RU2493345C1 - Electromagnet lock - Google Patents

Abstract

FIELD: construction.

SUBSTANCE: coaxially in a lock body there are the following components installed: a catch made in the form of a bushing, and a fixator capable of longitudinal displacement with the first permanent magnet installed inside of it, which interacts with the crossbar head, in the lock body there is also an electromagnet with a coil and a core. The fixator wall comprises a ball stop mechanism. The lock is complemented with the first and second magnet shunts, which are fixed inside the fixator accordingly at the front and rear sides of the first permanent magnet, with a stop fixed on the inner end of the core and fixing the electromagnet coil, and a ring installed inside the body in the plane of the front part of the stop. The crossbar head is complemented with the second permanent magnet and is made with a belt that interacts with the catch. The diameter of the inlet hole of the catch is made as corresponding to the belt diameter and the external diameter of the working part of the crossbar head, at the same time the door pad is made as cup-shaped, and its bottom couples along the ball surface with the responsive part of the external end of the stem.

EFFECT: electromagnetic lock makes it possible to increase operation reliability.

3 dwg

Description

An electromagnetic lock belongs to the field of hardware, in particular, to locking devices controlled by electromagnetic means, and can be used to lock doors for various purposes, including refrigerator doors and safes.

A known electromagnetic lock containing a bolt interacting with a catcher located in the lock case, made in the form of a cylindrical sleeve, coaxially with which a spring-loaded clamp is arranged with the possibility of longitudinal movement, as well as an electromagnet with a coil and a core installed in the lock case and a ball locking mechanism (RU 2298623, ЕВВ 47/02, 01/20/2004).

The disadvantage of this device is the increased energy consumption due to the fact that when the lock is locked, a voltage is applied to the electromagnet coil, after which the electromagnet must remain on until the lock is opened. In case of any power failure, for example, due to wire breakage, damage to the electromagnet coil or battery discharge of the power supply, the lock automatically opens, which reduces its reliability.

The closest in technical essence to the described invention is an electromagnetic lock, comprising a spring-loaded deadbolt, consisting of a head and a rod, movably connected to the door lining, a catch catcher coaxially arranged in the lock body, made in the form of a sleeve, and having the possibility of longitudinal movement of the latch mounted inside it with a permanent magnet interacting with the crossbar head, as well as a ball locking mechanism located in the latch wall and an electromagnet fixed in the lock case the coil and core. In this lock, the lock on the outside has a conical bore designed to center the crossbar head. The inlet of the latch does not prevent a possible skew of the bolt with respect to the axis of the latch (RU 2382861, ЕВВ 47/02, 10/21/2008).

The disadvantage of this lock is the lack of reliability due to the possibility of a significant skew of the bolt relative to the axis of the latch, which can lead to spontaneous unlocking of the lock due to a violation of contact between the bolt head and the permanent magnet, the difficulty of connecting the bolt to the door trim, and the overheating of the electromagnet coil due to increased energy consumption , as well as the lack of attachment of the coil of the electromagnet.

The task of the invention is to increase the reliability of the electromagnetic lock.

The technical result to which the invention is directed is achieved by the fact that an electromagnetic lock comprising a spring-loaded deadbolt, consisting of a head and a rod, movably connected to the door trim, a catcher arranged in the form of a sleeve coaxially located in the lock case and having the possibility of longitudinal movement of the latch with the first permanent magnet installed inside it, interacting with the bolt head, as well as a ball locking mechanism located in the latch wall and a lock fixed in the housing an electromagnet with a coil and a core, supplemented by first and second magnetic shunts mounted inside the lock, respectively, from the front and rear sides of the first permanent magnet, with a stop fixed on the inner end of the core and fixing the electromagnet coil, and a ring mounted inside the housing in the plane of the front of the stop , the crossbar head is supplemented by a second permanent magnet and is made with a belt interacting with the catcher, the diameter of the catcher inlet is made corresponding to the diameter of the belt and the outer diameter of the working part of the head of the bolt, while the door plate is made in a cup-shaped form, and its bottom is mated on the ball surface with the counterpart of the outer end of the stem.

The essence of the proposed technical solution lies in the fact that the addition of the lock with the first and second magnetic shunts mounted inside the lock, respectively, from the front and rear sides of the first permanent magnet, as well as the ring, allows you to reduce the current in the coil, reduce the power consumption from the power source, and , accordingly, to reduce the heating of the coil, thus increasing the reliability of the lock, simplifying the connection of the bolt with the door trim, supplementing the bolt head with a second permanent magnet and performing it with the belt in the zone of connection of the head with the rod, as well as the execution of the catcher inlet corresponding to the diameter of the belt and the working part of the bolt head, reduces the mechanical load on the latch when the bolt is inserted, eliminates the possibility of excessive skewing of the bolt relative to the axis of the latch, which leads to spontaneous unlocking of the lock, and eliminates inadvertent disengagement of the bolt head with a lock, the addition of a lock with a stop fixed on the inner end of the core, allows you to fix the electromagnet coil, which o also increases the reliability of the lock.

