RU2761228C2 - Secret padlock - Google Patents

Abstract

FIELD: locking systems.

SUBSTANCE: secret padlock actuating with a key is described that contains: stator case (2); rotor case (4) installed with the possibility of rotation in the specified stator case and equipped with keyhole (6) for the insertion of the key for actuating the padlock; and an encoding means for preventing the rotation of specified rotor case (4) relatively to specified stator case (2) and, vice versa, for providing the possibility of the specified rotation, if the allowed key is inserted into specified keyhole (6). The padlock differs in that the padlock encoding means contains two main types of pins located on rotor case (4) and operating in accordance with two different methods for the determination of a padlock locking state, as well as in that the specified pins are located at different points of rotor case (4) around its imaginary axis of rotation.

EFFECT: obtaining a secret padlock.

12 cl, 22 dwg

Description

The technical field to which the invention relates

The present invention relates to a key operated security lock of the type comprising:

- stator housing;

- a rotor housing mounted for rotation in said stator housing and provided with a keyhole for inserting a key to operate the lock; and

- coding means for preventing rotation of said rotor housing relative to said stator housing and, conversely, to enable said rotation if a permitted key is inserted into said keyhole.

Objective and essence of the invention

An object of the present invention is to provide a lock of the above-mentioned type, which guarantees a high degree of security and reliable operation. Another object of the invention is to accomplish the above object with a lock having a relatively simple structure and suitable for mass production.

To accomplish the aforementioned tasks, the lock described herein is characterized in that said encoding means comprises:

- at least one first pin located on the specified rotor housing and made with the possibility of sliding along its own axis, protruding into the specified keyhole for inserting a key;

- at least one second pin located on the specified rotor housing in a fixed position along its own axis, with the possibility of rotation about the specified axis, and protruding into the specified keyhole for inserting a key;

- at least one third pin disposed on said stator housing and slidable along its own axis, interacting with said first pin to determine a lock lock state in which said first pin or third pin is set to an obstructed position while on both sides of the contact surface of the specified rotor housing and the specified stator housing; and

- at least one blocking element located on the specified rotor housing and made with the possibility of moving between the operating position, in which it protrudes from the specified rotor housing and enters the socket made in the specified stator housing, and the position in which the specified element is completely located in said rotor housing, said second pin having an outer surface adapted to cooperate with said locking element to determine the position of said element based on the orientation of said second pin about its own axis.

Preferably, said at least one first pin and said at least one second pin are mounted at different positions around an imaginary central axis of rotation of said rotor housing.

Brief Description of Drawings

Additional features and advantages of the invention will follow from the description below with reference to the accompanying drawings, which are given by way of non-limiting example only. The drawings show the following.

- Fig. 1 is a perspective view of a preferred embodiment of the lock described herein.

- Fig. 2 shows in the same perspective view the lock of FIG. 1, from which the cover was removed to expose additional parts of the lock.

- Fig. 3 is a view of the lock of FIG. 1 from the side opposite to that shown in FIG. one.

- Fig. 4 shows, in side orthogonal projection, the lock of FIG. one.

- Fig. 5 is a cross-sectional view of the lock along the V-V plane of FIG. 4.

- Fig. 5A is a cross-sectional view of the lock in the same plane as in FIG. 5 in a state in which a key is inserted to operate the lock.

- Fig. 6 is a cross-sectional view of the lock along the VI-VI plane of FIG. 4.

- Fig. 6A is a cross-sectional view of the lock in the same plane as in FIG. 6 in a state in which a key is inserted to operate the lock.

- Fig. 7 is a cross-sectional view of the lock along the plane VII-VII of FIG. 4.

- Fig. 7A is a cross-sectional view of the lock in the same plane as in FIG. 7 in a state in which a key is inserted to operate the lock.

- Fig. 8 is a cross-sectional view of the lock along the plane VIII-VIII of FIG. one.

- Fig. 9 is a cross-sectional view of the lock in the same plane as in FIG. 8 in a state in which a key is inserted to operate the lock.

- Fig. 10 is a cross-sectional view of the lock in the same plane as in FIG. 8 in a state in which, as in FIG. 9, a key is inserted to operate the lock, but from the opposite side.

