exert through the wall of the key channel 10 an effect on the bipolar magnetic fields of the rotor magnets 5 fixed in the rotor caps 6, whereupon the torque - which appears as a result of the interaction of the magnets - rotates the rotor capsule 6 in the coded open position corresponding to the key 3. The cavities existing on the rear faces. rotor caps 6 then form a perfectly aligned locking bar channel 11. Under the action of the rotational torque exerted by the key 3 on the locking cylinder, the latter

tends to turn.

  In the exemplary embodiment shown here, the blocking element in the form of a locking bar 8 - which bears in the rest position on the wall of the groove 9 of the blocking strip of the casing 1, the manner represented in FIG. 3 -, is guided along the curved wall of the locking bar groove 9 and in the opening 18 of the rotor support 4 and as it moves, it sinks into the bar groove 11, causing the closing cylinder 2 - in the position shown in Figure 4 - can be rotated in the housing 1. If used to achieve the opening, a foreign body, not a key 3 appropriately coded, the locking bar grooves 11 of the rotor capsule 6 remain in a correspondingly unordered position, as a result of the interaction of the bipolar magnetic fields of the rotor magnets 5 upon insertion of the foreign body, or else, under the action of the foreign key magnets 12, they take a coded position that does not match and they do not accept the locking bar 8 which thus relies on the rear face of the rotor capsule and the wall of the locking bar groove 9 and a part of the locking bar 8 located in the locking bar groove 9 remains in the locking position. It is thus impossible to turn the closure cylinder 2 in the

  casing 1, even when applying a high torque.

  In the partial section of FIG. 3, a state is shown, in which the corresponding key 3 is inserted into the key groove 10, so that, as a result of the correct coding of the key magnets 12, the rotor magnets 5 turn to the end. at the correct position and form a

  corresponding block bar groove 11 open.

  The locking bar 8 is again supported on the wall of the locking bar groove 9, under the effect of the reaction force of the spring 13, which corresponds to the position

of Figure 2.

  Considering that it is a constituted structure, of several structural parts moving in a narrow space, whose correct and reliable operation must significantly influence the utilitarian character, the cylindrical lock cylinder represented here is provided, to stop the external impurities, sealing rings 14,15, also serving to protect against drilling by drilling which would reach the locking bars. An elastically biased structure is incorporated, having a sphere portion and a steel cover, which also prevents the key from being pulled out of its basic position and blocks the position.

  opening of the closure cylinder.

  In order to prevent axial extraction, which is usual when drilling by drilling, grooves 17 cooperating with the rotor shafts 7 are formed on the locking bars 8. If, on the rear face of the locking caps 6, no provision is made for , but two grooves lock bars 11 (this possibility is illustrated by a broken line in Figure 6), when introducing two keys 3 coded differently, the locking cap 6 is placed in a position o a locking bar groove 11 could receive a locking bar 8, and could thus realize key systems

  principal and general key using this principle.

  Pump cylindrical lock fittings play an important role in increasing burglary security. Lock structures of this type can not be opened with special burglar tools if reinforcing reinforcement of corresponding thickness is used and the structure is resistant to sudden burglary methods. After a certain period of use, the pump cylindrical lock seal is however clogged and seized and opening becomes more difficult. This situation limits confidence in the cylindrical pump lock seal. Regular rinsing and cleaning with a solvent product certainly helps solve the problem, but not everyone can undertake the regular disassembly and washing of the lock.

cylindrical pump.

