RU2090720C1 - Lock - Google Patents

Abstract

FIELD: locking devices. SUBSTANCE: lock has key and lock mechanism which consists of body and core movably installed in it. Core is engageable with key working part. Key working part has key code in form of coordinates of code surfaces and/or coordinates of permanent magnets. Body accommodates switch for charging modes of lock operation, control shells and rods. Control shells are installed movably and kinematically interconnected. Control shells have code grooves consisting of rectilinear slots and connecting sections. Spring-loaded rods are installed for straight line motion. They are engageable with code grooves through pins secured to them which are located in rectilinear slots of code grooves. Rods are engageable with key working part with the aid of feelers or permanent magnets attached to them. Core is kinematically connected through control shell with movable member which connects lock mechanism with actuating mechanism. Key code is equivalent to lock code which equals coordinates of intersection of axial lines of rectilinear slots and beginnings of connecting sections. EFFECT: higher efficiency. 41 dwg, 2 tbl

Description

 The technical solution relates to locking devices. Their functioning is possible with a secret key element. The lock has two operating modes (unlocking, locking) and is used together with an executive device [1] It can be: a mechanism for locking doors of rooms, cars and other objects (locking device), a device for closing (opening) electrical circuits, a device for switching operating mode of the electronic unit, etc.

 The cylinder locking mechanism [2] comprises a housing in which spring-loaded pushers and delays are arranged in the form of locking pins, as well as a rotatable cylindrical core that is connected to a connecting element for connecting the lock with the locking mechanism. Delays connect the core to the body. In the core there are surfaces intended for interaction with the working part of the key (the closest analogue).

This lock has low secrecy as it controls the key code in only one position, when the rotation angle is 0 ^o .

 The problem solved by the proposed device is to eliminate the above drawback, that is, the lock consists of a key to the lock mechanism, the key consists of a working part, on which the key code is applied, and a head, for which the key is held by hand. The key code can be mechanical, which is made in the form of coordinates of some points of the code surface, or magnetic, made in the form of coordinates of the poles of permanent magnets, which are fixed to the working part of the key. On a key several mechanical and magnetic codes can be applied. Key codes are equivalent to lock codes, which is a prerequisite for unlocking the latter.

 The lock mechanism is located in the housing, on which there are elements for mounting it on the actuator. The lock mechanism has two modes of operation: unlocking and locking. The mode switch is designed to switch them. The lock code is applied in the form of code grooves, which are made on control shells mounted movably and kinematically connected to each other. One of the control shells is kinematically connected with the movable element of the actuator. Each code groove contains a straight groove and a connecting portion. The lock code consists of the set of coordinates of the points of intersection of the axial (central) lines of the straight grooves with the beginnings of the axial (central) lines of the connecting sections. The code grooves interact with the spring-loaded rods installed with the possibility of linear movement through the pins attached to the last. The rods are equipped with probes intended for mechanical interaction with the code surfaces of the key, or permanent magnets designed for power interaction with the poles of the magnetic code of the key. The core is mounted movably in the housing, connected to the control shells and has surfaces for interaction with the working part of the key. In the lock mechanism, the pins are installed in the straight grooves of the code grooves.

The technical result of this technical solution is that without a key it is impossible to rotate the core connected to the control shells. Rotation of the core and the associated control shells is possible only if the key with the correct code is in the keyhole. An equivalent technical result is to simplify the design by eliminating an additional lock from it. In addition, modifications ΦR and ΦZ can work with rotation angles less than 360 ^o .