- Fig. 11 is a perspective view of the rotor housing of the lock of FIG. one.

- Fig. 12 is a bottom view of the rotor housing of FIG. eleven.

- Fig. 13A and 13B show a perspective and, respectively, front view of the key for operating the lock of FIG. one.

- Fig. 14 is a cross-sectional view of yet another embodiment of the lock described herein.

- Fig. 15 shows the lock of FIG. 14 with the appropriate key for operating this lock inserted from the left side.

- Fig. 16 shows the lock of FIG. 14 with a key inserted to operate this lock, in a key lock state.

- Fig. 17 shows the lock of FIG. 14 with the key for activating this lock inserted from the right side.

- Fig. 18 is a top view of the active part of the key for operating the lock of FIG. 14 according to one embodiment.

Implementation of the invention

In the following description, various specific details are illustrated for the purpose of a thorough understanding of embodiments of the invention. These options for implementation can be obtained without one or more specific parts or using other methods, components, materials, etc. In other instances, known structures, materials, or operations are not illustrated or described in detail so as not to obscure the understanding of various aspects of an embodiment of the invention.

The references used herein are for convenience only and do not define the scope of protection or the scope of the embodiments of the invention.

The lock described herein, generally designated by reference numeral 10, generally comprises:

- stator housing 2;

- rotor housing 4 rotatably mounted in the stator housing and provided with a keyhole 6 for inserting a key to operate the lock; and

- coding means for preventing the rotation of the rotor housing 4 relative to the stator housing 2 and, conversely, to ensure the possibility of said rotation if a permitted key is inserted into the keyhole 6.

The stator body 2, generally disk-shaped, has a through-hole 2A in the center, in which the rotor body 4 is rotatably mounted.

In the example shown, the lock 10 is configured to actuate a gear blocker (not shown) and for this purpose is equipped with a gear wheel 8 mounted directly on the rotor housing 4 (see Fig. 2) and designed to engage with the corresponding gear wheel of the aforementioned blocker (not shown).

The lock coding device contains two main types of pins located on the rotor body 4 and working according to two different methods to determine the locking state of the lock.

These pins are located at different points of the rotor housing 4 around its imaginary axis of rotation.

As will become clear below, this type of arrangement of the coding means makes it possible to reduce the overall dimensions of the lock in the axial direction and, in general, to provide a stronger and more reliable locking structure.

In accordance with the given example (Figs. 5 and 6), the first type of pins is represented by pins 22 located in the corresponding substantially radial holes made in the aforementioned housing, which define a keyhole 6 made in the rotor housing so that it is connected to its outer surface.

The pins 22 are made with the possibility of sliding along their own axis in the indicated holes and with one end protrude into the keyhole 6, and with their other, opposite end, face the stator housing.

The pins 22 are adapted to interact with the pins 24 installed in the stator housing 2 in respective positions, in the corresponding holes made in the stator housing and passing into the inner hole 2A. In these holes, the pins 24 can slide along their own axis in the same way as the pins 22. Preferably, the respective springs 26 located in these holes act on the pins 24, pushing them towards the rotor body 4 and the pins 22.

FIG. 5 shows the locking state of the lock in which the aforementioned holes are aligned with each other and the pins 22 and 24 cooperate to determine the rotation locked state of the rotor body 4.

In particular, the pins 24 pushed by the springs 26 enter the same holes as the pins 22, being positioned to pass through the rotor housing 4 and the stator housing 2, thereby preventing them from moving relative to each other.

To deactivate said locking, the key for operating the lock (shown in Fig. 13A and 13B) on its active part 100 has recesses 102, made with the possibility of receiving corresponding ends 22A of the pins 22 and having a predetermined shape and size in order to install pins 22 and 24 are flush with the contact surface of the stator housing 2 and the rotor housing 4.

Another type of pins installed in the rotor housing 4, on the contrary, is formed by pins 42 located in the rotor housing 4 in a fixed position along its own axis, but with the ability to rotate around it. The pins 42 can be installed in the rotor housing 4 in different ways. In various preferred embodiments, as in the embodiment shown (FIGS. 5 and 6), the pins are installed in corresponding holes made in the rotor housing and having a depth equal to the height of the pins themselves, so that the ends of the pins facing the stator housing 2 are flush with the outer surface of the rotor body 4. Thus, the pins 42 are substantially locked against any movement along their own axial direction, on the one hand by the bottom of the holes in which they are received, and on the other hand by the inner surface of the hole 2A.