  The dirt of the barrel and the filling comes from several sources. External dirt is caused by the fact that tiny particles which have entered the lock structure from the environment and some of which have accumulated on the magnets are gradually deposited and prevent the fine adjustment of the rotors and thus the irreproachable operation of the whole. The sealing rings 14, 15 used to prevent or limit soiling from outside - which can be made of rubber, plastic, or silicone material - significantly prevent soiling from the outside, while that the well-centered positioning with respect to the axis of the lock cylinder 2 limits the wear resulting from the friction between the lock cylinder 2 and the wall of the dirt from outside, while the positioning well centered by relative to the axis of the lock cylinder 2 limits the wear resulting from the friction between the lock cylinder 2 and the housing wall 1. The internal fouling occurs as a result of frequent use, so that the particles of material which can come loose from the friction surfaces as a result of sliding friction occurring during actuation, gradually settle and prevent the adjustment is rotors and the correct operation of the whole. In addition to soiling, the use of lubricants, which are inevitably used because of sliding friction, poses an additional problem, because the friction increases significantly, the friction surfaces become rougher and seize and finally the cylindrical pump lock seal remains plugged in or blocked. The sliding friction is particularly important for the rounded rear end of the locking bar 8, on the lower and upper faces which are in contact with the opening 18 of the rotor support 4, as well as for the

  lock grooves ll of the rotor housing 6.

  The reduction of sliding friction and lubrication of the lock structure can, according to practical experience, be achieved exclusively by using kerosene, which as a result of its composition is suitable for washing and lubricating the structure. In the case of the use of special lubricants, the rotors are braked by thickening and no longer position themselves in a corresponding open position. In the case of traditional lock fittings, to lower the

  sliding friction, care is taken to use graphite.

  In the case of magnetic pump cylindrical lock fittings, the use of graphite powder is inefficient, because of the high slip friction, since the graphite powder and the particles of material which are deposited reach the rotors , and restrains them, preventing the rotors from operating in the position

corresponding opening.

  In the manufacture of lock structures, one must satisfy an extremely important requirement, that the key magnets 12 and the rotor magnets 5 used, thanks to the precision of the magnetization, and that of the torsion torques produced by magnetic fields, can exercise without hindrance

  their effects on the elements taking part in the closure.

  In practical use, it has been found that the torque produced by the mutual action of the key magnets and rotor magnets decreases proportionally to the square of the reciprocal distance, if the space is filled with a zinc alloy, and decreases

  according to a power of three if the space is filled with air.

  This means that in order to achieve a greater torque every time, the distance between the key magnets 12 and the rotor magnets 5 must be reduced to the lowest possible value. In the typical embodiment of the magnetic pump cylindrical lock linings currently known and shown in FIG. 7, two key magnets 12 are fixed in the key 3 and, likewise, there are six key magnets 12 in the key 3 of the cylinder according to Figure 1. It is thus possible, in this way that the six key magnets 12 of the key 3 can rotate in the encoded opening position six rotor magnets 5. As we As already mentioned, six-pole, six-pole magnetic fields have been made inside a circle with a division at 60, so that 66 = 45,545 variants can be obtained. Despite the large number of current magnetization processes, the accuracy of the magnetization does not significantly lower below the angular division at 60, because the accuracy of adjustment of the rotor capsule is then not satisfactory. . For cylindrical locks used in a wide range, and using the rod system, it is considered satisfactory when 35,000 variants are obtained for practical use. This number of variants is obtained by the fact that the size of six rods can be varied according to five values, which makes it possible to produce 56 = 15,625 variants, one obtains a further increase in the number of variants by modifying the format of the In the case of cylindrical locking cylinders, to ensure the desired number of variants, two key magnets 12 are pressed into each cavity of the key 3. This solution offers the advantage of allowing a large number to be obtained. variants with a relatively small number of rotors, six to be precise. Despite the simplification obtnue, various disadvantages appear, which will be explained. The key magnet 12 must be extremely thin, so that the thickness of the key 3 does not increase, because when the thickness increases, it is also necessary to increase the thickness of the wall existing between the magnets of the key. Key 12 and the rotor magnets 5. Indeed, in a wide key groove can exert a high torsion torque with a foreign body and the small wall thickness lack of resistance to the high pressure exerted by the bars. 8 on the rear face of the rotor cap 6, so that the

  closing cylinder 2 rotates accordingly.

