RU2151252C1 - Lock - Google Patents

Abstract

FIELD: locks. SUBSTANCE: lock has body, turning axle and set of spring-loaded pushers and pins, and key. Turning axle is of two-step structure. Its first step is in the form of drum with longitudinal slots for key passing into longitudinal channels accommodating in pairs of pushers and pins. The second step is of small diameter and protrudes beyond body outline. Body has hollow for drum of turning axle with central hole for the second step of turning axle, and also longitudinal channels coaxial to drum longitudinal channels for each pair of pushers and pins. Springs are installed in body longitudinal channels. Pins with one part of their length are installed in body longitudinal channels, and with their other part of length in drum longitudinal channels. Lock has supporting member connected with the second step of turning axle beyond limits of body whose longitudinal channels are through. Springs are installed in longitudinal channels of body for engagement with supporting member by their ends. EFFECT: higher operating reliability. 3 cl, 19 dwg

Description

 The invention relates to devices for locking residential and office space, storage, warehouses, etc. The lock can also be used to lock doors, engine hoods and car trunks and for car ignition locks.

 A lock is known, comprising a housing with central and blind radial holes, a rotary drum installed in the central hole of the housing with radial holes, coaxial radial holes of the housing, spring-loaded pins and pushers located respectively in the radial holes of the housing and the rotary drum, equipped with a handle from the side of the well (see ., for example, ed. St. N 1263788, E 05 B 27/00, 1985).

 However, a disadvantage of the known lock is the possibility of opening it with master keys, since there are tolerances in the manufacture of the lock, as a result of which a step can occur between the movable and fixed parts, which when opened with a master key, the pusher abuts and the movable part rotates relatively motionless, the lock opens.

 Also known is the lock closest in technical essence to the invention, comprising a housing with an adjustable unit housed therein and spring-loaded sections of the main unit.

 In the adjustable unit and sections of the main unit, the cylinders are rotatably mounted. Aligned to the cylinders are a leash and a disc. The blocks and cylinders are equipped with spring-loaded locking pins and pushers, respectively. Moreover, the latter at the site of their interaction with the end surfaces are made with hemispherical chamfers (see, for example, ed. St. N 1659615, E 05 B 27/04), 1987.

 However, the known lock does not provide reliable enough closure, i.e., it can be opened with a master key. This is due to the fact that the pins and pushers in the place of their interaction are made in the form of a hemisphere, and when combining the movable and fixed parts of the lock, they move along a cylindrical surface.

 The implementation of hemispherical and cylindrical surfaces is a technologically laborious process, which leads to insufficient manufacturing accuracy. As a result of this, a step arises between the block and the cylinder. The master key rests against this ledge and the lock opens. To prevent this drawback, the number of pushers is increased in such locks. However, this is not effective enough. In addition, to increase the accuracy of manufacturing hemispheres of the pushers, which are relatively small in size and moving them not in the plane, but on a cylindrical surface is almost impossible. The problem arose: with smaller dimensions of the lock, increase the size of the pushers and ensure that the movable part rotates relatively motionless (opening, closing) in the plane, which will significantly increase the manufacturability of the castle.

 A lock is known, comprising a housing in which a rotary drum is located with pushers located in it, interacting with spring-loaded locking pins installed in the housing, and a push key, while the pushers are made in steps, with large bases facing the locking pins (see ed. USSR N 520794, class E 05 B 35/04, 1977). This famous castle has the above disadvantages, although the composition of the design features is closer to the proposed castle.

 A known lock containing a rotary axis with a drum located in the housing and a set of spring-loaded pins and pushers installed in longitudinal cells of the drum, the central hole being made for a rotary axis in the housing, which passes into a cylindrical cavity coaxial with it for a rotary axis drum, as well as an annular a cavity concentric with the central hole in which the springs are located and pins made part of their length, made with shanks on the side of the springs, and in this part of the annular cavity of the housing holes for the shanks of the pins are lined, and the length of the pins with shanks is equal to the length of the annular cavity of the casing (see ed. St. N 722 for the utility model "Krotova Castle", cl. E 05 B 27/00, 1993).

 This known technical solution is the closest in technical essence and the achieved result.

 However, this castle also has drawbacks in design and in the reliability of preventing the possibility of actuating the castle by foreign objects.