The pins 42 are made with the possibility of interaction with the corresponding locking elements 44, which are also placed in the rotor housing 4 and are located next to the specified pins. Each element 44 is movable between an operating position, in which it protrudes from the outer surface of the stator housing, entering a socket 62 formed in the inner surface of the stator housing 2A, and an inoperative position, in which, on the contrary, it is completely contained in the rotor housing.

The outer surface of the pins 42 is configured to release and lock the above-mentioned inoperative position of the element 44 in accordance with the orientation of the pin 42 about its own axis. In particular, said side surface is generally dimensioned so as to prevent the element 44 from completely re-entering the rotor housing, thus keeping it in the indicated operating position, in which it is inserted into the seat 62. However, in a special place, its outer On the surface, the pin 42 has a groove 42A, which, on the contrary, is configured to receive at least a part of the element 44 in order to provide sufficient space in the rotor housing for the element 44 so that it can completely re-enter the said housing, moving into the inoperative position.

Preferably, the rotor housing 4 may have springs 46 acting on the element 44, pushing it against the seat 62.

FIG. 5 shows a locking state in which each member 44 fits into a respective seat 62 and is locked in this position by a corresponding pin 42 to prevent rotation of the rotor housing 4.

In light of the above, in order to deactivate this locking state, it is necessary to orient the pins 42 so as to set their respective grooves 42A in the direction of the elements 44.

For this, at their ends facing the keyhole 6, the pins 42 have an eccentric pin 42B protruding into the keyhole and intended to engage with a track 104 made on the key for activating the lock (Fig. 13A).

Track 104 extends in the longitudinal direction of the key and is profiled so as to rotate the pin 42 by inserting the key into the keyhole, positioning it in the appropriate orientation, whereby the said non-working position of element 44 is possible.

When the pins 42 are oriented appropriately, the members 44 can enter the rotor housing 4 simply by rotation of the rotor housing itself, due to the axial load acting on them from the surfaces of the respective seats 62 after said rotation.

It should be noted here that the pins 22 and 42, located as shown above, can be made in several transverse planes of the lock to allow a larger number of combinations.

According to the embodiment shown, said pins are formed in two transverse planes, shown respectively in FIGS. 5 and 6. Preferably, the pins of different planes are in any case located in appropriate positions in order to simplify the overall structure of the lock. In addition, again to simplify construction, respective pins 42 of two different planes are associated with the same locking element 44, having an elongated shape and oriented in the axial direction of the lock (see Figs. 11 and 12). Consequently, the working position and non-working position of this element is controlled in two planes, and only when the pins 42 of both planes are oriented appropriately, this element can move to its non-working position.

The lock, in any case, can also provide additional planes in which only one of the two types of pins are made, in accordance with the specific requirements of the application and taking into account the available overall dimensions. In this regard, in FIG. 11 and 12, a third font 42 can be seen installed in an additional plane relative to the pins 42 of the planes shown in FIG. 5 and 6.

With reference to the key for operating the lock, the above-mentioned active part 100 of the key intended for interaction with the encoding means of the lock is characterized in that it has at least one longitudinal section of constant cross-section having a polygonal profile, the number of sides of which is equal to the number of positions of the encoding means about the axis of rotation of the rotor housing 4. In various embodiments, as in the embodiment shown, portion 100 in particular has a substantially hexagonal outer profile. On respective sides, the aforementioned recesses 102 and tracks 104 are provided for engaging the pins 22 and 42.

In various preferred embodiments, as in the embodiment shown, the rotor housing 4 further comprises a protective body 82 disposed in a corresponding socket in the rotor housing and protruding into the keyhole 6 to obstruct it (FIGS. 5, 6 and 8) ...

The function of the body in question is to resist any possible break-in attempts made through the specified keyhole. Preferably, it is made of a high strength metallic material (eg hardened steel, special alloys, sintered steel, etc.) to also make it possible to prevent possible burglary actions using a drill.