  In order to avoid interactions, the thin key magnets 12 should in no way be completely magnetized, magnetic induction lines being simply made inside the key magnets 12 and these lines closing approximately in the shape of a U. In this way it is not possible to achieve complete magnetic saturation, which means that lower key magnets are obtained than if a linear parallel magnetization was passed, as well as

  is usual for rotor magnets 5.

  As a result of the thickness of the relatively large key 3, the result is a wall thickness between the key magnets 12 and the rotor magnets 5 which is relatively large, so that the torques exerted between these magnets decrease significantly. The interactions between the key magnets 12 and the rotor magnets 5 are replaced, after the extraction of the key 3, only by the interaction between the rotor magnets 5, so that the rotor housing 6 comes into a position unordered deviating from the coded position allowing opening. Due to the large wall thickness these influences are reduced - for example due to the rotors rotating soiling - and the unordered position is not obtained as a result of the extraction of the rotors.

  key 3, which endangers the security of the closure.

  In the known magnetic pump cylindrical lock fittings, there are two magnetic circuits operating independently of one another and illustrated in FIG. 7 by dashed lines 20. The independent magnetic field lines 20 also exert mutual influences, causing their effects to deform each other and make it more difficult to adjust

of the rotor capsule 6.

  It is an object of the invention to eliminate the aforementioned defects of known magnetic pump cylindrical lock seals and to develop a reliable, long-life, magnetic pump lock seal which is free of maintenance, which can be manufactured with simple means and

  economic, while offering a large number of variants.

  The invention is based on the recognition that the primary problem is to prevent the entry of impurities - which is the main cause of uncertain operation - so that the barrel operates reliably, without any maintenance, with the lubricant introduced into the cylinder. during the manufacture, and furthermore, in the case where the key magnets are magnetized over their whole thickness, a better angular division can be obtained than the angular division to which is usual today, so that with a more limited number of key magnets, but with a larger number of codes, one can obtain numbers of

  identical variants-or exceeding the current number.

  For the solution of the problem, we started with an improved cylindrical lock lock with magnetic pump, comprising at least one cylinder or closing cylinder, sealed in a standardized casing, rotating and connected to a slider driving member of a lock containing the magnetic pump cylindrical lock seal, the closure cylinder containing on the one hand a key channel, into which a key containing a magnetized magnetic disk according to a rope or diametrically with a north-south polarity, that is to say a key containing key magnets, on the other hand a cavity surrounding the key channel on both sides and in which rotor caps serving as rotor supports, arranged in the cavities and complementing the cylindrical closing cylinder, are recessed rotating, the number and the axis of rotation of the capsule rotors corresponding to the key magnets of the key inserted into the key channel and a rotor magnet being fixed in each rotor capsule and being magnetized identically to the key magnet, one or more

26313 6

  cavities being furthermore made on the face of the rotor capsule opposite the magnet of. rotor, and forming a tongue channel or locking bar in operative relation with the key inserted into the rotor magnets placed in the open state; an opening covering the locking bar channel being formed in the rotor support, as well as a locking bar groove which covers this opening in the inner wall of the housing, a locking element being guided and mounted movably inside. of said groove in the basic position of the lock cylinder, an elastically biased spar reinforcement being further provided, which determines the relative position of the lock cylinder with respect to the housing or barrel, which holds in the key channel the key inserted when this one is placed out of the basic position and which prevents the routing by

  drilling cylindrical lock barrel.

  The cylindrical pump lock seal is developed according to the invention, in order to prevent the penetration of external and internal impurities. resulting from the internal friction during the use of the cylindrical pump lock seal, and, to ensure rotation of the rotor cap in the exact open position; for this purpose the blocking element is in pointwise support on the wall of the locking bar groove in each contact cross section, and is at least arranged in shape-fit in one section.

  transverse opening and movable in this opening.