In Fig.1 shows a longitudinal section of the lock in the "open" state with the dead bolt, in Fig.2 - the section of the lock in the "open" state with the bolt inserted, and Fig.3 - the cross section of the lock in the "closed" state.

The lock contains a cylindrical body 1, into which an electromagnet core 2 is pressed in, having a central threaded hole 3. An electromagnet coil 4 is placed on the cylindrical part of the core 2, which is fixed by a stop 5 installed in the threaded hole 3 of the core 2. The stop can be made, for example, in the form pan head screws. A catcher 6 is arranged coaxially in the lock case 1, and the latch 7 is longitudinally movable. The diameter of the front part of the stop 5 is larger than the diameter of the cylindrical part of the core 2, which reduces the resistance of the magnetic circuit of the electromagnet in the contact zone of the latch 7 with the core 2 and thereby increases the efficiency electromagnet. The catcher 6 is made in the form of a stepped sleeve with an external 8 and 9 internal conical bores, an inlet cylindrical hole 10, and a cylindrical working cavity 11. The latch 7 is a stepped sleeve, the larger outer part of which contacts the walls of the housing 1, and the smaller part is made with holes 12 for balls 13 of the locking mechanism interacting with the inner conical bore 9 of the catcher 6 and its cylindrical working cavity 11. Between the catcher 6 and the housing 1 is a washer 14. In the inner hole 15 of the latch 7, the first permanent magnet 16 is placed 16. On the front side of the same hole, the first magnetic shunt 17 is installed. On the back side of the first permanent magnet 16, a second magnetic shunt 19 is pressed into the cylindrical bore 18 of the latch 7. Inside the housing 1, in the plane of the front of the stop 5, in the embodiment under consideration, a ring 20 is fixed in the plane of the screw head. The latter compensates for the influence of the air gap between the housing 1 and the outer surface of the retainer 7 on the magnetic flux, because reduces the resistance of the circuit of the magnetic flux passing through the latch 7 and the housing 1. The lock also includes a bolt, consisting of interconnected threaded connection of the shaped head 21 and the rod 22, movably connected to the door trim 23. The bolt is under the constant influence of a pre-compressed spring 24, placed on the rod 22 between the head 21 of the bolt having a rounded side surface and the overlay 23. The latter is made in the shape of a cup, and its bottom is mated on the ball surface with the mating part 25 of the outer about the end of the rod 22. Pairing on the spherical surface of the lining 23 with the counterpart 25 of the outer end of the rod 22 provides automatic alignment of the bolt relative to the lining 23 in its free state, the necessary misalignment of the bolt when the head 21 is inserted into the catcher 6 in the event of an acceptable misalignment of the lining 23 of the housing 1 or during indirect movement of the bolt in the process of closing the door, as well as the possibility of additional axial movement of the lining 23 after the stop of the head 21 of the bolt in the first magnetic shunt 17. The head 21 r gel in the connection area with the rod 22 has a rib 26 cooperating with the catcher 6, wherein the diameter of the entrance opening 10 the safety device 6 is corresponding to the diameter of the girdle 26 and the outer diameter of the working portion of the head bolt 21. This design of the catcher 6 makes it possible to center the head of the bolt 21 before it is inserted into the internal cavity of the latch 7, and thus reduce the mechanical load on the latch 7. On the front side of the head 21, a second permanent magnet 28 is pressed into the hole 27. Between the door trim 23 and the spring 22 a washer 29 is placed, the outer diameter of which is larger than the diameter of the hole 30 in the door trim 23. The thickness of the first magnetic shunt 17 is selected so as to optimally minimize the force of attraction of the head 21 of the bolt to the latch 7. The thickness of the second magnetic shunt 19 is selected so that it is in a state of magnetic saturation, and part of the magnetic flux generated by the first permanent magnet 16 is closed through the stop 5, core 2, housing 1, ring 20 and retainer 7. This creates a small the magnitude of the force of attraction of the second magnetic shunt 19 to the stop 5, sufficient to hold the latch 7 in the "open" state with the deadbolt and the electromagnet coil 4 off. At the same time, this force does not interfere with the adhesion and joint movement of the head 21 of the crossbar and the latch 6 when locking the lock.