In various preferred embodiments, as in the embodiment shown, furthermore, the body 82, like the aforementioned encoding means, is mounted at a predetermined radial position along the aforementioned circular track (FIGS. 5 and 6).

In various preferred embodiments, as in the embodiment shown, the body portion 82 protruding into the keyhole 6 and indicated by the reference sign 82A preferably has the following dimensions:

- length, approximately corresponding to the length of the specified keyhole (Fig. 8); and / or

- a height equal to at least half the height of the specified keyhole (Fig. 5 and 6); and / or

- a width approximately equal to or greater than half the minimum width of said keyhole (FIGS. 5 and 6).

Returning again to the key for activating the lock, it should be noted that its active part 100 has a groove 106 extending in the longitudinal direction starting from the tip of the key and is provided for completely accommodating the protective body part 82A therein. In particular, this groove has a length (measured in the axial direction of the lock) equal to that of portion 82A and a depth approximately equal to the height of said portion.

It should be noted here that in various preferred embodiments, as in the embodiment shown, the body 82 has a length slightly less than the length of the keyhole 6, so that the key portion 100 has at least one full cross-sectional part, the functions of which are in the direction of the key and giving it rigidity. In addition, the body 82 is mounted for movement in the rotor housing 4 in the axial direction of the lock, between the first end position and the second end position, one or the other of which said body receives after inserting the key into the lock, depending on the side from which the key is inserted ... These two positions are defined by respective opposing surfaces 52, 54 provided in the rotor housing 4. In these positions, the body 82 is positioned so that it occupies the outer opening of the keyhole 6 on the side of the lock opposite to the side from which the key is inserted, preventing any gaps or slots between the inserted key and said body through which tools can be inserted in a tampering attempt. castle.

With regard to the key, at the end of the groove 106, opposite the tip of the key, an opposing edge 108 is defined for contacting and pushing the body 82, during insertion of the key, into one of the two aforementioned end positions.

In the case when, again using the breaking tool, the body 82, on the contrary, is pushed, even slightly, towards the inside of the keyhole 6, for example, in an attempt to find a support for the tool, it will again push the key at its end 108, moving it out of the corresponding working position and, thus, again transferring the lock to the blocking state.

Therefore, in light of the above, the body 82 provides effective and complete protection against burglary attempts made through the keyhole 6.

FIG. 9 and 10, the body 82 is shown in the above two end positions for the insertion of the key from the right and, respectively, from the left.

It should be noted that the aforementioned end positions of the body 82 also define the axial position of the key in the keyhole 6.

In various preferred embodiments, as in the embodiment shown, at least one pin 84 is slidably mounted in the body 82 (for a reason that will be explained below, in the embodiment shown here there are two pins), controlled by a corresponding spring 86, which is also contained in the body, in a position in which the end of the pin 84 opposite the spring protrudes from the body 82 through a corresponding opening 82 'to exit on the inside of the keyhole 6.

The pin 84 is provided to interact with the pin 22 'and a corresponding pin 24' with respect to which the pin 84 is aligned (FIGS. 7 and 8).

Pins 22 'and 24' correspond to the above pins 22 and 24.

However, the pins in question define a special locking state that cannot be deactivated only by a recess made in the key, for example, by the aforementioned recesses 102.

Indeed, the pin 22 'is significantly shorter in length than the other pins 22, so that in order for the pin 22' and the pin 24 'to be flush with the contact surface of the rotor housing and the stator housing, as shown above in relation to the pins 22 and 24, so that unblock the rotor body, the active part of the key must have a corresponding part protruding from the body of the key itself.

In various preferred embodiments, as in the embodiment shown, said portion is defined by a ring 30 of a predetermined diameter located on the key.

As discussed in more detail below, the ring 30 can move freely relative to the key in the transverse direction, so that during insertion of the key it can self-center in the corresponding slot of the keyhole 6, namely so as not to interfere with the key when it is inserted.

After insertion of the key, the ring 30 on one side comes into contact with the pin 84, and on the other side with the pins 22 'and 24'.

