RU2171882C1 - Electromagnetic lock - Google Patents

Abstract

FIELD: security equipment, in particular, locking devices, and namely, code electromagnetic locks controlled by means of electronic equipment, applicable for closing of the doors of living and service rooms, cars, cabinets and safes, as well as of other objects. SUBSTANCE: the lock has a spring-loaded cross-bar with a cavity and chamfer on the locking end installed in the body for longitudinal motion, return spring, whose one end rests on a bulge on the spring, whose one end rests on a bulge on the inner surface of the body, and a means for fixation of the cross-bar made in the form of a ball arrester, whose balls are positioned in the holes of the electromagnet body cantilever with a support on the spring-loaded core of the electromagnet. The core is step-shaped in length with cylindrical and taper sections. An additional chamber is made on the locking end of the cross-bar symmetrically to the chamfer. A square-shaped rotary safety catch is installed on an axle that is parallel to the chamfer planes for arrestment in two positions: along and across the cross-bar. The safety catch length does not exceed the cross-bar width in plant, the safety catch width does not exceed a half of the cross-bar width in plan. In the initial position of the cross- bar the ball arrester is located in the cross-bar cavity for engagement of the balls with the cross-bar end that is opposite the locking end in the closed position of the cross-bar. The return spring is positioned between the body and the cross-bar, the other end of the return spring rests on an annular shoulder made on the end of the cross-bar that is opposite the locking end. EFFECT: improved characteristics. 10 cl, 8 dwg

Description

 The invention relates to security equipment, in particular to locking devices, namely, electromagnetic coded locks controlled by electronic equipment, and can be used to lock the doors of residential and office buildings, cars, cabinets and safes, as well as any objects in order to exclude unauthorized access.

State of the art
Known pin lock containing rotary rings, which are fixed from turning by means of a pin connected to the core of the electromagnet (US 4807454, E 05 B 47/00, 02.28.1989). When voltage is applied to the winding of the electromagnet, the core of the electromagnet is drawn into its winding and leads the pin out of the hole made in one of the rings. Then it is possible to rotate the rings and the mask with the key inserted. This lock cannot be attributed to electromagnetic locks, since the movement of the crossbar kinematically connected to the mask occurs due to mechanical stress. The electromagnet in the lock performs only the function of an additional common pin.

 Known electromagnetic lock containing a spring-loaded bolt connected to the core of the electromagnet (GB 2069590, E 05 47/00, 08/26/1981). In the known device, the movement of the core is equal to the working stroke of the crossbar, which is due to their rigid kinematic connection. When the lock is opened, the core of the electromagnet is drawn into the solenoid coil for a considerable distance, which increases energy consumption.

 The closest in technical essence and the achieved result to the described invention is an electromagnetic lock containing a spring-loaded crossbar installed in the housing with the possibility of longitudinal movement with an internal cavity and a bevel on the locking end, a return spring, one end of which abuts against a protrusion on the inner surface of the housing, and means fixing the bolt, made in the form of a ball locking mechanism, the balls of which are placed in the holes of the console part of the electromagnet body with support on a spring-loaded core of an electromagnet having a stepped shape in length with cylindrical and conical sections (RU 2063505, E 05 B 47/02, 07/10/1996). In the known device, the bolt is connected via a pin to a spring-loaded sleeve, which increases the total length of the lock. In the known device reduced power consumption since in the closed position, the power and control circuits are off. The design of the lock also allows you to reduce energy consumption by reducing up to 2 mm the stroke of the core of the electromagnet, since the traction force of the electromagnet is known to be inversely proportional to the square of the gap between the core and the pole of the electromagnet. In the closed position, the lock is manually installed inside the room. From the inside of the room, the lock can be opened manually by pulling the bolt by the handle inside the case. When tearing the lock outside the room, a short current pulse from the control system is supplied to the electromagnet winding. A retractable anchor carries along a core, which has a stepped shape, which unlocks the locking mechanism. After the castle is opened, its bolt moves to the closed position. To fix the crossbar in the open position, it is necessary to move the crossbar every time with the handle connected to it.