 Design flaws are primarily due to the implementation of pins with shanks and holes for them in this part of the housing.

 In this castle, the possibility of bringing it into action with the help of foreign objects is not ruled out. If by any extraneous means it is possible to drown the pushers and pins all the way to the bottom of the case and then fix the springs and pins in the recessed position, for example using quick-hardening fluid, it will be possible to pull some pushers back to the front end of the lock case. After that, it will be possible to rotate the drum, since the pushers and pins could be disconnected and not a single pin or pusher will be placed in the plane of interaction of the end of the drum and the end of the body forming the annular cavity.

 In addition, the ends of the last turns of the springs also do not contribute to improving the reliability of the lock.

 The end of the last coil of the spring from the side of the bottom of the body, possessing sufficient hardness, not only knocks out small holes and scratches, for which, in subsequent work, the end of the last coil engages and stops.

 But a more serious drawback in the work of the ends of the last turns of the springs is the situation that occurs in the area opposite to the bottom of the housing, namely at the ends of the pins. The ends of the pins are made with chamfers. Due to these chamfers, an annular gap is formed between the surface of these chamfers and the surface of the longitudinal cells in the housing in which these pins are placed. If the end of the last coil of the spring falls into this gap, then three elements are jammed: the housing, the pin and the spring, and through them the entire locking mechanism is locked.

 It is often possible to get the lock mechanism out of this state only as a result of complete disassembly or destruction.

 Between the ends of the body part, forming an annular cavity, and the drum, a gap is inevitable, which is determined not by design parameters, but by possible manufacturing accuracy. To reduce the specified gap is possible by increasing the accuracy of manufacturing parts, but increasing the accuracy of manufacturing leads to a sharp rise in price of the castle.

 If there is a gap between the said ends, jamming of the pins and pushers is possible.

 The purpose of the invention is to increase reliability.

 To achieve increased reliability in the operation of the locking mechanism, it is proposed to abandon the case with a monolithic bottom and replace this element with another - the so-called moving bottom. The movable bottom is connected to the rotary axis of the drum and transfers axial forces from the springs not to the bottom of the housing, but to the drum, thereby compensating for the gap mentioned above.

 To eliminate the harmful effects of the ends of the last turns of the springs, it is proposed to change their configuration.

 As a result of these changes, it is necessary to abandon the shanks of the pins - they are not needed.

 This goal was achieved due to the fact that the lock contains a housing, a rotary axis and a set of spring-loaded pushers and pins, as well as a key, while the rotary axis is made of two stages, the first stage is a drum with longitudinal key cuts that turn into longitudinal channels, in which pushers and pins are placed in pairs, the second step of a smaller diameter extends beyond the housing, which is made with a cavity under the drum of the rotary axis, with a central hole for the second stage of the rotary axis, as well as with longitudinal channels coaxial with the longitudinal channels of the drum for each pair of pushers and pins, with the springs installed in the longitudinal channels of the housing, and the pins with one part of their length installed in the longitudinal channels of the housing, the other part of their length in the longitudinal channels of the drum, equipped with a support element connected to the second stage the rotary axis outside the housing, the longitudinal channels of which are made through, the springs are installed in the longitudinal channels of the housing with the possibility of interaction with their ends with the supporting element.

 The lock is equipped with a separator located between the support element and the springs, and is partially recessed in the housing.

 The longitudinal channels of the drum and the housing are not parallel to the Central hole of the housing.

The invention is illustrated by drawings, where:
in FIG. 1 shows a castle in longitudinal section;
in FIG. 2 shows a lock key;
in FIG. 3 shows an embodiment of a lock;
in FIG. 4 shows a section AA of FIG. 1;
in FIG. 5 and 6 are sections A-A of FIG. 1, embodiments;
in FIG. 7 shows section BB of FIG. 1;
in FIG. 8, 9, 10, 11 and 12 depict sections BB of FIG. 1, embodiments;
in FIG. 13 shows a cross-section BB of FIG. 2;
in FIG. 14, 15, 16 and 17 depict sections BB of FIG. 2, embodiments;
in FIG. 18 shows the lock in working position;
in FIG. 19 shows an embodiment of a lock.

 The lock contains a housing 1, a rotary axis 2, a set of pins 3 and pushers 4, as well as springs 5.

