RU2087658C1 - Remotely-operated hasp - Google Patents

Abstract

FIELD: locking devices. SUBSTANCE: this has body and coaxially located inside it are span-piece and slide which are installed for possible relative displacement and interaction by part of their length. Slide at its one end is provided with end stop located beyond body. Located between end stop and outer wall of body is compression spring. Span-piece and slide have fixing recesses located in their side surfaces and interacting with mechanisms for fixing their position located in body wall. One end of span-piece is located against hole in locking strip, and other end is in contact with other compression spring. Device is provided with span-piece stroke limiter created by protrusion and longitudinal slot. Interaction of span-piece and slide can be effected due to lateral slots on their ends directed towards each other, or due to axial passage in end of slide in which installed are compression spring and span-piece. Interaction of span-piece position fixing mechanism and fixing recesses is effected through longitudinal slot made in wall of axial passage. EFFECT: high efficiency. 4 cl, 5 dwg

Description

 The invention relates to locking devices and can be used in the design of locks designed for remote unlocking of room doors, cabinet doors, safes and the like in cases where the lock is fixed inside the lockable object and therefore cannot be opened by direct contact with it, then there is in cases of lack of direct access to the castle.

 Known remote-controlled valve containing a spring-loaded bolt with a groove on the side surface, interacting with the locking mechanism of the position of the bolt, driven by an electromagnet.

 The known device allows for remote unlocking of the lock, however, it has a complex electromechanical part and does not provide reliable fixation of the valve in the closed position, since the lock can open during shocks and vibrations.

 The technical result achieved in this invention is to create a remotely controlled gate valve with a simple design and increased locking reliability while reducing the size and power consumption.

 The specified technical result is achieved by the fact that in a remotely controlled valve containing a housing, a bolt located inside the housing with the possibility of longitudinal movement, the first compression spring in contact with one of the ends of the bolt, a mechanism for fixing the position of the bolt mounted in the wall of the housing, the fixing element of which interacts with a first locking recess on the side surface of the crossbar, and a locking strip with an opening coaxial with the crossbar, located opposite the other end of the crossbar, according to the invention On the other hand, a slider is installed coaxially with the crossbar, contacting one end with the first compression spring, and the other end of the slider is equipped with an end stop located outside the housing, and the valve is equipped with a second compression spring located on the slider between the end stop and the outer surface of the housing installed in the housing wall a mechanism for fixing the position of the slider, the fixing element of which interacts with the fixing recess made on the side surface of the slider, and a limiter for moving the bolt, and on the side The bolt surface has a second fixing recess located relative to the first one at a distance equal to the working stroke of the bolt, and the slider and the bolt are installed with the possibility of mutual movement and interaction with one another over part of their length.

 The mutual movement and interaction of the crossbar and the slider can be carried out by performing at the ends of the crossbar and the slider facing one another, transverse grooves, placing the side wall of the transverse groove of the crossbar and the first compression spring in the transverse groove of the slider, and the side wall of the transverse groove of the slider in the transverse groove the bolt, as well as the execution of the limiter to move the bolt in the form of a protrusion on the inner surface of the wall of the housing, interacting with a longitudinal groove, which is made on the side surface of the bolt; or by performing an axial channel at the end of the slider opposite the end stop, installing a bolt and a first compression spring in the axial channel and making a bolt movement limiter in the form of a protrusion on the lateral surface of the bolt interacting in the first longitudinal slot, which is made in the axial wall channel, while in the wall of the axial channel a second longitudinal slot is made, the position of which coincides with the position of the first and second fixing recesses in the side surface of the crossbar. In the latter case, a second protrusion located diametrically opposite to the first protrusion and interacting with a third longitudinal slot made in the wall of the axial channel can be made on the lateral surface of the crossbar.

 The mechanism for fixing the position of the bolt or the mechanism for fixing the position of the slider can be made in the form of an electromagnet installed in the wall of the housing perpendicular to the axis of the bolt and closed with a plug on the outside of the housing, while one end of the armature of the electromagnet is connected to the locking element, and placed between its other end and the plug additional compression spring.

 A feature of this remote-controlled valve is the use of the energy of pre-charged springs to move the moving structural elements when unlocking and locking. The electromagnets in this device are used only for fixing or for releasing these moving elements, which makes it possible to use a lower power source of energy for the valve than for supplying a valve with a power traction electromagnet.

 The invention is illustrated by drawings, where in FIG. 1 shows the design of a remote-controlled valve; in FIG. 2 the same, in the closed position; figure 3 the same, in a "cocked state"; in FIG. 4 design of a remote-controlled valve in another embodiment; in FIG. 5 is a structural electrical diagram of the inclusion of a remote-controlled valve.