  In order to increase the number of variants of the magnetic pump cylindrical lock seal, and in order to increase the magnetic interactions between the key magnets and the rotor magnets, the thickness of the key magnets is identical at the thickness of the key, the magnetized key magnets in their entire thickness, at most in an angular division at 20, magnetized key magnets in their entire thickness, at most in an angular division at 20, being surrounded on each side of a rotor magnet

magnetized identically.

  According to an advantageous embodiment of the cylindrical pump lock seal, the locking element is composed of a locking bar extending along the opening of the rotor support and engaging in the grooves of the bars. blocking of the rotor capsule, and an intermediate element connecting its face

  back and the wall of the locking bar groove.

  The intermediate element can be simply adapted to the shape of the opening of the rotor support: in this way, the impurities can not in any way be introduced into the area of the locking bar and the groove of

blocking bar.

  In the case mentioned above, the intermediate piece may advantageously be a spherical metal ball engaging by shape adjustment in the circular section of the shaped opening and movable to. inside this opening. It can also be constituted by a rolled barrel or a

  cylindrical roller satisfying the general requirements.

  One embodiment of the cylindrical magnetic pump lock seal is considered advantageous if the key magnets and the rotor magnets are magnetized with an angular division to 11, since in this way a number of variants can be obtained simultaneously. really high while still maintaining a

good mechanical resistance.

  In the improved packing cylindrical lock pump according to the invention, as a result of the modification of the locking bar is eliminated the wear from sliding friction and the risk of blockage following

faulty lubrication.

  The separation of the friction surfaces of the particles of material, which is usual during sliding friction, practically ceases, and the functional disturbances and scrapes due to the incorrect setting of the rotors are also eliminated. Thanks to the embodiment proposed in the invention, it is also possible to eliminate all the disturbances resulting from the impurities

exterior.

  As a result of the low friction, the lubricating product requirements decrease and it suffices simply to apply once and for all a lubricating product to ensure the lubrication product.

  continuous operation, while for

  Cylinder lock with pump made in open form, the need for lubricant and maintenance

  decrease significantly.

  Thanks to the larger magnetic field, it is possible to produce a cylindrical lock with a pump according to the invention, which is more robust, without the number of variants being less than that which is accepted on the

international plan.

  D Other goals, benefits and features

  will appear on reading the description of various

  Embodiments of the invention, given by way of non-limiting example and with reference to the accompanying drawings, in which: FIG. 1 is a longitudinal section of a detail of the cylindrical lock packing with a traditional magnetic pump, according to FIG. state of the art; Fig. 2 shows a cross-section along the line II-II of the cylindrical pump lock according to Fig. 1 in the basic position with the key inserted; FIG. 3 represents a section along the line III-III of the cylindrical packing of

  pump lock according to Figure 1; -

  Figure 4 shows a cross section along the line IV-IV of Figure 1, with the cylindrical lock placed in the open position; Figure 5 shows in section and on a larger scale a rotor of the cylindrical packing of pump lock according to Figure 1; FIG. 6 represents the front view of the rotor according to FIG. 5; Figure 7 shows on a larger scale the. central detail of the cylindrical packing of pump lock according to Figure 2, with the magnetic circuits that are established there; FIG. 8 shows a longitudinal section of a part of a possible embodiment of the improved cylindrical lock seal with a magnetic pump, according to the invention; Fig. 9 shows a cross-section along the line IX-IX of the cylindrical pump lock packing according to Fig. 8, the closure cylinder being placed in the base position; Figure 10 shows a section along line X-X of the cylindrical pump lock packing of Figure 8; Fig. 11 shows a section along the line XI-XI of the cylindrical pump lock packing of Fig. 8 with the locking cylinder in the open position; Figure 12 shows some possible embodiments of the locking element; Fig. 13 shows a section along the line XIII-XIII of Fig. 12; Figure 14 shows a section along the line XIV-XIV of Figure 12; Figure 15 shows a section along the line XV-XV of Figure 12; FIG. 16 represents the coded magnetization of the rotor magnets and key magnets of the cylindrical pump lock seal according to the invention; FIG. 17 shows the bearing surface of the locking bar and the rotor capsule which takes the most unfavorable position of closure from the mechanical point of view; FIG. 18 represents the front view of the rotor capsule and the locking bar according to FIG. 17; Fig. 19 shows a cross-section along the line XIX-XIX of the cylindrical pump lock packing according to Fig; 8, the cylinder or barrel closure being in the base position, and Figure 20 shows on a larger scale the central detail of the cylindrical lock pump lock according to Figure 19, with the

lines of the magnetic field.

