RU2100551C1 - Lock - Google Patents

Abstract

FIELD: guarding equipment, in particular, locking devices which may be used in encoder systems. SUBSTANCE: lock has body, cross bar, cross bar control member, rotation member in control circuit, retainer and retainer control member. Cross bar control member has shaft, whose one end is positioned outside the door and other end may directly or through kinematic circuit cooperate with rotation member. Shaft or kinematic circuit member and rotation member are positioned so as to define friction pair between them. Retainer and retainer control member are attached to door inner surface for cooperation of retainer with control circuit member or cross bar and fixing cross bar in closed position of lock. Construction of lock eliminates possibility of selecting key or breakage of key well. EFFECT: increased efficiency, enhanced reliability in blocking and wider operational capabilities. 4 cl, 4 dwg

Description

 The invention relates to security equipment, in particular to locking devices, and can be used in code-forming systems.

 The invention is known according to the patent of Russia N 2019656, class. E 05 17/20, 1994, taken as a prototype. It contains a housing, a bolt, a bolt control element, a rotation element in the control circuit, a latch and a latch control means. However, the lock presented in the prototype has an unnecessarily complicated fixation of the crossbar. In addition, the bolt control element in the form of, for example, a cylinder mechanism is easily damaged and needs a key as a code carrier, while the degree of secrecy of known electronic-code devices makes it possible to abandon such mechanisms.

 The technical result of the invention is to simplify the design and increase the reliability of locking the lock, which is achieved by using a shaft bolt as a control element, one end of which is located outside the door, and the other directly or through a kinematic chain has the ability to interact with the rotation element. The shaft or the kinematic chain element and the rotation element are installed with the formation of a friction pair between them. The latch and the control means of the latch are located on the inner surface of the door with the possibility of interaction of the latch with an element of the control circuit or the bolt and ensure the fixation of the bolt in the closed position of the lock. The clamp control means, for example an electromagnet, is connected to the power source by the inputs, and its core is connected to the clamp. To reduce the required power of the electromagnet, the latch is made in the form of a rod and installed with the possibility of reciprocating movement in the vertical direction. The latch is connected to the core of the electromagnet through a link of non-magnetic material to prevent magnetic sticking of the latch. The fixing process is ensured by the weight of the retainer and its associated elements.

 In FIG. 1 shows a castle; in FIG. 2, section AA in FIG. one; in FIG. 3, section BB of the embodiment of the lock in FIG. one; in FIG. 4 version of the castle.

 The lock comprises a housing 1 mounted on a door 2, a crossbar 3, a shaft 4, a control circuit with a rack pair 5 and 6. A rotation element in the form of a gear 6 is mounted to rotate on the shaft 4 and by means of an elastic element 7, and the nut 8 is spring-loaded relative to shaft 4 with the formation between them of a friction connection. The latch 9 is mounted vertically and connected to the core 10 of the control electromagnet 11 by a link 12 made of non-magnetic material and which is at the same time a limiter of the latch 9. The electromagnet 11 inputs 13 is connected to a power source. The wheel 6 is provided with grooves 14 and 15 for interaction with the latch 9. The shaft 4 has a groove 16, and the deadbolt 3 control handle 17.

 In FIG. 3 shows a variant of the lock with a shaft 18 and a kinematic chain 19 and 20. The kinematic chain element of the gear wheel 20 and the wheel 21 are rotatably mounted on the axis 22 and spring-loaded relative to each other, as in the embodiment of FIG. 2.

 In FIG. 4 shows an embodiment of a lock with a latch 23 mounted to interact with a bolt 24. Otherwise, the lock is similar to the embodiment in FIG. one.

 The castle operates as follows.

 In the closed position of the lock, the latch 9 by means of the groove 14 blocks the rotation of the wheel 6 and the movement of the bolt 3 connected with it while maintaining the possibility of idling for the shaft 4. When applying to the inputs 13 of the electromagnet 11 a power supply, for example, by means of an electronic-coding device, the latch 9 moves up and releases the wheel 6. By means of the groove 16, the shaft 4 can be rotated with an ordinary coin. The rotation of the shaft 4 due to frictional forces is transmitted to the gear wheel 6, which moves the crossbar 3. The groove 15 serves to fix the wheel 6 and the associated crossbar 3 in the open position of the lock. The maximum shear force that can be applied to the bolt 3 from the side of the wheel 6 is due to the pressure of the nut 8 on the elastic element 7 and is set when adjusting the lock. From the inside, the bolt 3 can be controlled using the handle 17. In this case, the lock is operable even when the shaft 4 is jammed or deliberately held outside, since the gear 6 can be rotated by the rail 5 of the bolt 3.

 In the embodiment of FIG. 3, when the wheel 21 is locked, the rotation of the shaft 18 leads to the sliding of the wheel 20 along the wheel 21. When the wheel 21 is unlocked, the rotation of the shaft 18 through the wheel 20 is transmitted via friction coupling to the wheel 21, which moves the crossbar 3. Otherwise, the lock works in the same way as in FIG. 2.

 In the embodiment of FIG. 4, the latch 23 interacts directly with the crossbar 24, fixing it in the closed position of the lock. The groove 25 serves to fix the bolt 24 in the open position of the lock. Otherwise, the lock operates similarly to the embodiment of FIG. 1. The design of the lock allows you to equip it with an effective system (not shown) emergency transfer bolt to the open position without breaking the door. It is also possible to implement a multi-lever lock of a safe type with a hinged connection of the rotation element and the control rods of the rods. The crossbar control shaft can be integral, composite, contain kinematic connections, be flexible or otherwise.

 Currently, the author has made and tested a prototype of the claimed castle.

Claims (4)

 1. The lock containing located in the housing with the possibility of reciprocating movement of the bolt, the bolt control element, the rotation element in the control circuit, the latch and the latch control means, characterized in that the bolt control element is a shaft, one end of which is located outside the door, and the other directly or through the kinematic chain has the ability to interact with the rotation element, and the shaft or element of the kinematic chain and the rotation element are installed with the formation between it a friction pair, and latch and lock control means are arranged on the inner surface of the door for engagement with the latch element of the control circuit and providing or bolt fixing bolt in the closed position of the lock.  2. The lock according to claim 1, characterized in that the latch is made in the form of a rod mounted with the possibility of reciprocating movement in the vertical direction associated with the latch control means.  3. The castle in paragraphs. 1 and 2, characterized in that the control means of the latch is an electromagnet, the inputs of which are connected to the power source, and the core is connected to the latch.  4. The lock according to claim 3, characterized in that the connection of the core with the latch is made by means of a link of non-magnetic material to prevent magnetic flooding.

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