SUMMARY OF THE INVENTION
The objective of the present invention is the development and creation of an electromagnetic lock with enhanced characteristics.

 As a result of solving this problem, it is possible to obtain new technical results, namely, that the design of the device is simplified, the manufacturability is increased, and the lock can operate in the latch mode.

 These technical results are achieved in that in an electromagnetic lock comprising a spring-loaded bolt with an internal cavity and a bevel on the locking end installed in the housing with the possibility of longitudinal movement, a return spring, one end of which abuts against a protrusion on the inner surface of the housing, and a bolt fixing means made in the form of a ball locking mechanism, the balls of which are placed in the holes of the cantilever part of the electromagnet housing with support on the spring-loaded core of the electromagnet, having lengthwise step shape with cylindrical and conical sections, an additional bevel is symmetrically beveled on the locking end of the crossbar, on the axis parallel to the bevel planes it can be locked in two positions: a rectangular flag is rotated along and across the crossbar, and the flag does not exceed the width of the crossbar in the plan, the width of the flag does not exceed half the width of the bolt in the plan, the ball locking mechanism in the initial position of the bolt is located in the inner cavity of the bolt with the possibility of closed the position of the contact beam of the balls with the end of the crossbar opposite the locking end, and the return spring is located between the housing and the crossbar, while the other end of the return spring abuts against an annular collar made on the end of the crossbar opposite the locking end.

 A distinctive feature of the present invention is as follows. An additional bevel is made symmetrically to the bevel on the locking end of the crossbar so that the locking end of the crossbar has a triangular shape in plan. On an axis parallel to the planes of the bevels, the axis is mounted with the possibility of locking in two positions: along and across the crossbar, a rectangular rotating flag that interacts with the cover made on the door leaf or on the door frame and does not allow the crossbar to move earlier than the axis of the crossbar and the cover holes . Obviously, in each of the locking positions, in terms of the dimensions of the flag should not exceed the dimensions of the bolt. Therefore, the length of the flag does not exceed the width of the crossbar in the plan, the width of the flag does not exceed half the width of the crossbar in the plan. The ball locking mechanism in the initial position of the crossbar is located in the inner cavity of the crossbar, which significantly reduces the length of the lock. When the crossbar is closed, the balls are able to contact the end of the crossbar opposite the locking end, thereby fixing the crossbar in the closed position. The return spring is located between the housing and the crossbar, while the other end of the return spring abuts against an annular flange made on the end of the crossbar opposite the locking end.

 In addition, a rotating flag can be placed in a slot made in the locking end of the bolt. In this case, the flag is locked when its side contacts the slot side parallel to the axis of rotation of the flag.

 The cantilever part of the electromagnet case is expediently made of non-magnetic material, for example, plastic, and the rest of the case is made of ferromagnetic material.

 Balls of the ball locking mechanism can be made of non-magnetic material, which will prevent sticking when applying electric current to the winding of the electromagnet.

 The outer surface of the housing and the crossbar is preferably made cylindrical.

 The electromagnetic lock can be equipped with a spring-loaded button kinematically connected by means of a flexible shaft to the core of the electromagnet with the possibility of its movement. The result is the mechanical unlocking of the bolt (when it is jammed) from the inside of the room, regardless of whether or not the electric lock opening system is turned on.

 A cavity may be provided in the housing to accommodate an electronic unit that generates a signal to open the lock.

 In terms of plan, the axis parallel to the bevel planes is shifted by (0.5 - 2.5) mm relative to the longitudinal axis of the crossbar, which will allow the flag to be made equal to half the width of the crossbar, taking into account the need to make holes in the flag.

 It is also preferable that the length of the flag is (0.8 - 1.0) of the width of the crossbar in the plan, and the width of the flag is (0.4 - 0.5) of the width of the crossbar in the plan.