In FIG. 1 is a longitudinal section through a lock ΦR together with a locking device;
in Fig.2 a section along II-II of Fig. one;
in Fig.3 a section along III-III of Figs. one;
in Fig. 4 a section along IV-IV of Fig. one;
in Fig. 5 a section along VV of Fig. one;
Fig.6 section along VI-VI of Fig. one;
7 a section according to VII-VII of FIG. one;
on Fig section along VIII-VIII of Fig. 1 on a reduced scale (the lock is closed for one turn of the key);
Fig.9 is a General view of the key on an enlarged scale;
in Fig.10 cutaway according to XX of Fig. 9;
11 a section along XI-XI of FIG. 9;
12 is a section along XII-XII of FIG. 9;
on Fig section along XIII-XIII of Fig. 9;
on Fig section along XVI-XVI of Fig. 9;
in FIG. 15 is a section according to II-II of FIG. 1 (the position of the parts corresponds to the moment when the key is inserted into the lock);
on Fig section through III-III of Fig. 1 (the position of the parts corresponds to the moment when the key is inserted into the lock);
in FIG. 17 a section according to II-II of FIG. 1 (the position of the parts corresponds to the moment when the key is inserted into the lock and turned 30 ^o in the unlocking direction);
on Fig a section along III-III of Fig. 1 (the position of the parts corresponds to the moment when the key is inserted into the lock and turned 30 ^o in the unlocking direction);
in FIG. 19 is a section according to II-II of FIG. 1 (the position of the parts corresponds to the moment when the key is turned 30 ^o in the direction of locking);
on Fig section along III-III of Fig. 1 (the position of the parts corresponds to the moment when the key is turned 30 ^o in the direction of locking);
in FIG. 21 is a general view of the ΦZ castle from the keyhole side;
on Fig a General view of the key;
in Fig.23 section along XXIII-XXIII Fig.21;
on Fig scan section along XXIV-XXIV of Fig. 22;
on Fig scan section along XXV-XXV of Fig. 22;
on Fig section along XXVI-XXVI of Fig. 21;
on Fig section along XXVII-XXVII of Fig. 21;
on Fig a section along XXVIII-XXVIII of Fig. 21;
on Fig scan section along XXIX-XXII. 28;
on Fig scan section along XXX-XXX of Fig. 28;
on Fig longitudinal section of the lock ZR;
on Fig section along XXXII-XXXII of Fig. 31;
on Fig section along XXXIII-XXXIII of Fig. 31;
on Fig section along XXXIV-XXXIV of Fig. 32;
on Fig section along XXXV-XXXV of Fig. 32;
on Fig section along XXXVI-XXXVI of Fig. 32;
on Fig section along XXXVII-XXXVII of Fig. 32;
on Fig a General view of the key;
on Fig section along XXXIX-XXXIX of Fig. 38.

 in Fig.40, 41 the lock in disassembled form.

 The lock ΦR is shown in FIG. 1-20.

 The lock (Fig. 1) contains a housing 1, in the blind hole of which there is a glass 2 with a blind hole, in which axial grooves are made 3. In the hole of the glass, a control washer 4 is mounted for rotation (Fig. 2), on the end surface of which there are code grooves 5, 6. Each of the code grooves consists of a straight groove 7 and a connecting section 8. The grooves 7 are located along the radii of the control washer 4. The axial lines of the connecting sections 8 are segments of a logarithmic spiral or a combination of segments of a logarithmic with piracy and circles. In the through hole of the housing 1 by means of a spline connection, a guide 10 for the key is installed. In the guide 10, a figured hole 11 is made, the shape of which corresponds to the shape of the key.

 Next, in the hole of the cup 2, a ferrule 12 (Fig. 1,3) is installed with a tooth 13 that enters the groove 3. In the ferrule 12 there are radial channels 14 and 15 in which the rods 16, 17 are movably mounted. The springs 18 press the rods 16, 17 in the direction of the hole 19, made along the longitudinal axis of the cage 12, which consists of two parts. The probes 20, 21 are connected to the rods 16, 17, respectively, and are installed in the holes connecting the channels 14, 15 and the hole 19. The pins 22, 23 are connected to the rod 16, and the pins 24, 25 are connected to the rod 17. The axis of the pins 22, 23, 24, 25 are parallel to the axis of the hole 19. Pin 22 fits into the straight groove of the code groove 5, and pin 24 fits into the groove of the code groove 6. Pin 23 fits into the straight groove of the code groove 26, and pin 25 fits into the straight groove of the code groove 27 The code grooves 26, 27 are made on the end surface of the control washer 28, which is movably mounted in the hole The holes of the glass 3 on the other side of the holder 12. Code grooves 29, 30 are made on the second end surface of the control washer 28.