 The casing is made in the form of a thin-walled cylinder with a front end wall 6. In the front end wall 6 of the casing are made slots 7 under the key 8, for example, four located at right angles to each other. A different number of slots on the front end wall of the housing and a corresponding number of longitudinal lobes 9 on the key 8 are possible.

 Inside the housing 1, a cavity 10 is formed in the area adjacent to the front wall 6, passing into the axial channel 11, as well as a number of longitudinal channels 12 parallel to the axial channel 11.

 The rotary axis 2 consists of two sections: cylindrical 13 and drum 14.

 The cylindrical section 13 of the rotary axis 2 is located in the axial channel 11 of the housing, exits the housing and is connected outside the housing to the supporting element 15.

 The drum 14 is located in the cylindrical cavity 10 of the housing and is made with a number of longitudinal slots 16, equal to the number of longitudinal channels 12 in the housing and equal to the number of slots 7 on the front wall 6 of the housing and the number of longitudinal lobes 9 of the key 8. Number of slots on the drum, channels in the housing and accordingly, the number of longitudinal petals on the key can be two or more. The relative position of the slots on the drum, the channels in the housing and the longitudinal lobes on the key can also be different both with respect to the longitudinal axis of the drum and the key, and the angular location relative to each other (angles a1, a2 ... etc). It is possible to make petals of various thicknesses (b1 ... bn), as well as with protrusions (see Figs. 13, 14, 15, 16 and 17). The longitudinal slots 16 of the drum 14 in the area of the outer periphery pass into the longitudinal channels 17. The longitudinal channels 17 of the drum 14 can be made open to the periphery of the drum: rectangular (see Fig. 4) or oval (see Fig. 5) cross-section. However, these longitudinal channels can be made closed to the periphery of the drum (see Fig.6).

 In the longitudinal channels 17 of the drum 14 and in the longitudinal channels 12 of the housing 1, pins 3, pushers 4 and springs 5 are placed in pairs.

 Pushers and pins have a cylindrical shape, however, they can also have a different shape, for example, cylindrical with longitudinal flats, multifaceted (see Fig. 7.12).

 The ends of the pushers facing the front end wall of the housing are straight. The ends of the pushers and pins interacting with each other are also straight, but of a smaller diameter due to the formation of conical surfaces 18 at these ends.

 The pins 3 part of their length are located in the longitudinal channels 12 of the housing, and the other part of their length, facing their conical surfaces, are located in the longitudinal channels 17 of the drum 14.

 Pushers 4 are completely located in the longitudinal channels 17 of the drum 14.

 The longitudinal channels 12 in the housing 1, in which the pins 3 and the springs 5 are placed, are made through, that is, the ends of the springs 5 from the side of the support element 15 freely extend beyond the end of the housing 1.

 The longitudinal channels 12 in the housing 1 are made in the monolith of the housing with various cross-sections: round, rectangular, square (see Fig. 7.8).

 Based on technological capabilities, the implementation of the longitudinal channels 12 in the monolith of the housing 1 can be replaced by the execution of these channels in a separate element 19, such as a sleeve, which is installed in the housing 1 and covers a cylindrical section 13 of the rotary axis 2. Longitudinal channels 12 made in a separate technological element 19 , such as a sleeve, have an open shape of various configurations (see Fig. 9.10). Instead of a sleeve with longitudinal channels, you can make a cylindrical sleeve 20 and a separate element for holding the pins 3 from displacement in the form of plates 21 (see Fig. 11).

 You can avoid the manufacture of individual retaining elements - plates 21 due to the execution of the sleeve 22 with a faceted outer surface, and the pins 23 are also faceted, which will ensure their retention from displacement.

 The supporting element 15 is connected to the cylindrical section 13 of the rotary axis and serves as a stop for the springs 5. The springs 5 interact with the end face of the pins 3 with one end and interact with the supporting element 15 with their second end. However, the stop element 15 can act as a transmitting element, that is, it will transmit rotational motion from the rotary axis to the actuator.

 However, it should be noted that these functions can be separated, that is, one element will serve only as an emphasis for springs, and another element should be used to transmit movement to the actuator.

 To exclude the possible introduction of the ends of the last turns of the spring into the surface of the support element 15 between the springs and the stop element, an intermediate separator 24 can be placed (see Fig. 3), which is partially recessed in the housing.