In particular, the pin 84, driven by the spring 86, conversely acts on the ring 30, pushing it until it protrudes from the key, as well as pushing the pins 22 'and 24'.

The ring 30 must have a predetermined diameter so that, supported by the pin 84, it sets the pins 22 'and 24' in a non-locking position (Fig. 7A).

In particular, with regard to the methods of mounting the ring 30 on the key, it is preferably mounted on a cylindrical pin 31, in a hole 112 formed on the side of the active part 100, opposite the side of the key on which the groove 106 is formed.

The ring 30 has a significantly larger diameter than the pin 31 and can move in the hole 112 in a direction perpendicular to the corresponding side of the portion 100.

Preferably, during this movement, the ring 30 is guided laterally by the walls of said opening so that it is in a defined position in a direction transverse to the longitudinal direction of the key. For this, in the transverse direction, the opening 112 has a width slightly greater than the width of the ring. Likewise, ring 30 is preferably also bounded by the front and rear walls of opening 112 with respect to longitudinal movement within a limited range sufficient to provide minor movements to prevent any possible contact between the ring and nearby parts when the key is inserted into the lock. Therefore, in the transverse direction of the key, the hole 112 also has a length slightly greater than the diameter of the ring.

It should be noted that although the ring 30 is a preferred embodiment, other elements could in any case be envisaged that are configured to operate in a similar manner. For example, the key can have a ball placed in a socket, made in the form of a clip on the part 100 of the key, and configured to move in this socket, as shown above for the ring 30.

Returning to the lock, it should be noted that in the case where the lock is intended to be operated with a key provided with a ring 30 and at the same time the protective body 82 is slidably mounted between two end positions, as shown above, the protective body 82 may have two pins 84 mounted at two different positions in the axial direction of the lock (FIGS. 8, 9 and 10).

Each pin is adapted to cooperate with the ring 30 and the pins 22 'and 24' for one of the two end positions assumed by the body 82. In this connection, reference can be made to FIG. 9 and 10, respectively showing the active state of the right pin 84 for the end position of the body 82 achieved after inserting the key from the right side and the active state of the left pin 84 for the end position of the body 82 achieved after inserting the key from the left side.

It is not difficult to understand that the distance between the two pins 84 will be substantially equal to the distance between the aforementioned two end positions of the body 82.

In various preferred embodiments, as in the embodiment shown in FIG. 14-17, the protective body 82 is controlled in one of two positions by means of an elastic member 85. For reasons that will become apparent below, the end position thus controlled corresponds to the position in which the protective body 82 faces the inner side of the door or window frame on which the lock is installed.

In various preferred embodiments, as in the embodiment shown, the resilient member is mounted in a seat provided in the rotor housing 4 between the protective body 82 and the inner wall of the rotor housing 4. In various preferred embodiments, as in the embodiment shown, said resilient member is formed by a coil spring mounted with its axis parallel to the axis of rotation of the rotor housing. Preferably, the two opposite ends of the spring are disposed in respective flat-bottomed bowl bodies 87, one of which engages with the protective body 82 and the other with the inner wall of the rotor housing 4.

Thanks to the resilient member 85, the protective body 82 can move the key previously inserted into the lock to a locked position in which the lock is locked.

In particular, when the key is first inserted into the lock to its end position, the protective body 82 is pushed by the opposite edge 108 of the key into its end position, in the opposite direction to the direction of action of the elastic element 85, and thus the elastic element is "charged" (FIG. 15). It is due to the presence of the elastic element during the operation of the lock, in order to hold the key in the final position, the user must exert constant pressure on the key, against the above-mentioned element.

If the user then releases the key, the resilient member 85 pushes the protective body 82 back to its opposite end position, which in turn pushes the key from the end position to the locked position (FIG. 16). Indeed, in this connection, FIG. 16 shows pins 22 and 24 in the locked position of the lock as a result of the above movement of the key.

It should be noted that the amount of movement can be minimal, provided that it is sufficient to move the code recesses provided on the key from their lock release position.

The described configuration was obtained as a security measure, when the key is inserted into the lock from the left, from the inside of the door or window frame, in order to prevent burglary attempts, in which the insert is rotated from the outside using appropriate burglary tools, using the fact that the lock is in the unlocked the state provided by the inserted key.