 Behind the control washer 28 (Figs. 1, 4, 5), a ferrule 31 with spring-loaded rods 32, 33 is installed, the composition and construction of which are identical to the composition and construction of the rods 16, 17. The rods 32, 33 are connected to the probes 34, 35 and to the pins 36, 37, 38, 39. The pins 36, 37 interact with the code grooves 29, 30. In the central hole 40 (FIGS. 5, 6) of the holder 31, a key guide 42 is mounted using a pin 41. The holder 31 is fixed in the glass 2 using the tooth 43 (figure 4).

 Next, in the glass 3 (1, 5), a control sleeve 44 is installed with code grooves 45, 46, which interact with the pins 37, 39, respectively. Using the pin 47, the control sleeve 44 is connected to the gear 48. The spring-loaded balls 49 perform the function of a torque coupling that connects the control sleeve 44 to the core 50, in which a figured hole 51 is made, the shape of which corresponds to the shape of the key. By means of the ring gear 52 mounted on the ring gear 31 of the gear 53 and the ring gear 54, the control sleeve 44 is kinematically connected to the control washer 28. The control washer 28 is kinematically connected to the control washer 4 through the ring gear 55, the gear 56 and the ring gear 57 mounted on the ring 12.

 Spring-loaded dogs 58, 59 (FIGS. 1, 7) are installed in a radial hole 60, which is made in a glass 2. Dogs 58, 59 interact with cavities 61, 62 made on the cylindrical surfaces of the control sleeve 44 and the housing 1, forming two ratchet mechanisms, performing the function of a switch of lock operation modes. The cover 63 is fixed in the housing 1 using a snap ring 64.

 Figured hole 11 (figure 1), hole 19, figured hole made in the guide 42, figured hole 51 make up the keyhole of the castle.

 Using screws 65 (Fig. 1, 8), the lock is connected to a locking device, which consists of a cover 67, a housing 68 and a bolt 69. Screws 70 connect the cover 67 and the housing 68. The groove 71 is made in the bolt 69 and with the help of teeth 72, available on its inner side, interacts with the teeth 73 of the gear 48, forming a rack and pinion transmission. Screws 74 secure the lock to door 75. Socket 76, which includes the deadbolt 69, is mounted on door frame 77.

 The key 80 (Fig.9-14) consists of a rod 81 and a head 82 having an opening 83. On the rod there are curly ribs 84 on which a key code is applied in the form of depressions 85. A protrusion 86 is provided on one of the ribs for initial key orientation. In the figured hole 11, a corresponding extension 87 is made (Fig. 2).

 Various uses of the castle suggest several versions of its functioning.

 Door lock for home.

It is assumed that such a lock is locked by turning the key through an angle of 360 ^o (720 ^o ), after which the key is removed from the lock. Unlocking is performed by turning the key in the opposite direction at an angle of 360 ^o (720 ^o ), then the key is removed from the keyhole.

 Locking.

The key 80 (Fig. 9-14) is inserted into the keyhole so that the rib 84 with the protrusion 86 is located opposite the extension 87 (Fig. 2) of the figured hole 11, which corresponds to the vertical position of the head 82. The hole 83 is in the lower position. In this case, the probes 20, 21, 34, 35 slide along the corresponding ribs of the key 80, and the rods 16, 17, 32, 33 make a reciprocating movement (Fig. 1 8). After the key 80 is inserted all the way, it is rotated in the direction of 90 by an angle of 360 ^o . When this gear 48 advances the bolt 69 in the direction of 91. This design of the locking mechanism provides that the complete locking is performed by two full turns of the key, that is, by turning the key 720 ^o . After that, the key is removed from the lock. When locking the glass 2 is rotated in the housing 1, and the dog 59 performs a reciprocating motion.

