RU90831U1 - ELECTROMAGNETIC LOCK - Google Patents

Abstract

An electromagnetic lock, including a bolt, interacting with a catcher located in the lock body having a cup shape made in the form of a stepped-cylindrical sleeve, coaxially with which a latch arranged with the possibility of longitudinal movement is placed, as well as an electromagnet and a ball locking mechanism installed in the lock case , characterized in that the lock is supplemented by a permanent magnet, and the latch is made of ferromagnetic material in the form of a glass, in the central part of the bottom of which is on the inside The above-mentioned permanent magnet is fixed, while the electromagnet coil is placed along the length of the body between its wall and the reference plane formed by the outer surfaces of the retainer and the catcher in such a way that one cheek of the coil is adjacent to the bottom of the body, and the second to the thickened part of the stepped-cylindrical sleeve of the catcher located at the beginning of the inner cavity of the housing and connected to the inner surface of the housing.

Description

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

Known electromagnetic lock containing installed in the housing with the possibility of longitudinal movement of the spring-loaded bolt with an internal cavity and a bevel at the locking end, a return spring, one end of which abuts against a protrusion on the inner surface of the housing, and a ball locking mechanism, the balls of which are placed in the holes of the console part of the housing an electromagnet supported by a spring-loaded core of an electromagnet having a stepped shape in length with cylindrical and conical sections (RU 2063505, ЕВВ 47/02, 10.07.199 6).

The disadvantage of this device is that the electromagnet only unlocks the locking mechanism, and to fix the bolt in the open position, it is necessary to move the bolt using the handle connected to it.

The closest in technical essence to the described utility model is an electromagnetic lock, including a bolt, interacting with a catcher located in the lock case, made in the form of a cylindrical sleeve, coaxially with which a latch arranged with the possibility of longitudinal movement is placed, as well as an electromagnet with a core installed in the lock case and ball locking mechanism, (RU 2298623, ЕВВ 47/02, 01/20/2004). The disadvantage of this device is the limited technological and operational capabilities of the castle, due to its shape in the form of a glass and dimensions that do not allow it to be installed on doors with thin walls, for example, on the doors of refrigerators.

The problem the utility model aims to solve is to create an electromagnetic lock devoid of the disadvantages of the prototype, namely, to obtain a universal lock for locking doors of various thicknesses.

The technical result, which the utility model aims to achieve, is achieved by the fact that the electromagnetic lock includes a bolt interacting with a catcher located in the lock case, made in the form of a step-cylindrical sleeve, coaxially with which a latch arranged with the possibility of longitudinal movement is placed, and an electromagnet and ball locking mechanism are also installed in the lock case, supplemented with a permanent magnet, the lock case has the shape of a rectangle, and the lock is made of ferromagnetically material in the form of a cup, in the central part of the bottom of which the said permanent magnet is mounted on the inside, while the coil of the electromagnet is placed along the length of the housing between its wall and the conventional plane formed by the outer surfaces of the latch and catcher so that one cheek of the coil is adjacent to the base case, and the second - to the thickened part of the stepped-cylindrical sleeve of the catcher, located at the beginning of the internal cavity of the body and connected to the inner surface of the body.

The essence of the utility model is that due to the placement of the electromagnet coil along the length of the lock case, the placement of the lock elements inside the electromagnet coil, the use of a clamp made of ferromagnetic material in the form of a cup as a core of the electromagnet, and the addition of the electromagnetic lock by a permanent magnet interacting with the crossbar installed in the central part of the bottom of the latch, as well as the execution of the case by a rectangular lock becomes compact, which leads to the expansion of its technology cal opportunities, increase flexibility and reduce the weight of the lock. In Fig.1 shows a General view of the lock, Fig.2 is a longitudinal section of an electromagnetic lock in the "open" position, Fig.3 is the same in the "closed" position.