The work of the castle is as follows. In the initial state shown in FIG. 1, when the door is open, the bolt is pulled out of the lock case 1 and under the influence of the spring 24 as a result of the interaction of the mating part 25 of the outer end of the stem 22 with the plate 23 is centered with respect to the plate 23 which is rigidly attached to the door. The coil 4 of the electromagnet is de-energized. The latch 7 is in the “open” state, in which the second magnetic shunt 19 pressed into it is pressed against the stop 5 under the influence of the aforementioned part of the magnetic flux created by the permanent magnet 16. When the door is subsequently closed, the crossbar head 21 guided by the external conical bore 8 of the catch 6 , is introduced into its inlet 10. In this case, in the case of an allowable misalignment of the cover 23 and the housing 1 or with a non-linear movement of the crossbar during the closing of the door, the crossbar deviates from its original position in the limits allowed by the diameter of the hole 30 in the door trim 23, and is installed coaxially with the housing 1 of the castle. With the subsequent movement of the door, the bolt freely enters the internal cavity of the latch 7 and is installed in the position shown in figure 2. During this movement, the working part of the head of the crossbar 21 displaces the balls 13 of the locking mechanism into the zone of the conical bore 9 of the catcher 6. The head 21 of the crossbar with a magnet 28 comes into contact with the first magnetic shunt 17, and under the influence of the total flux of the first permanent magnet 16 and the second permanent magnet 28 is attracted to it with optimally minimized effort. In this case, the belt 26 of the head 21 of the crossbar is installed in the zone of the inlet 10 of the catcher 12, the diameter of which corresponds to the diameter of the belt 26 and the working part of the head 21 of the crossbar. There is the possibility of additional movement of the door forward, in which the cover 23 and the washer 29, overcoming the resistance of the spring 24, are displaced along the stem 22. When you try to open the door, the lock is automatically locked without additional external influences. In this case, the head 21 of the crossbar, due to the total attraction of the first permanent magnet 16 and the second permanent magnet 28, carries the latch 7 and moves it to the position shown in Fig.3. In this closed state of the lock, the latch 7 is pressed against the catcher 6 by the force transmitted to it by the working part of the head of the crossbar 21 through the balls 13. Moreover, the balls 13 of the locking mechanism are located in the area of the cylindrical working cavity 11 of the catcher 6 and therefore they cannot be forced out of the inner the cavity of the retainer 7, which prevents the output of the working part of the head 21 of the crossbar. In the open and closed states of the lock, the belt 26 of the crossbar head 21 is located in the area of the inlet 10 of the catcher 6, which eliminates the possibility of excessive skewing of the crossbar, which can lead to unintentional opening of the lock. To unlock the lock on the coil 4 of the electromagnet supplied voltage, and the bolt together with the latch 7 is recessed into the "open" position (figure 2). In the process of this movement, the working part of the head of the crossbar 21 recesses the latch 7 back until the second magnetic shunt 19 contacts with the stop 5, and the balls 13 of the locking mechanism are brought into the conical bore zone 9 from the inside of the catcher 6. In this case, the force exerted by the electromagnet 7 , the magnetic flux of which is closed along the path: core 2, stop 5, second magnetic shunt 19, retainer 7, ring 20 and housing 1, is folded with the force created by the first permanent magnet 16 and acting on the second magnetic shunt 19 from the stop side 5. The parameters of the coil 4 of the electromagnet, the first permanent magnet 16, as well as the geometric dimensions of the magnetic cores, including the thickness of the magnetic shunt 19, are selected in such a way that their total force is greater than the value of the force, which provided "sticking" of the latch 7 to the crossbar. As a result, the latch 7 is held in the “open” position, and the bolt is freely withdrawn from the inner cavity of the latch 7. Due to the optimal minimization of the force of attraction of the head 21 of the bolt to the latch 7 provided by the first magnetic shunt 17, as well as by the addition of the force created by the magnetic flux of the first constant magnet 16 passing through the second magnetic shunt 19 and the stop 5, with the force generated by the electromagnet, the current of the coil 4 of the electromagnet needed to hold the latch 7 when unlocking the lock can be minimized nym. The result is energy savings and eliminates the dangerous overheating of the coil 4 of the electromagnet.

Thus, the proposed implementation of the castle increases the reliability of its operation.

Claims (1)

An electromagnetic lock, including a spring-loaded bolt, consisting of a head and a rod, movably connected to the door trim, a catcher coaxially arranged in the lock body, made in the form of a sleeve, and having the possibility of longitudinal movement of the latch with the first permanent magnet installed inside it, interacting with the bolt head, as well as a ball locking mechanism located in the wall of the latch and an electromagnet with a coil and core fixed in the lock case, characterized in that the lock is supplemented first and with magnetic shunts, mounted inside the latch on the front and rear sides of the first permanent magnet, respectively, with a stop fixed on the inner end of the core and fixing the electromagnet coil, and a ring mounted inside the housing in the plane of the front of the stop, the crossbar head is supplemented with a second permanent magnet and made with a belt interacting with the catcher, the diameter of the inlet of the catcher is made corresponding to the diameter of the belt and the outer diameter of the working part of the crossbar head, while faithful plate is made cup-shaped and its bottom is accompanied by a spherical surface mating with the outer end of the rod.

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