 Unlocking.

The key 80 (Fig. 9-14) is inserted into the keyhole as well as during unlocking. The probes 20, 21, 34, 35 (Fig. 1 8) interact with the corresponding curly ribs 84 of the key 80. The rods 16, 17, 32, 33 occupy the positions in which their pins 22 25, 36 39 are opposite the connecting sections 8 of the corresponding code grooves 5, 6, 26, 27, 29,30, 45, 46. After the key 80 is inserted all the way, it is turned in direction 92. The dog 59 prevents rotation of the cup 2 in direction 92. Rotation from the core 50 is transmitted through the balls 49 the control sleeve 44, then through the gear 48 the rotation is transmitted to the control washer 28. Then through the gear 52 rotation transmitted to the control washer 4. In this case, the dog 58 makes a reciprocating motion. When rotating the parts 4, 28, 44, the pins 21 25, 36 39 interact with the connecting sections 8 of the code grooves 5, 6, 26, 27, 29, 30, 45, 46, and accordingly move, and the probes 20, 21, 34, 35 removed from the key 80. After the pins 21 25, 36 39 fall into the following straight grooves 7, the rods 16, 17, 32, 33 under the action of the springs 18 will move in the direction of the key 80. After touching the key 80 with the probes 21, 21, 34, 35 pins 21 25, 36 39 will again be located opposite the connecting sections 8 of the code grooves 5, 6, 26, 27, 29, 30, 45, 46. Next, the process continues until the lock is completely unlocked, that is, before turning at an angle of 360 ^o . When turning through an angle of 360 ^o, such a lock is equivalent to twelve locks sequentially unlocked with codes (Fig. 15) a, b, c, d, i, f, g, h, i, j, k, l, and its secrecy can be estimated ≈ r ¹² , where r is the secrecy of one such castle.

 Door lock for car.

It is assumed that the unlocking of such a lock is carried out by turning the key at an angle of 30 ^o (60 ^o , 90 ^o ), after which the key is rotated in the opposite direction and removed from the lock. Locking by turning the key at an angle of 30 ^o (60 ^o , 90 ^o ) in the opposite direction of unlocking, then the key is rotated in the opposite direction to the initial position and is removed from the lock.

Unlocking (30 ^o ).

When unlocking, the lock code a is checked (Fig. 15, 16). The number of code variants r. The rotation of the key (arrow 92) at 30 ^o is fixed by the dog 58 (Fig. 7, 17, 18). When the key is rotated in the direction of the arrow 90 (Figs. 19, 20), the glass 2 rotates at an angle of 30 ^° , and the probes 20, 21, 34, 35 change their angular position. Next, the key is removed from the lock. The next time it is unlocked, the lock code b is checked. When the key is turned back, the glass 2 rotates to the next angle of 30 ^o , and the probes again change their position.

In this embodiment, this lock is equivalent to a cylinder lock with secrecy r, for which the code is constantly changing. Since it is not known which code is currently unlocking the lock, the overall secrecy of the lock is ≈r ¹² (see Table 1).

Locking (30 ^o ).

The key rotates in the direction of the arrow 92. In this case, the glass 2 rotates, and the probes 20, 21, 34, 35 change their angular position. When the key is rotated in the opposite direction, the code changes, and now, when unlocking, the code c will be checked. Thus, if the lock is unlocked and locked by turning the key at the same angle equal to 30 ^o , then this lock is equivalent to a cylinder lock, in which the code changes six times, and its secrecy is ≈r ⁶ .