List of drawings
In FIG. 1 shows a longitudinal section of an electromagnetic lock in its initial position, FIG. 2 shows a fragment of the interaction of the crossbar with the pad during longitudinal locking of the flag, in FIG. 3 shows a longitudinal section through an electromagnetic lock with a recessed crossbar; FIG. 4 shows a longitudinal section through the electromagnetic lock in the locked position; FIG. 3 shows a fragment of locking the crossbar with an overlay during lateral locking of the flag; FIG. 6 shows a longitudinal section of a modification of an electromagnetic lock in its initial position; FIG. 7 shows a longitudinal section through a modification of an electromagnetic lock with a recessed crossbar; FIG. 8 is a longitudinal sectional view of a modification of an electromagnetic lock in a buried position.

Information confirming the possibility of carrying out the invention
The electromagnetic lock contains a crossbar 2 mounted in the housing 1 with the possibility of longitudinal movement, which is spring-loaded with a spring 3. The crossbar has an internal cavity 4 and two symmetrical bevels 5 at the locking end. The return spring 6 is located between the housing 1 and the bolt 2. One end of the spring abuts against the protrusion 7 on the inner surface of the housing. The other end of the return spring abuts against the annular collar 8. In the inner cavity 4, at the initial position of the crossbar 2 (see Fig. 1 and Fig. 6), there is a locking mechanism for the crossbar, made in the form of a ball locking mechanism, the balls 9 of which are placed in the holes of the console part 10 of the housing 11 of the electromagnet with support on the core 12 of the electromagnet. The core 12 has a stepped shape in length with cylindrical and conical sections and is spring-loaded with a spring 13. On the axis parallel to the bevel planes, the axis 14 is installed with the possibility of locking in two positions: a rotating flag 15 of a rectangular shape along and across the crossbar. In plan view, the axis 14 parallel to the bevel planes is offset relative to the longitudinal axis of the crossbar 2 by a distance d.

 The electromagnetic lock operates as follows.

 In FIG. 1, FIG. 3 and FIG. Figure 4 shows the modification of the lock, the deadbolt of which is unlocked by applying electric current to the winding of the electromagnet. In FIG. 6, FIG. 7 and FIG. Figure 8 shows a modification of the lock, the bolt of which is released when the voltage is removed from the winding of the electromagnet. For this reason, the difference between these modifications consists only in the sequence of execution of the conical and cylindrical sections of the core of the electromagnet.

 To close the door, the lock bolt is in its original position (see Fig. 1 and Fig. 6). When closing the door, the bevel 5 of the crossbar interacts with the lining 16 with the hole installed on the door frame (in principle, the lock can be installed in the frame and the lining on the door). As a result, the bolt is released. In this position, the spring 3 is compressed, since it is in contact with the end of the bolt 2. In this case, the spring 13 is in a compressed state. After the center of the crossbar is aligned with the hole of the lining, it is in the recessed position (see Fig. 3 and Fig. 7). When the door is further closed, the second bevel 5 does not come in contact with the cover 16. This is prevented by the flag 15 resting on the cover 16. Only after the crossbar axis is aligned with the axis of the hole in the cover 16, the crossbar is sharply ejected from the housing. The bolt is ejected due to the conversion of the potential energy of the spring 3 into kinetic energy accumulated during compression of the spring 3 at the time of closing the door. In the extended position of the crossbar, the return spring 6 is compressed and the bolt is fixed by the balls 10. The bolt is fixed due to the fact that, when the bolt is extended, the balls 10 unlock the core 12, which moves along the action of the spring 13. The balls 10 at this moment have the support on the cylindrical section of the core 12, are moved in the radial direction and are removed from contact with the surface of the inner cavity of the crossbar to the end of the crossbar, opposite the locking end.