  It was mentioned in the introductory part of the

  description the structure and operation of the

  cylindrical lock seal with magnetic pump according to the state of the art and the defects that ensue and

will not evoke this subject anymore.

  FIG. 8 represents the longitudinal section of the cylindrical magnetic pump lock seal,

  perfected according to the invention, or part thereof.

  ci - with the key 3 inserted inside.

  If we now compare Figure 8 and Figure 1, the different embodiment of the locking bar 8 appears clearly. Starting from the cross-section of FIG. 9, it is distinctly apparent that instead of 5. the single locking bar 8, so far used, a locking element consisting of the locking bar 8 is used. pushing in the locking bar grooves 11 during the rotation of the locking cylinder 2, and an intermediate element 8a connecting 0 together the locking bar 8 and the locking bar groove 9 of the housing or barrel 1. In the figures 9 to 11, this intermediate element 8a is a steel ball which engages diametrically by shape adjustment in the opening 18 of the rotor support 4, so that it can move about, while simultaneously isolating

  the interior of the rotor support 4 of the external environment.

  It is clearly visible from the partial section of FIG. 10 that the basic position of the locking bar 8 - in the same way as for the previous solutions - is ensured by springs 13, the locking bar 8 being simultaneously become all the narrower that the intermediate element 8a engages without jamming between the locking bar 8 and the wall of the

locking bar groove 9.

  In order to enable secure positioning of the locking bar 8 and the intermediate element 8a, cavities 19 matching the shape of the intermediate element 8a are machined on the rear face of the locking bar 8. FIG. 11 clearly shows that during the rotation of the cylinder or closing cylinder 2, the intermediate elements 8a of the steel balls, as represented in FIG. 1, engage in the opening 18 of the rotor support 4, on the wall of the locking bar groove 9 rolling freely, the locking bar 8 being introduced by the corresponding key 3 into the groove of

  locking bar 11 during rotation.

  There is shown by way of example in FIG. 12 three different intermediate elements 8a: in the cavity 19, to the left of the locking bar 8 is fitted a rolled roll, in the central cavity 19 a steel ball, and in cavity 19 on the right fits a

  cylindrical roller satisfying the general requirements.

  FIG. 13 shows the cross section of the locking bar in contact with the spherical intermediate element 8a, while FIG. 14 represents the cross section of the locking bar 8 in contact with the intermediate element 8a produced in the form of a roller. in barrel. FIG. 15 represents an alternative embodiment of the proposed cylindrical lock seal, more precisely two components thereof, where the locking bar 8 is not in contact with two, three, or four intermediate elements 8a - in this case case the number of openings 18 in the rotor support 4 corresponds to the number of intermediate elements 8a - but o, on the contrary, the intermediate element 8a is formed by a single needle roller, whose length corresponds approximately to the length of the locking bar 8, the needle roller fitting in the opening 18 of the rotor support 4, whose size corresponds to that of the needle roller. Two grooves 17 are machined in a manner known per se on the needle roller which can not move in the longitudinal direction of the cavity 19 of the locking bar 8. The function of the grooves is to prevent the extraction force of the intermediate element 8a and therefore

locking bars 8.

