RU2119032C1 - Cylindrical secrecy mechanism of lock for tubular key - Google Patents

Abstract

FIELD: locking devices. SUBSTANCE: cylindrical mechanism of lock has body and turnable bush which is located inside body at clearance fit. Rigidly connected with bush is central core which is kinematically linked with latch of lock. Created between bush and core is annular slot to receive key. Made in body and turnable bush are coaxial radial holes which are filled with two sets of spring-biased members. First set of spring-biased members ensures locking of turnable bush with any key being inserted which is made not according to given code. Second set of spring-biased members ensures locking of turnable bush when key is removed. In this case, radial holes made in body and turnable bush filled with first set of spring-biased members are coaxial with holes in key made according to code. Turning bush and key have members which ensure displacement of lock latch as key is being rotated. Also members are provided which fix rotatable bush in axial direction relative to body. Central core is stepped. Extreme step located in front part of mechanism is larger in diameter than adjacent step which is in contact with cylindrical bosses included in sets of spring-biased members. Each set is made up of two cylindrical bosses. One of them is spring-biased, and other is supporting and is in contact with core. Made in end of supporting bosses facing towards core is cone. Angle of cone incline is not larger than incline angle of tapered surface made in key hole. Key is seated in turnable bush with clearance fit. Aforesaid embodiment of lock gives higher protection against burglary. EFFECT: higher efficiency. 4 cl, 5 dwg

Description

 The invention relates to locking devices and can be used in locks of various designs.

 Known cylinder lock mechanism for a tubular wrench, manufactured by Zavod Izmeron plant, the design of which is made in accordance with RF patent N 2042024 Bull. N 23, comprising a housing rolled into a casing, a sleeve with which the central core is rigidly connected, which in turn is kinematically connected with the lock bolt, and a circular slot for a tubular key is formed between the rotary sleeve and the central core, and elements are made for the rotary sleeve and key ensuring the movement of the bolt from the rotation of the key. These elements are the pin, pressed into the rotary sleeve, and the slot in the key, which includes this pin. This interacting pair of parts operates under high specific loads and wears out quickly. Coaxial radial openings filled with two sets of spring-loaded elements are made in the housing and in the sleeve. In these sets, steel tempered balls are used as supporting elements. In the case of using balls as supporting elements, the wall thickness of the tubular wrench cannot be less than half the diameter of the ball. Therefore, the circular slit is large, which facilitates the use of master keys.

 As an element fixing the relative position of the housing and the rotary sleeve in the axial direction, a casing is used. This decision turned out to be extremely unsuccessful: the design is non-separable, and it is difficult to check the operability of the mechanism before installing the casing. After installing the mechanism in the casing as a result of a possible axial shift of the rotary sleeve relative to the housing, the operability of the mechanism may be impaired, and it is difficult to fix anything, since the design is not separable. When the rotary sleeve rotates, the spring-loaded elements (balls or tsugaliki) exert a force on the edge of the holes of the rotary sleeve, crush and break it off. Wear products fill the landing gap between the rotary sleeve and the housing, which leads to jamming.

 The aim of this invention is to eliminate the noted drawbacks and create a design that provides greater manufacturability, reliability and durability, as well as creating additional difficulties for opening the lock with master keys.

 The goal for a cylinder lock secrecy mechanism for a tubular key, consisting of a rotary sleeve housing located in the landing housing with a gap, to which a central stepped core is rigidly connected kinematically connected to the lock bolt, and a circular key gap is formed between the sleeve and the core, and in the housing and in the rotary sleeve, coaxial radial holes are made, filled with two sets of spring-loaded elements - the first one, which ensures locking of the rotary sleeve for any insertion the key, made not according to this code, and the second, which ensures the locking of the rotary sleeve with the key removed, while the radial holes made in the housing and in the rotary sleeve, filled with the first set of spring elements, are aligned with the holes in the key made in accordance with the code moreover, the rotary sleeve and the key are made elements that ensure the movement of the bolt of the lock from the rotation of the key, as well as the elements that fix the rotary sleeve relative to the housing in the axial direction, is achieved by the fact that the price the swivel core is made stepped, and the extreme step located in the front of the mechanism is made larger in diameter than the adjacent step, which is contacted by cylindrical coils included in sets of spring-loaded elements, each set consisting of two cylindrical coils - spring-loaded and supporting, contacting with a core; at the end of the support tsugaliks facing the core, a cone is made, the angle of inclination of which is not greater than the angle of inclination of the conical surface made in the key holes; the key is placed in the rotary sleeve for landing with a gap.

