RU2295620C1 - Lock - Google Patents

Abstract

FIELD: locks.

SUBSTANCE: lock comprises locking mechanism, first lock for locking the mechanism, means for pressing the first lock for permitting cooperation with the locking mechanism, second lock, and mechanism for actuating the second lock. The mechanism for actuating the second lock is made of third lock and means for pressing the second lock for permitting cooperation with the first lock or the locking mechanism.

EFFECT: reduced power consumption.

2 dwg

Description

The invention relates to locks, as well as to executive mechanical devices and can be used, in particular, in the construction of household, office and safe locks with manual and remote (radio or wire) control.

Known remotely controlled lock company "Cisa" (Italy), the model "Wave", equipped with a latch and a rotary handle. The low-power electric drive of this lock ensures the establishment and breaking of an unloaded mechanical connection between the handle and the latch. The operation of the lock is possible without replacing the battery for a long time. However, the need for the participation of the hand when unlocking the lock, namely the rotation of the handle coupled to the latch, does not allow for autonomous or secretive functioning of the product.

The closest analogue to the claimed invention is a lock with wire control of the company "Iseo" (Italy), model 2001, which does not require, unlike the design mentioned above, the action of the hand to unlock it. The lock contains a locking mechanism, a first latch designed to block it and made in the form of a rotary lever, a second latch designed to block the first latch and a drive mechanism of the second latch made in the form of an electromagnet. The locking mechanism comprises a cocking bolt with an entry bevel and a latch spring-loaded outside the lock and interconnected by a powerful spring mechanism necessary for reliable unlocking of the lock. The first latch is installed to lock the latch. The lock mechanism is also equipped with a means of preloading the latch in the direction of its movement, made in the form of a center of rotation of the latch displaced relative to the latch force. When the door is closed, the cocking bolt and the latch under the influence of the door frame are sunk into the lock case, the first and second locks go into the locking position, the latch falls into the niche provided for it in the frame and is locked by the first lock in the extended position, the cocking bolt cockes the spring mechanism that compresses the latch inside the castle. To open the lock, turn on the electromagnet, the second lock releases the first, it releases the latch and the spring mechanism carries it inside the lock, which leads to its unlocking.

This design is equipped with a powerful electromagnet necessary to overcome the friction caused by a noticeable force on the second latch from the side of the first, which, in turn, is loaded with a spring mechanism through the latch. The presence of a strong electromagnet makes it difficult to operate the lock offline, as requires the use of a bulky battery, as well as a system for recharging it from the network.

The objective of the invention is the creation of a compact, autonomously functioning, remotely controlled lock with built-in power source, capable of working for a long time without changing or charging the battery.

The technical result is the reduction of energy consumption in the drive mechanism due to the use of mechanical energy stored in the lock when it is locked and / or unlocked.

This is achieved by the fact that in the lock containing the locking mechanism, the first latch designed to block it, the tool pushed the first latch in the direction of its movement, installed with the possibility of interaction with the locking mechanism, a second latch designed to block the first, the drive mechanism of the second latch, according to the invention, the drive mechanism is formed by additionally introduced a third latch, designed to block the second, the drive of the third latch and means preloaded the second latch in the direction of its movement, installed with the possibility of interaction with the first latch or locking mechanism.

Signs that distinguish from the closest analogue are:

- the design additionally introduced a third latch, intended to block the second;

- the drive of the third latch is additionally introduced into the design;

- in the design, a means of tightening the second retainer is additionally introduced;

- the tool is tightened second clamp is installed with the possibility of impact on the clamp in the direction of its movement;

- the tool is tightened second clamp is installed with the possibility of interaction with the first clamp or locking mechanism;

- the third latch, its drive and the tool pushed the second latch form the drive mechanism of the second latch.

Figure 1, 2 shows the kinematic diagram of the castle in a locked and unlocked state.

In the housing 1 of the device (Fig. 1) there is a locking mechanism comprising a bolt 2, movably mounted in the supports 3 and a window 4 in the housing 1. The bolt is equipped with a drive lever 5 and is spring loaded inside the housing with a working spring 6. The first latch is made in the form of a lever 7, pivotally mounted in the support 8 and pressed by the return spring 9 in the direction of blocking the bolt. The first latch is installed with the possibility of interaction with his toe 10 with the toe 11 of the crossbar. The second latch is made in the form of a lever 12, pivotally mounted in the support 13 with the possibility of interaction with his toe 14 with the toe 10 of the first latch and a spring-loaded return spring 15 in the direction of blocking the first latch.