 When applying electric current to the coil of the electromagnet, the core 12 is drawn into the coil. When this occurs, the compression of the spring 13 and the release of the balls 10, which move radially to the center of the core 12 and have a support on the conical section of the core 12. The balls 10 begin to contact the surface of the inner cavity of the crossbar, freeing its end face. The crossbar 2 under the action of the return spring 6 is returned to its original position. When the door is opened, the flag 15 by sliding the lining 16 along the bevel of the crossbar puts the flag in the position across the crossbar (see Fig. 5). In this position, the energy of the spring 3 is extinguished at the vanishing point of the flag 15 from the lining 16. Thus, the bolt is transferred not to the extended position, but to the original. The next time you close the door, the flag automatically switches to a position along the crossbar. The functioning of the lock modification, in which the locking of the bolt from the closed position is carried out by removing the voltage from the electromagnet coil, occurs in a similar way.

 The lock is opened from the inside by pressing a spring-loaded button 17, kinematically connected to the core 12 by means of a flexible shaft 18, made, for example, in the form of a cable for driving bicycle brakes. When you press the button 17, the cable in the form of a polymer core pushes the core of the electromagnet to the extreme position and unlocks the crossbar.

 Using mechanical opening of the lock from the inside of the room saves energy, and this method can also be used for emergency opening of the lock. Button 17 is structurally designed so that it can be locked in the depressed position. In this case, the core of the electromagnet loses its ability to move and the ball locking mechanism does not function. This allows you to put the lock in the door latch mode. Button 17 can be installed in a blind hole in the door from the inside of the room.

 The described design is technological, contains a small number of parts, and is easy to manufacture. The lock can be made as a mortise version, and overhead. Electronic components can be installed in the lock case, which receive a signal to open the lock and form an appropriate command, as well as other auxiliary equipment.

Claims (10)

 1. An electromagnetic lock comprising a spring-loaded bolt mounted in the housing with the possibility of longitudinal movement with an internal cavity and a bevel on the locking end, a return spring, one end of which abuts against a protrusion on the inner surface of the housing, and a bolt fixing means made in the form of a ball locking mechanism, balls of which are placed in the openings of the cantilever part of the electromagnet body with support on the spring-loaded core of the electromagnet, having a stepped shape in length with a cylindrical and con areas, characterized in that an additional bevel is symmetrically beveled on the locking end of the crossbar, on the axis parallel to the bevel planes it can be locked in two positions: a rectangular flag rotating along and across the crossbar, the flag length not exceeding the width of the crossbar in plan, width flag does not exceed half of the crossbar in the plan, the ball locking mechanism in the initial position of the crossbar is located in the inner cavity of the crossbar with the possibility of contacting when the bolt is closed balls with the end of the crossbar opposite the locking end, and the return spring is located between the housing and the crossbar, while the other end of the return spring abuts against an annular flange made on the end of the crossbar opposite the locking end.  2. An electromagnetic lock according to claim 1, characterized in that the rotating flag is placed in a slot made in the locking end of the bolt.  3. The electromagnetic lock according to claim 1 or 2, characterized in that the cantilever part of the electromagnet body is made of non-magnetic material, and the main part of the body is made of ferromagnetic material.  4. The electromagnetic lock according to claim 3, characterized in that plastic is used as a non-magnetic material.  5. An electromagnetic lock according to any one of claims 1 to 4, characterized in that the balls of the ball locking mechanism are made of non-magnetic material.  6. An electromagnetic lock according to any one of claims 1 to 5, characterized in that the outer surface of the housing and the crossbar is made of a cylindrical shape.  7. An electromagnetic lock according to any one of claims 1 to 6, characterized in that it is equipped with a spring-loaded button kinematically connected by means of a flexible shaft to the core of the electromagnet with the possibility of its movement.  8. An electromagnetic lock according to any one of claims 1 to 7, characterized in that a cavity is provided in the housing for housing the electronic unit.  9. An electromagnetic lock according to any one of claims 1 to 8, characterized in that in terms of plan, the axis parallel to the bevel planes is offset by 0.5 - 2.5 mm relative to the longitudinal axis of the crossbar.  10. An electromagnetic lock according to any one of claims 1 to 9, characterized in that the flag is 0.8-1.0 times the width of the crossbar in the plan, and the flag is 0.4-0.5 times the width of the crossbar in the plan.

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