In that case, if the locking is performed by a rotation of 60 ^o , and unlocking by a rotation of 30 ^o , the security of the lock is ≈r ⁸ (see table 2).

In the case when locking is possible not by turning the key, but in another way, the security of the lock is ≈r ¹² .

 Ignition lock for car.

It is assumed that the car’s power supply is first turned on by turning the key through an angle of 180 ^o (90 ^o ), then the engine is started by turning the key by 30 ^o and turning back by the same angle. The engine can be started repeatedly. Turning off the power by turning the key at an angle of 180 ^o (90 ^o ), that is, its return to its original position.

 Power on.

Turning the key in the direction of the arrow 92 through 180 ^{o is} equivalent to unlocking the lock. In this case, codes a, b, c, d, e, f are checked sequentially (Fig. 15).

 Engine starting.

Turn the key in arrow 92 through an angle of 30 ^o . This step is equivalent to unlocking the lock. This checks the g code. Turn the key in arrow 90 through an angle of 30 ^o . When this glass 2 is rotated at an angle of 30 ^o .

 Two options are possible.

Engine starting. Turn the key in arrow 92 through an angle of 30 ^o . This step is equivalent to unlocking the lock. This checks the code h. Turn the key in arrow 90 through an angle of 30 ^o . When this glass 2 is rotated at an angle of 30 ^o .

Power off Turning the key in the direction of the arrow 90 by 180 ^{o is} equivalent to locking the lock. When this glass 2 is rotated at an angle of 180 ^o .

 The lock ΦZ is shown in FIGS. 21-30.

 The lock 101 (Fig.21) is equipped with a key 102 (Fig.22, 23) and is mounted on a locking device 103.

 The key 102 (Fig. 22-25) consists of a disk 105 with grooves 106, 107, a plate 108, a head 109 and cylinders 110, 111, on the surfaces 112, 113 of which there is a geometric code in the form of the coordinates of the points highlighted in FIG. 24, 25 circles. Magnets 114 are attached to the disk 105; pluses are carriers of a magnetic code.

 The housing 115 (Fig.21, 26-28), on which there are protrusions 116, 117, is connected to the locking device 103 by screws 118. The cup 119 is mounted in the housing 115 for rotation. In the axial channels of the cup 119, spring-loaded rods 120, 121, 122, 123 with pins 124 are located. Permanent magnets 125 (their north poles are blackened in FIGS. 23, 26) are fixed on the rods 120, 121. Windows 126 are made in the cup 119 opposite magnets 125 and closed by inserts of ferromagnetic material. The probes 127 are mounted on the rods 122, 123. Through the pins 124, the rods 120-123 interact with the code grooves 128-131, which are made on the control cylinders 132, 133 (Fig. 26, 27, 29, 30). Each code groove consists of a rectangular groove 134 and a connecting portion 135. In the axial hole of the nozzle 119, a core 136 with a groove 137 is rotatably mounted with a groove 137 (Fig. 21, 26, 27). The core 136 interacts with the disk 138, which connects the control cylinders 132, 133, through a spring-loaded ball 139, which acts as a torque coupling. The spring-loaded rollers 140 are installed in the cover 141 connected to the cup 119 and the spring-loaded rollers 142 installed in the disk 138 comprise two overrunning clutches (Fig. 28). The snap ring 143 secures the lock cover 144 in its housing 115 (FIG. 26). A key 145 connects the disk 138 to the movable part 146 of the locking device 103.

 During the operation of the lock, the key 102 (Fig. 22, 23) is inserted into the keyhole, while the protrusions 116, 117 enter the grooves 106, 107 (Fig. 21, 26) and the plate 108 enters the groove 137 of the core 136. The magnets 114 interact with magnets 125 of the rods 120, 121, and the probes 127 are in contact with the surfaces 112, 113 of the key 103. The pins 124, moving along the straight grooves 134, stop opposite the connecting sections 135 (Fig. 29, 30).