The means of preloading the first retainer in the direction of its movement is formed by the beveled interacting faces of the bolt toe 11 and toe 10 of the first retainer: when one is applied to the other, the force is directed normal to the interacting faces (the direction of the force is shown by arrow A), it partially acts in the direction of movement of the retainer, more precisely, in the direction of unlocking the bolt, and creates a preload of the first latch.

The drive mechanism of the second latch includes a third latch, made in the form of a lever 17, pivotally mounted in the support 18 with the possibility of blocking the second latch and spring-loaded return spring 19 in the direction of blocking the second latch. The drive of the third latch is made in the form of an electromagnet containing a coil 20 and a core 21 movably mounted inside it, connected to the third latch by a thrust 22. The drive mechanism of the second latch also includes means for compressing the second latch, formed, in accordance with the first alternative feature of the invention, by shifting the center of rotation the second retainer relative to the force of the first retainer: when the first retainer acts on the second force, it is directed along the normal to the interacting surfaces (the direction of ilia is shown by arrow B) and creates a moment of rotation of the second latch in the support 13 and, accordingly, causes the second latch to be pressed in the direction of its end movement to the third latch. 1, 2 also shows a means of preloading the second latch, built on the second alternative feature of the invention. It is formed by a spring tab 23 (shown by a dashed line) mounted on the second latch with the possibility of interaction with the locking mechanism (with the bolt).

The device operates as follows.

When the lock is locked (Fig. 1), the latches, under the action of their return springs, are in the initial blocking position, the core of the electromagnet is pulled out of the coil, the bolt is pulled out of the lock body and locked by the first clamp. The working spring creates a preload of the bolt to the first latch, that is tightened to the second, second to third.

To unlock the lock, turn on the power of the electromagnet coil. The anchor slides into the coil (figure 2) and through the rod rotates the third latch, which leads to the unlocking of the second latch. The second latch under the influence of the first rotates to the third latch, thereby unlocking the first. The first latch under the influence of the crossbar turns to the second and unlocks the crossbar. A working spring carries the bolt into the housing. As a result of the process of “self-unlocking” of the latches described above, the lock goes into an unlocked state. The power of the electromagnet coil is turned off.

To lock the lock, the bolt is moved out of the housing until it stops, acting on the drive lever and overcoming the action of the working spring. The first latch under the action of its return spring is rotated to a position corresponding to the locking bolt. With the rotation of the first latch, in turn, the second latch is released and, under the action of its return spring, rotates towards blocking the first latch. Finally, with the rotation of the second latch, the third one is released and rotates under the action of its return spring to the position blocking the second latch, pulling the electromagnet armature from the coil. The castle goes into a locked state, the movable elements of the castle return to their original position (figure 1).

Thus, the means of tightening the second retainer allows the energy accumulated by the lock mechanism at one stage to be used at other stages to overcome friction between the parts of the device and the action of auxiliary springs. Thanks to this, the lock can be controlled by a less powerful and, accordingly, more economical drive mechanism. This makes it possible to create locks with remote control and long autonomous functioning. Direct use of the product is also facilitated: regardless of the strength and massiveness of the lock, it is necessary to unlock it with a light movement of a miniature key or a slight effort to press a button or lever of a manual drive.

The considered construction principle of control devices can be applied when creating cocked mechanisms for other purposes, for example, residual current circuit breakers (RCDs) used in electrical engineering.

Since the locking mechanism with the "closest" latches to it can be arbitrarily combined into one functional unit and considered as a locking mechanism, the lock in accordance with the claims may contain a chain of an arbitrary number of latches interacting with each other (according to the "domino" principle). Of course, the total number of latches in the device is limited by the complexity, reliability and cost of the design.

Claims (1)

A lock containing a locking mechanism, a first latch designed to block it, means for compressing the first latch that can interact with the locking mechanism, a second latch designed to block the first, the drive mechanism of the second latch, characterized in that the drive mechanism of the second latch is made in the form the third latch, designed to block the second latch, the drive of the third latch and means of preloading the second latch, with the possibility of interaction with the first latch or locking mechanism.

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