 The ends of the last turns of the spring are allocated from the point of interaction with the ends of the pins and the separator 24 or of the supporting element 15. The ends of the last turns can be taken radially into the last turn, bent along the spring inside it or in some other configuration and arrangement, but excluding force interaction with a separator or thrust element, and most importantly, preventing the end of the last coil of the spring from entering the zone between the chamfer at the end of the pins 3 and the surface of the longitudinal channels 12 of the housing 1.

 On the longitudinal petals 9 of the key 8 are made radial protrusions 25 for radial interaction with the ends of the pushers 4.

 The castle is as follows.

 The key of the lock 8 is inserted into the longitudinal slots 16 of the drum when combining these slots with the longitudinal petals 9 of the key 8. The radial protrusions 25 of the petals of the key, overcoming the resistance of the springs 5, move the pushers and pins deep into the body until the end face 26 of the key 8 in the bottom 27 of the longitudinal slots drum. At this moment, the interacting ends of the pushers 4 and pins 3 are aligned with the GG plane.

 The plane GG passes through the end between the drum 14 and the cylindrical section 13 of the rotary axis 2 (see Fig. 18).

 The rotary axis 2 using the key 8 at this moment can rotate, driving the actuator.

If at least one of the pins is advanced deeper than indicated above, then the movement of the pivot axis will be impossible. Such a case may
occur when you try to activate the lock with the help of a non-standard key or a foreign object.

 When removing the key from the slots of the drum, the pushers and pins return to their original position. In the initial position, the pushers abut against the front front wall of the housing, and the pins - in the pushers. The GG plane is overlapped by a set of pins.

 This lock will ensure the reliable operation of all its elements with increased secrecy.

 Improving the reliability of the lock is provided by supplying the lock with a support element, which serves as a support for the springs. If in the known designs of the locks the springs rested against the dead bottom of each longitudinal channel in the housing, then in this lock, instead of the bottom made in one piece with the housing, there is a support element on which the ends of the springs rest, but outside the housing, the springs freely leave the housing . The supporting element has a rigid connection with the rotary axis of the lock. Thus, a completely different scheme of transmission of the force interaction of the castle parts is formed.

 In the known lock, the springs transmitted axial force interaction between the bottom of the housing and the pins to the pushers, and the pushers, in turn, to the front wall of the housing, dragging the rotary axis drum behind it through friction forces. As a result of such force interaction along the aforementioned GG plane, an axial clearance was deliberately formed, since the springs sought to move the drum and the inner end of the housing in the GG plane from each other. The situation was aggravated in case of unfavorable distribution of tolerance fields in the manufacture of parts.

 In this castle, the power scheme for the interaction of these parts is completely different. The springs, resting not on the housing, but on the pressure element, provide constant pressing of the drum to the inner end of the housing in the GG plane, therefore, there will be no gap on this plane between these elements.

 The absence of the mentioned gap eliminates the possibility of skewing the drum relative to the housing and jamming of the pins and pushers.

 This difference of this lock is the most significant for achieving the goal - improving reliability.

 The implementation of the springs with the bent ends of the last turns excludes the possibility of these ends falling into the zone between the chamfer at the end of the pin and the surface of the longitudinal channels in the housing and in the drum.

Claims (3)

 1. A lock containing a housing, a rotary axis and a set of spring-loaded pushers and pins, as well as a key, while the rotary axis is made of two stages, the first step is a drum with keywise longitudinal slots turning into longitudinal channels in which pushers and pins are placed in pairs, the second stage of a smaller diameter extends beyond the housing, which is made with a cavity under the drum of the rotary axis, with a central hole for the second stage of the rotary axis, as well as longitudinal channels coaxial with the longitudinal channels of the drum for each pair of pushers and pins, with the springs installed in the longitudinal channels of the housing, and the pins with one part of their length installed in the longitudinal channels of the housing, the other part of their length in the longitudinal channels of the drum, characterized in that it is equipped with a support element connected to the second stage of the rotary axis outside the housing, the longitudinal channels of which are made through, the springs are installed in the longitudinal channels of the housing with the possibility of interaction with their ends with the supporting element.  2. The lock according to claim 1, characterized in that it is equipped with a separator located between the support element and the springs and partially recessed into the housing.  3. The lock according to claims 1 and 2, characterized in that the longitudinal channels of the drum and the housing are not parallel to the central hole of the housing.

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