 When the lock is locked, the beaker 119 and the lid 141 rotates together with the key 102 in the direction 151. The rollers 140 do not impede such movement.

When the lock is unlocked, the key 102 is turned in the direction 150. The rollers 140 prevent the cup 119 and the cover 141 from turning. The rotation from the core 136 through the balls 139 is transmitted to the disk 138 and the control cylinders 132, 133 (Fig. 26). The rotation of these control cylinders is possible only if the position of the pins 124 corresponds to the codes printed on the code grooves 128-131. On the other hand, the position of the rods is determined by the coordinates of the surfaces 112, 113, as well as the location of the poles of the magnets 114. In this case, the pins 124 always fall into the connecting sections 135 of the code grooves 128-131. The further operation of the castle is no different from the operation of the ΦR castle described above.
The lock ZR is shown in FIG. 31-39.

 The lock case 201 (Fig. 31) is connected to the locking device 202 by screws 203. A cylinder 204 is installed in the case 201. A piston 206 is installed in the keyhole 205 with the possibility of axial movement, in which a figured hole 207 corresponding to the shape of the key is made. The protrusions 208 are intended for the initial orientation of the key. In the figured channel 209 (Fig. 32, 34) of the cylinder 204, a spring-loaded rod 210 is located. The figured channel 209 is connected to the keyhole 205 by a radial hole. Pins 211 are installed on the stem 210, which cooperate with the code grooves 212 made on the control plate 213. The code groove 212 (Fig. 31) consists of straight grooves 214, bypass 215 and connecting sections 216. Straight grooves 214 are parallel to the axis of movement of the rod 210. In the figured channel 217 (Fig. 32), the rod 218 with a permanent magnet 219 is located. Through the pins 220, the rod 218 interacts with the code grooves 221, which are made on the control plate 222. The code groove 222 consists of rectilinear grooves 225, bypass 226, connecting 227 and dead end 228 sections (Fig. 31). In the shaped channels 229, 230 (Fig. 32), spring-loaded rods 231, 232 are installed. These rods have a structure identical to that of the rod 210. When the lock is engaged, they interact with other parts and move identical to the interactions and movements of the rod 210. The pins 211, 220 interact with shaped grooves 233 (Fig. 35), which are made on the sliders 234. Each of the sliders is installed in a groove made in the cylinder 204. The slider 234 interacts with the cylinder 204 through a telescopic rod (Fig. 36), consisting of spring-loaded half-rods 235, 236. The protrusion 237 formed on the slider 234 interacts with a special groove 238, which is made in the rib 239, fastened to the disk 240 (Fig. 37). The control plates 213, 222, 241, 242 (Figs. 31-34) are combined with a disk 240, which interacts with the piston 206 through a safety device consisting of a spring ball 243 located in the opening of the rib 239. The ball 243 interacts with the hole, which is made in connected to the piston 206 strap 244 (Fig. 34). Disc 240 with a groove 245 is the leading coupling coupling half. A tooth 249 is made on the leading coupling half 246, which is connected via a key 247 to the movable element 248 of the locking device 202. By means of the ribs 239 (Fig. 31, 33,34), the piston 206 interacts with the grooves 250, which are made in the housing 201 and the cylinder 204 The springs 251 provide the interaction of the disk 240 with the driven coupling half 246. The spring ring 252 fixes all the details in the housing 201 of the lock. In the groove 238, thrust surfaces 253, 254 are made.

 The key 255 (Fig. 38, 39) contains a rod 256 with code grooves 257-259, on the bottom surfaces 260-262 of which mechanical codes are applied in the form of the coordinates of the points highlighted in Fig. 38 circles. The magnetic code is made in the form of a set of plastic plates 263, 264 attached to the rod 256. The permanent magnets 265 are oriented along the radius of the rod 256, which is fastened to the head 266. The slots 267 are intended for the initial orientation of the key.

 The castle operates as follows.