 The proposed device has a reduced circular slot for the key, which is made smaller than half the diameter of the Tsugaliks, which made it possible to increase their size and stroke size, and therefore, allowed to increase the tolerances on the length of the Tsugaliks, as well as create additional difficulties for opening the lock with master keys.

 On the outer surface of the rotary sleeve, a circular groove is made in which the pin is placed, and a hole is made in the housing for this pin in which it is placed to fit. This ensures fixation of the relative position of the housing and the rotary sleeve in the axial direction, which is maintained after the final assembly of the mechanism.

 The pin placed in the circular groove is spring loaded. A conical surface is made at its end located in the circular groove, and a hole with a chamfer is made in the groove of the rotary sleeve, and both conical surfaces are in contact only in the initial position of the rotary sleeve, in which the key can be inserted and removed from the privacy mechanism. The hole for this pin in the housing is made to fit with a gap.

 Chamfers are made on those parts of the outer edges of the holes located on the rotary sleeve that, when it rotates, come into contact with the surface located at the ends of the coils, and the shape at the surface of the spring-loaded coils made at the end facing the center is conical, and the angle of inclination this cone is made smaller than the angle of inclination of the chamfers made in the holes of the rotary sleeve.

 This eliminates the edge contact of the hole with the Tsugalik. Therefore, rotation is facilitated and edge wear is reduced.

 The invention is illustrated by drawings.

 In FIG. 1 is a sectional view showing a cylinder mechanism. In FIG. 2 shows the position of the Tsugaliks with the key inserted. In FIG. Figure 3 shows the position of the tsugaliks with the key removed. In FIG. 4 shows a cylinder mechanism in section along BB in FIG. 2. In FIG. 5 shows a cylinder mechanism in section along BB in FIG. 1.

 The cylinder locking mechanism of the lock consists of a housing 1 placed in a casing 2, and of a rotary sleeve 3 kinematically connected with the lock bolt of the lock. A central core 4 is rigidly connected to the rotary sleeve 3. A circular slot for a tubular key 5 is formed between the sleeve 3 and the central core 4. The tubular key 5 has crackers 6 (FIGS. 1 and 5), which enter a groove 7 located on the front end of the sleeve 3. A strap 9 is attached to the rear end of the central core with a cotter pin 8, kinematically connecting the secrecy mechanism with bolt lock. Coaxial radial holes are made in the housing 1 and in the rotary sleeve 3, part of which are key and are aligned with holes 10 (FIG. 2) made in key 5. In the key holes are Tsugaliki 11 and 12 (FIGS. 2 and 4), spring-loaded spring 13. In the remaining holes are located spring-loaded spring 13 Tsugaliki 14 and 15. At the ends of the support Tsugaliki 11i14 a conical surface is made, and in the holes 10 of the key chamfers are made, the angle of inclination of which is not less than the angle of inclination of the conical surface of the cone of Tsugaliki 11 and 14. Or they can be conic holes with the same angle of inclination of the conical surface. A cone is made at the ends of the spring-loaded Tsugaliks 12 and 15, and on those parts of the outer edges of the holes located on the rotary sleeve 3, which, when it rotates, come into contact with the surface located at the ends of the Tsugaliks, chamfers 16 are made (Fig. 4), the angle of which more than the angle of inclination of the conical surface located at the ends of the coils 12 and 15. On the outer surface of the rotary sleeve 3 there is made a circular groove 17 (Figs. 1 and 5), into which a pin 18 is placed with clearance with a gap, and in this case 1 under this the pin is made a hole in to he was placed on landing with a gap. Pin 18 is spring loaded.

 A hole 19 with a chamfer is made in the rotary sleeve 3, and a conical surface is made on the end of the pin 18 located in the circular groove 17, and both conical surfaces are in contact only in the initial position of the rotary sleeve, in which the key can be inserted and removed from the privacy mechanism .

 At the front end of the central core 4 there is a girdle 20 (FIG. 1), which reduces the circular gap between the rotary sleeve 3 and the central core 4. This makes it difficult to use the master keys to open the lock.