On the other hand, with reference to FIG. 17, it should be noted that, conversely, when the key is inserted from the opposite side, i.e. from the outside of the door or window frame, the resilient member 85 does not interfere with the operation of the lock in any way.

Returning to the effect of the elastic element 85 on the key, it should be noted that it is counteracted by the effect that the springs 26 indirectly exert on it by means of pins 22 pushed into the recesses 102 of the key, so that the elastic element 85 must be dimensioned in such a way that it could overcome the aforementioned impact exerted by the springs 26.

However, taking into account that when the lock is actuated, as has been shown, the user himself must overcome the force of the elastic element 85 in order to move the key to its final position, it is desirable that the action exerted by the above element be limited in order to reduce the resistance , counteracting the user and, thus, improve the usability of the lock. For this, preferably, the key has several recesses made with the possibility of interaction with pins 22 (in Fig. 18 denoted by the reference numeral 102 '), which contain a section extending in the longitudinal direction and having a constant depth along the key axis so as not to move the corresponding pins 22 during the displacement of the key caused by the protective body 82, and therefore do not apply force to the springs 26 associated with them. Therefore, only some of the springs 26 will actually exert the opposite effect on the elastic element 85, so this can be envisaged at the design stage to apply less elastic force.

In addition, it should be noted that the solution described here also relates to a key blank provided with an active part and having some of the features shown above in relation to the key for operating the lock, excluding the recesses 102 and tracks 104 obtained later at the time of the key coding.

Finally, returning to the above embodiments, it should be noted that the lock described herein may also have the following general features:

- on the protective body (82), at least two pins (84) mounted on it are located, mounted at a distance from each other along the axis of rotation of the rotor body (4), which are made to slide along their own axis and are propelled by a spring ( 86) to an additional pin (22 ') located on the aforementioned rotor housing (4) and installed on the opposite side of the keyhole (6) for inserting a key, moreover, in the first of the end positions of the protective body (82) to interact with the specified additional pin ( 22 ') the first of said two pins is provided, while in the other end position the other of said two pins is provided for engagement with said additional pin (22');

- preferably, said additional pin (22 '), in turn, is configured to interact with an additional pin (24') located on the stator housing (2) in order to determine the locking state of the lock, in which one or the other of the additional pins (22 ' , 24 ') is set to the blocking position, being on both sides of the contact surface of the rotor housing and the stator housing; and

even more preferably, the distance between said two pins (84) in said axial direction is substantially equal to the length of the portion along which said protective body (82) can move between said two end positions.

Of course, without prejudice to the principle of the present invention, it is possible to apply the details of construction and embodiments of the invention that differ, including significantly, from what has been described and illustrated here by way of example only, without going beyond the scope of legal protection defined in the attached claims.

Claims (27)