 The key 255 (Fig. 38, 39) is fully inserted into the keyhole 205 (Fig. 31). Key codes are controlled when it moves in the keyhole. The initial angular fixation of the key is carried out by the protrusions 208, which enter the slots 267. After contact with the key 255, the piston 206 is mixed with it. This will happen only if the key codes correspond to the lock codes, that is, when the rods 210, 218, 231, 232 interact with the key, the pins 211, 220 will be located opposite the connecting sections of the corresponding groove codes. When moving the key 255 together with the piston 206, the control plates 213, 222, 241, 242 and the ribs 239 move with them. If the key codes correspond to the lock codes, the disk 240 will reach the stop in the driven coupling half 246. In this case, the ribs 239 will come out of grooves 250, and the angular fixation of the piston 206 relative to the housing 201 will disappear. The groove 238 will mesh with the tooth 239, and it will be possible to transmit rotation from the key 255 to the movable element 248 of the locking device 202 in both directions, that is, it becomes possible to open or close the lock.

 When the piston 206 moves, the ribs 239 move with it (Figs. 35, 38). The surfaces 253 of the slots 238 will come into contact with the protrusions 237 of the sliders 234 at the moment when the key 202 is almost completely inserted into the keyhole 206. The slide 234 will begin to move along with other parts. After passing the unstable position corresponding to the minimum length of the telescopic rod, the sliders 234 will be thrown over and take a second stable position. The unstable position of the sliders 234 is close to the end position of the piston when the key 255 is almost completely inserted into the keyhole. At the time of the slide of the sliders 234, the figured grooves 233 (Fig. 35) move the pins 211, 221 towards the bypass sections 215, 226 of the code grooves 212, 221, and they will fall into these grooves.

 In a situation where the key code is not equal to the lock code, the pins 211, 220 will be in straight grooves 214, 225 (or in dead-end grooves 228), and the piston 206 will interfere with the movement of the key 255 (Fig. 31). An attempt to destroy the elements of the lock by force on the piston 206 will trigger a safety device (ball 243 will come out of the hole of the strap 244) and disconnect the piston 206 from the disk 240.

 Further axial movement of the piston 206 does not make sense, since it cannot lead to mechanical coupling of the key 255 with the locking device 202.

 The pins 211, 220 are located in the bypass sections 215, 226 and do not interfere with the movement of the control plates 213, 222, 241, 242 when removing the key 255 from the lock. When the piston 206 approaches its initial position, the surface 254 (Fig. 37) will come into contact with the protrusions 237 of the sliders 234. The sliders will be moved to their initial stable position, and the figured groove 233 will begin to block the possible movement of the pins 211, 220 to the bypass sections 215, 226 The return stroke occurs under the action of springs 251.

Bibliography
1. Krainev A. F. Dictionary dictionary of mechanisms. M. Engineering, 1987, p. 560.

 2. Auth. testimonial. USSR 1134687 E 05 B 35/04.

Claims (1)

 A lock having a key and a lock mechanism comprising a housing and movably mounted in the housing with the possibility of interacting with the key working part of the key, characterized in that the key code is applied to the working part of the key in the form of coordinates of points on the code surface and / or coordinates of the location of the poles of the permanent magnets in the case of the lock mechanism are located a switch of the operating modes of the lock mechanism, movably mounted and kinematically connected to each other control shells with code grooves carrying the lock code, consisting of and straight grooves and connecting sections, as well as spring-loaded rods that interact with the code grooves through the pins fixed in them and located in the straight groove of the code grooves and are installed with the possibility of rectilinear movement and interaction with the working part of the key using the probes or permanent magnets attached to them, wherein the core is kinematically connected through the control shell with a movable element connecting the lock mechanism to the actuator, and the key code is equivalent It is identical to the lock code, which is equal to the coordinates of the intersection of the axial lines of straight grooves and the beginnings of the axial lines of the connecting sections.

Images