  FIGS. 16a to 16c illustrate the coded magnetization of the rotor magnets 5 and the key magnets 12. It is clear from FIG. 16a that after magnetization has been performed, each individual rotor magnet 5 and each individual key magnet 12 contains a dipole magnetic field with north-south polarity, the position of the separation line separating the north pole and the south pole and their direction indicating the angular division of the magnetization. For example, FIG. 16a shows a vertically developing separation line defining 0 and an angular division at 60, defined by a discontinuous line, used in the cylindrical barrels according to the state of the art. In contrast, for the rotor magnets 5 and the key magnets 12 according to the invention, a much smaller angular division is used - for example at 10 -, (FIGS. 16b, 1I6c), which makes it possible to obtain a number of possible codings that can

  to be almost six times higher.

  The use of an even smaller angular division - disregarding the extremely high accuracy requirements for coding devices - does not seem appropriate, as the common bearing surfaces on the face rear of the rotor caps 6, which have not been brought into the open position due to the intervention of a foreign body or a foreign key, as well as the locking bar 8 exerting pressure, are limited, and that this limitation can lead to the deformation of the locking bar 8 or the rotor cap 6, which ultimately leads to the locking bar 8 snaps under the action of the solicitation in the groove to

  blocking bars 11 which turned a small value.

  In the case shown in FIG. 17 and which constitutes, moreover, the most unfavorable case, the compressive strength of the surfaces in contact with the rotor capsule 6 and with the locking bar 8 is able to withstand the stress without deformation. , or the corresponding torsion torque, which is caused by a foreign body or a foreign key introduced into the

key groove 11.

  In the embodiment shown in FIG. 19, the cross section of the cylindrical pump lock packing according to FIG. 8 is modified so that it is not three times two magnets 12 that are arranged in the key 3, but that this is a total of three key magnets 12 which are mounted in the key 3; these magnets, however, are not made with a U-shaped magnetization which is usual today, but are completely magnetized throughout their thickness, analogous to the rotor magnets 5. In this way appears a unique circular circuit des- -Fields 20 as shown in Figure 20 and which closes by the key magnet 12 and the rotor magnets 5 surrounding the latter of the two faces. It is clearly visible in the figure that the thickness. the key 3 and thus the width of the key groove 10 receiving it are substantially smaller than for the cylindrical barrel cylinder traditional pump shown in Figure 6. In this way, one can provide a smaller wall thickness on both sides of the key groove 10 with a more robust mechanical structure. In this way, on the one hand, it prevents any strong and coarse foreign body is introduced into the key groove 10, or can not be introduced by shock, and secondly, is allowed for reasons described above to achieve a much larger magnetic force field, which improves the safety and accuracy of the closing and opening process. If, for the rotor magnets 5 and the key magnets 12, an angular division at 11 could be used during magnetization, 333 = 35,937 variants could be created with 33 encodings of the rotor magnets in the three cavities. Given what has been said, can be obtained through the modification of the key channel 10 or the shape of the key, more than 150 000 different variants, this

  which already meets the most stringent requirements.

  Of course, the present invention is not limited to the embodiments described and shown, but it is susceptible of many variants accessible to those skilled in the art without one deviates from the spirit of the art. 'invention.

263.1366

Claims (9)