1. A key operated lock with a secret, comprising: - stator housing (2); - rotor housing (4) rotatably mounted in said stator housing and provided with a keyhole (6) for inserting a key to operate the lock; and - coding means for preventing rotation of said rotor housing (4) relative to said stator housing (2) and, conversely, to enable said rotation if a permitted key is inserted into said keyhole (6); moreover, the specified encoding means contains: - at least one first pin (22) located on said rotor housing (4) and made to slide along its own axis, protruding into said keyhole (6) to insert a key; - at least one second pin (42) located on said rotor housing (4) in a fixed position along its own axis, rotatable about said axis, and protruding into said keyhole (6) for inserting a key; - at least one third pin (24) located on said stator housing (2) and made to slide along its own axis, interacting with said first pin, to determine the state of the lock lock, in which the said first pin (22) or the third pin (24) is set to an obstacle position, being on both sides of the contact surface of said rotor housing and said stator housing; and - at least one blocking element (44) located on the specified rotor housing and made with the possibility of moving between the working position, in which it protrudes from the specified rotor housing (4) and enters the socket (62) made in the specified stator housing, and a position in which said element is completely contained in said rotor housing (4), said second pin (42) having an outer surface adapted to cooperate with said locking element (44) to determine the position of said element based on the orientation of said second a pin about its own axis, characterized in that said rotor housing (4) comprises a protective body (82) protruding into said keyhole for inserting a key to block it in order to prevent possible burglary attempts made through said keyhole, for example, by means of a drill, and the specified protective body (82) is installed with the possibility sliding along the specified imaginary axis of rotation between two opposite end positions. 2. The lock according to claim 1, in which: - said at least one first pin (22) and said at least one second pin (42) are installed in different positions around an imaginary central axis of rotation of said rotor housing (4); - the specified rotor housing contains a plurality of units of the specified at least one first pin and / or a plurality of units of the specified at least one second pin, all of which are installed in different positions around the imaginary central axis of rotation of the specified rotor housing (4); - the first pins and the second pins (22, 24) are located one after the other along different sections of the specified rotor housing (4); and - the number of said third pins (24) is equal to the number of said first pins (22), and said third pins (24) are mounted on said stator housing (2) in positions corresponding to the positions of said first pins (22) around said imaginary axis of rotation. 3. A lock according to claim 1, wherein said at least one first pin (22), said at least one second pin (42) and said protective body (82) are installed in different positions around an imaginary central axis of rotation of said housing ( 4) rotor. 4. A lock according to claim 1 or 3, wherein the portion (82A) of said protective body projecting into said keyhole (6) has: - a length approximately corresponding to the length of the specified keyhole; and / or - a height equal to at least half the height of the specified keyhole; and / or - a width approximately equal to or greater than half the minimum width of the specified keyhole. 5. A lock according to claim 1, wherein said protective body (82) is slidably mounted along said imaginary axis of rotation between two opposite end positions, in at least one of said two opposite end positions, the corresponding end of said protruding part (82A ) is installed so as to occupy the outer hole of the specified keyhole (6), located opposite the side from which the key is inserted. 6. A lock according to claim 1, in which an elastic element (85) is installed in said rotor housing (4), which is provided for controlling said protective body (82) in one of said end positions. 7. A lock according to claim 1, in which at least one pin (84) mounted thereon is disposed on said protective body and is capable of sliding along its own axis and moving by means of a spring (86) in the direction of an additional pin (22 ' ) located on the specified rotor on the opposite side of the specified keyhole (6). 8. A key designed to operate the lock according to any one of paragraphs. 1-7, and the specified key contains an active part (100) designed to interact with the coding means of the specified lock, characterized in that said active part has a cross-section having a polygonal profile with many sides, and on one side said active part (100 ) has a groove (106) extending longitudinally, starting from the tip of the key, and designed to accommodate a part (82A) of said protective body protruding into said keyhole (6) of said rotor housing (4) of said lock, completely enclosing her, moreover, at the end of said groove (106), opposite the tip of said key, said key defines an opposite edge (108) provided for contacting with said protective body (82) and pushing it, during key insertion, along an imaginary axis of rotation of the body ( 4) the rotor of the specified lock, to the end position. 9. A key according to claim 8, wherein said opposite edge (108) is provided for contacting and pushing said protective body (82), during insertion of the key, into an end position in which said protruding part (82A) is installed flush with the opening of said keyhole on the side opposite to the side from which the key is inserted. 10. A key according to claim 8 or 9, in which on the side opposite to said groove (106), on said active part (100) there is an element (30) mounted thereon, having a predetermined size, which is movable in the direction, perpendicular to the specified side, and is located in the slot made on the specified side, which is connected to the specified groove (106), and the specified element is configured to interact both with the specified pin or pins located on the specified protective body (82), and with the specified another pin (22 ') located on the specified rotor housing, mating with them by means of the specified predetermined size. 11. The key according to any one of paragraphs. 8-10, in which the specified portion has a hexagonal cross-section. 12. The key according to any one of paragraphs. 8-11, in which a plurality of recesses (102) are made on said active part (100), provided for contacting with said at least one pin (22) of said lock, and in which each of a subset of said plurality of recesses (102) contains a section extending in the longitudinal direction and having a constant depth, provided in such a way that during the operation of the specified key, the depression of the specified subset will not move the corresponding first pin (22), which is in contact with it, during the movement of the key along the axis of rotation of the body (4) the rotor of the specified lock.

Images