 If a key 5 is inserted into the cylinder mechanism, in which the holes 10 are made in accordance with the mechanism code (FIGS. 2 and 4), then the coils 11 through key holes 10 are in contact with the central core 4, and the coils 14 are in contact with the key 5 . When the key 5 is rotated, the locking tugs 11 and 15 do not interfere with the rotation of the rotary sleeve 3. If you insert a key that does not correspond to the mechanism code, at least one of the tugs 11 will not be in the hole 10 and will prevent the sleeve 3 from turning relative to the housing 1. It will not be possible to turn vtu lku 3 and in the event that the button 14 is in the hole of such a key. Then Tsugalik 15 will prevent the rotation of the sleeve 3.

 When the key is removed (Fig. 3), the swivel 3 prevents the sleeve 3 from turning. When the key 5 is inserted into the circular slot, the conical surfaces of the support swivels 11 and 14 will come into contact with the chamfer 20 made on the end part of the key, and as a result of the interaction of the swivels 11 and 14 move away, compressing the springs 13, and miss the tubular part of the key 5. If the code of the inserted key matches the code of the mechanism, then the coils 11 will be in the holes of the key, and the coils 14 will be in contact with the surface of the key. The locking tugs 11 and 15 in this case will not impede the rotation of the sleeve 3. When the key 5 is rotated, the crackers 6 located in the groove 7 of the sleeve 3 will transmit this rotation to the sleeve 3, the core 4 and the bar 9 kinematically connected to the lock bolt. The spring-loaded tsugaliki 12 and 15 as a result of the interaction of their conical surfaces with the chamfers 16 move away, compressing the springs 13, and will not interfere with the rotation of the sleeve 3. In the initial position, the sleeve 3 is fixed by a spring pin 18.

 When the key is removed, the support tugs 11 and 14 located in the holes of the key 5 or falling there enter their conical surfaces into interaction with the chamfers made in the holes 10 and move away, allowing the key 5 to be removed.

Claims (5)

 1. A cylinder lock security mechanism for a tubular key, consisting of a housing and a rotary sleeve. located in the landing housing with a gap, with which the central core is rigidly connected kinematically to the lock bolt, and a circular key slot is formed between the sleeve and the core, and coaxial radial holes are made in the housing and in the rotary sleeve, filled with two sets of spring-loaded elements - the first one that provides locking of the rotary sleeve with any key inserted, made not according to this code, and the second one that provides locking of the rotary sleeve with the key removed, while radial from the holes made in the housing and in the rotary sleeve, filled with the first set of spring-loaded elements, are aligned with the holes in the key, made in accordance with the code, moreover, the elements of the rotary sleeve and the key are made to ensure that the bolt of the lock moves from the rotation of the key, as well as the element fixing the rotary sleeve relative to the housing in the axial direction, characterized in that the central core is made stepped, and the extreme step located in front of the mechanism is made larger in diameter, th m is an adjacent step, with which cylindrical tugs in contact with the sets of spring-loaded elements come into contact, each set consisting of two cylindrical tugs - spring loaded and supporting, in contact with the core, and a cone is made at the end of the supporting tugs facing the core, the tilt angle of which is not greater than the angle of inclination of the conical surface made in the key hole, and the key is placed in the rotary sleeve for landing with a gap.  2. The mechanism according to claim 1, characterized in that the end groove is made on the rotary sleeve, and on the key crackers included in this groove.  3. The mechanism according to claim 1, characterized in that on the outer surface of the rotary sleeve there is a circular groove in which a pin is placed with a clearance to fit, and a hole is made in the housing for this pin in which it is placed to fit.  4. The mechanism according to claims 1 and 3, characterized in that the pin is spring-loaded, a conical surface is made at its end located in the circular groove, and chamfered holes are made in the groove of the rotary sleeve, and both conical surfaces are in contact only with the original the position of the rotary sleeve, in which only the key can be input and output, and the hole for this pin in the housing is made by landing with a gap.  5. The mechanism according to claim 1, characterized in that on those parts of the outer edges of the holes located on the rotary sleeve, which during its rotation come in contact with the surface located at the ends of the spring-loaded coils, chamfers are made, and the surface shape of the spring-loaded coils made on the end facing the center is conical, and the angle of inclination of this body is made smaller than the angle of inclination of the chamfers made in the holes of the rotary sleeve.

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