The electromagnetic lock contains a rectangular housing 1 in which an electromagnet coil 2 is mounted. In the inner cavity of the coil 2 there is a catcher 3 made in the form of a stepped-cylindrical sleeve, coaxially with which a latch 4 made with the possibility of longitudinal movement is placed, and a ball locking mechanism. The catcher 3 contains a Central hole, consisting of a conical part 5, a cylindrical part 6 and a threaded part 7. The outer diametrical surface of the catcher 3 consists of three parts - a thickened magnetic part 8, the middle part 9, the diameter of which is equal to the inner diameter of the coil 2 and the third cantilever part 10, the diameter of which is smaller than the inner diameter of the coil 2. On the cantilever part 10 of the catcher 3, holes 11 are made for balls 12 of the locking mechanism. The holes 11 are made in the form of two parts 13 and 14 of different diameters connected by a conical transition. The diameter of the part 13 of the holes 11 located on the outer surface of the cantilever part 10 of the catcher 3 is equal to the diameter of the balls 12, and the part 14 of the holes 11 located on the inner surface of the cylindrical part 6 of the hole of the catcher 3 is less than the diameter of the balls 12. The depth of the holes 11 of each diameter is such that the surface of the balls 12 located in them coincide with the outer surface of the cantilever part 10 of the catcher 3 and protrudes beyond the inner surface of the cylindrical part 6 of the hole of the catcher 3. The latch 4 is placed in the cavity formed between onsolnoy portion 10 of the safety device 3 and the inner surface of the reel 2 with the possibility of longitudinal displacement. The inner surface of the retainer 4 is made in the form of two parts of different diameters connected by a conical transition, which differ from each other by the size of the protrusion of the balls 11 beyond the inner surface of the cylindrical part 6 of the hole. The latch 4 is made of ferromagnetic material and performs the function of a cylindrical core of an electromagnet. The latch 4 has the possibility of longitudinal movement inside the coil 2 to the base of the housing 1. On the inner side of the bottom of the latch 4 a blind hole 15 is made, in which a disk permanent magnet 16 is placed with the possibility of interaction with the ball head 17 of the crossbar 18. The latter is made in the form of a rod passing through the central hole of the catcher 3. The diameter of the head 17 of the crossbar 18 is equal to the diameter of the cylindrical part 6 of the hole of the catcher 3. The coil 2 is installed along the length of the castle body 1 between its wall and a conventional plane formed by the outer the surfaces of the retainer 4 and the catcher 3 in such a way that one cheek 19 of the coil 2 is adjacent to the base of the housing 1, and the second 20 to the thickened 8 step-cylindrical sleeve of the catcher 3. For fixing the catcher 3 to the housing 1, a flange 21 is intended.

Electromechanical lock operates as follows. In the initial position, which occurs after disconnecting the coil 2 of the electromagnet from the power source, under the influence of the magnetic flux generated by the magnet 16, the bottom of the latch 4 is pulled to the end surface of the cantilever part 10 of the catcher 3 to the stop and the latch 4 is set to its original position (figure 2) , allowing the balls 12 of the locking mechanism to move in the holes 11 in the transverse direction. In this case, the crossbar 18 is released and the lock opens. When you turn on the power of the coil 2 of the electromagnet, the latch 4 remains in the same position, since the current flowing through the coil 2 is small and the magnetic flux generated by it is not sufficient to overcome the force created by the permanent magnet 16. When closing the door, the bolt 18 with the head 17 passes through the hole of the flange 21, falls into the conical part of the hole 5 of the trap 3 and is directed, with subsequent movement, into the cylindrical part 6 of the hole of the trap 3. In this case, the ball head 17 pushes the balls 12 and comes in contact with the magnet 16, times eschennym in the bottom of the retainer 4 and moves the latter. The latch 4 with its inner surface of smaller diameter pushes the balls 12 beyond the inner surface of the cylindrical part 6 of the hole of the catcher 3, eliminating the possibility of movement of the bolt 18 in the opposite direction. Further movement of the crossbar 18 reduces the gap between the bottom of the latch 4 and the base of the housing 1. When the gap between the bottom of the latch 4 and the base of the housing 1 is reduced so that the magnetic flux of the magnet 16 and the magnetic flux of the coil 2 passing along the path: housing 1, thickened magnetically conductive part 8 the catcher 3, its middle part 9, the latch 4 and the bolt 18, are summed up and create a force sufficient to attract the bottom of the latch 4 to the base of the housing 1. The electromechanical lock is in the closed state, (figure 3)

To open the lock, the coil 2 is disconnected from the power source. At the same time, along with the movement of the bolt 18 in the opposite direction, the magnet 16 is attracted to the ball head 17 of the bolt 18 and moves the lock 4 all the way to the end surface of the catcher 3, allowing the balls 12 to move in the holes 11 in the transverse direction, and the ball head 17 to exit from the cylindrical parts 6 of the hole for the catcher 3.

Claims (1)

An electromagnetic lock, including a bolt, interacting with a catcher located in the lock body having a cup shape made in the form of a stepped-cylindrical sleeve, coaxially with which a latch arranged with the possibility of longitudinal movement is placed, as well as an electromagnet and a ball locking mechanism installed in the lock case , characterized in that the lock is supplemented by a permanent magnet, and the latch is made of ferromagnetic material in the form of a glass, in the central part of the bottom of which is on the inside The above-mentioned permanent magnet is fixed, while the electromagnet coil is placed along the length of the body between its wall and the reference plane formed by the outer surfaces of the retainer and the catcher in such a way that one cheek of the coil is adjacent to the bottom of the body, and the second to the thickened part of the stepped-cylindrical sleeve of the catcher located at the beginning of the inner cavity of the housing and connected to the inner surface of the housing.