  A magnetic pump cylindrical lock seal comprising at least one closure cylinder or cylinder, sealed in a standard housing, rotatably disposed, and connected to a slide drive member of a lock containing the seal cylindrical lock with a magnetic pump, the locking cylinder containing on the one hand a key channel, into which a key containing a magnetic disk magnetized along a rope or diametrically with a north-south polarity engages, that is to say key containing key magnets, on the other hand a cavity surrounding the key channel on both sides and in which rotors capsules serving as rotor supports, disposed in the cavities and cylindrically completing the locking cylinder, are recessed the number and the axis of rotation of the capsule rotors corresponding to the key magnets of the key introduced into the key channel and a rotor magnet being fi in one or more cavities being provided on the face of the rotor capsule opposite to the rotor magnet, and forming a tongue channel or locking bar in functional relation with the key inserted into the rotor magnets in the open state; an opening covering the locking bar channel being formed in the rotor support, as well as a locking bar groove which covers this opening in the inner wall of the housing, a locking element being guided and mounted movably inside. of said groove in the basic position of the lock cylinder, an elastically biased spar reinforcement being further provided, which determines the relative position of the lock cylinder with respect to the housing or barrel, which holds in the key channel the key inserted when it is placed out of the basic position and which prevents the drill-through drilling of the cylindrical lock barrel, characterized in that to prevent the passage inside the lining of the external or internal impurities resulting internal friction and occurring during the use of the cylindrical pump lock packing, and to ensure the rotation of the With the rotor capsule in the exact open position, the blocking element is in punctual support on the wall of the locking bar groove (9) in each contact cross section, and is at least arranged in shape adjustment. in a cross section of the opening (18) and movable in the opening (18).   Cylinder lock cylindrical packing according to Claim 1, characterized in that the locking element is composed of a locking bar (8) extending along the opening (18) of the rotor support ( 4) and engaging in the locking bar grooves (11) of the rotor capsule (6) and an intermediate element (Sa) connecting together its rear face and the   wall of the locking bar groove (9).   Cylindrical pump lock according to claim 2, characterized in that the intermediate element (8a) is a metal ball engaging by shape adjustment in the circular section of the opening (18), and movable to inside said opening (18>.   Cylindrical cylinder lock according to claim 2, characterized in that the intermediate element (8a) is a barrel roll, engaging by shape adjustment in the cross section of the opening (18) and movable inside said opening (18). -   Cylindrical cylinder lock according to claim 2, characterized in that the intermediate element (8a) is a cylindrical roller, engaging by shape adjustment in the cross-section of the opening (18) and movable to inside said opening (18).   6. Cylindrical cylinder lock according to claim 2, characterized in that the intermediate element (8a) is a needle roller, engaging by shape adjustment in the cross section of the opening (18) and movable inside of said aperture (18), whose length substantially corresponds to   the length of the locking bar (8).   7. Cylinder lock lock with pump according to   any of claims 1 to 6, characterized in that   that the intermediate element (8a) enters one or more cavities (19) formed on the rear face of the locking bar (8), grooves (17) being made transversely on the intermediate element (8a) or on the locking bar (8), to prevent their extraction force. Magnetic pump cylindrical lock seal comprising at least one closure cylinder or cylinder, sealingly insulated in a standardized housing, rotatably disposed, and connected to a slide drive member of a lock containing the seal. cylindrical lock with a magnetic pump, the locking cylinder containing on the one hand a key channel, into which a key containing a magnetic disk magnetized along a rope or diametrically with a north-south polarity engages, that is to say key containing key magnets, on the other hand a cavity surrounding the key channel on both sides and in which rotor caps acting as rotor supports, disposed in the cavities and cylindrically completing the closure cylinder, are the number and axis of rotation of the capsule rotors corresponding to the key magnets of the key introduced into the key channel and a rotor magnet being fi in one or more cavities being provided on the face of the rotor capsule opposite to the rotor magnet, and forming a tongue channel or locking bar in functional relation with the key inserted into the rotor magnets in the open state; an opening covering the locking bar channel being formed in the rotor support, as well as a locking bar groove which covers this opening in the inner wall of the housing, a locking element being guided and mounted movable to the inside of iadite groove in the basic position of the lock cylinder, an elastically biased spherical reinforcement being further provided, which determines the relative position of the lock cylinder with respect to the housing or barrel, which maintains in the key channel the key inserted. when the latter is placed out of the basic position and which prevents drilling by drilling the cylindrical lock barrel, characterized in that, in order to increase the number of variants of the cylindrical lock lock pump and to increase the magnetic interaction between the key magnets (12) and the rotor magnets (5), the thickness of the key magnet (12) corresponds to the thickness r of the key, the key magnets (12) magnetized at most in an angular division to 20 being surrounded on both sides by a rotor magnet   (5) magnetized identically.   Pump cylindrical lock according to Claim 8, characterized in that the key magnets (12) and the rotor magnets (5) are magnetised according to a angular division at 11.