The remote-controlled valve comprises a housing 1, inside of which a slider 2 and a bolt 3 are arranged coaxially, a locking bracket 4, a first compression spring 5 in contact with the bolt and the slider, a second compression spring 6 located on the slider 2 between its end stop 7 and the outer surface case 1, the mechanism for fixing the position of the crossbar 3, made in the form of an electromagnet, consisting of an armature 8 with a winding 9 installed in the hole made in the body 1 and closed by a plug 10, while between the plug and the armature 8 an additional Jin 11 compression. The locking mechanism of the position of the slider 2 is made in the form of an electromagnet, consisting of an armature 12 with a winding 13, spring-loaded with a second additional spring 14 to the plug 15. On the lateral surfaces of the crossbar 3 and the slider 2, respectively, the first, second and third fixing recesses 16, 17, 18, interacting respectively with the locking elements 19 and 20 of the mechanisms for fixing the position of the bolt 3 and the slider 2, respectively,
In accordance with FIG. 1, 2, 3 at the ends of the crossbar 3 and the slider 2 facing one another, transverse grooves 21 and 22 are made, the side wall 23 defining the groove 21 of the crossbar 3 and the first compression spring 5 included in the transverse groove 22 of the slide 2, and a side wall 24 defining a transverse groove 22 of the slider 2 is located in a transverse groove 21 of the crossbar 3; the movement limiter of the crossbar 3 is made in the form of a protrusion 25, for example, in the form of a pin on the inner surface of the wall of the housing 1, interacting with a longitudinal groove 26, which is made on the side surface of the crossbar 3.

 In accordance with FIG. 4, at the end of the slider 2, the opposite end with the end stop 7, an axial channel 27 is made, in which the first compression spring 5 and the crossbar 3 are placed, while the limiter for the movement of the crossbar 3 is made in the form of a protrusion 28 on the side surface of the crossbar 3 interacting with the first longitudinal a slot 29 made in the wall 30 of the axial channel 27, in which a second longitudinal slot 31 is also made, the position of which coincides with the positions of the first and second fixing recesses 16, 17 in the side surface of the crossbar 3. On the side surface of the crossbar 3 can be Execute the second protrusion (not shown) situated diametrically opposite first projection 28 and cooperating with the third longitudinal slit formed in the wall of the axial passage (not shown).

 The structural electrical circuit for switching on a remote-controlled gate valve consists of a DC voltage source 32, a diode 33, a lock release button 34, a lock release button 35, and also windings 9 and 13 of the electromagnets of the locking mechanisms of the crossbar 3 and the slider 2, respectively.

 Remote-controlled valve operates as follows.

 The housing 1 is fixed to the door of the lockable object. The locking bracket 4 is fixed on the door frame or on that side of the object to which the edge of the door adjoins when it is closed. In this case, in the initial state of the valve (Fig. 1) with the door of the object closed, the crossbar 3 is aligned with the hole of the locking bracket 4. In this state, the slider 2 and the crossbar 3 are in the extreme left position. Since the bolt 3 does not engage with the locking bracket 4, the door of the object is not locked and can freely open and close.

 To perform one locking-unlocking cycle, it is necessary to cock the first and second springs 5, 6. Cocking the springs 5 and 6 is done by pressing the end stop 7 of the slide 2 to the stop in the direction from left to right in accordance with FIG. 1. As a result of this pressing, the slider 2 will begin to move to the right. Since the anchor 8 fixes the crossbar 3, the latter remains stationary. Moving the slider 2 to the right with the fixed bolt 3 will compress the springs 6 and 5. The slider 2 will move to the right until the fixing recess 18 is opposite the armature 12. At this point, the armature 12 sinks into the fixing recess 18 and fixes the slider (Fig. . 3). If you now release the slider 2, it will not return to its original state, that is, the valve will remain in the cocked state. In this state, the valve is ready for one lock-unlock cycle without mechanical action on it, but only with the help of direct current pulses supplied to the windings of the locking and unlocking electromagnets.

 The locking of the valve occurs when a direct current pulse is applied, for example, by closing and opening the button 35 to the winding 13, as a result of which the armature 8 is attracted to the plug 10, rising up and compressing the spring 11. The armature 8 will remove the locking element 19 from the fixing recess 16. the crossbar 3 under the action of the compressed spring 5 will move to the right until the left edge of the longitudinal groove 26 on the lateral surface of the crossbar 3 abuts against the protrusion 25. In this case, the right end of the crossbar 3 will come out of the housing 1 and will go into the locking hole staples 4. Thus, the door of the object is locked and can no longer open until the valve is unlocked. After removing the voltage from the winding 9, the button 35 is open, the spring 11, unclenching, will release the anchor 8 down. In this case, the locking element 19 will enter the recess 16 and fix the bolt 3 in this position, which ensures the reliability of the constipation.

 Unlocking of the valve occurs when DC pulses are applied to both windings 9 and 13. In this case, the anchors 8 and 12 are pulled to the plugs 10 and 15, respectively, rising up and compressing the springs 11 and 14. The anchor 12 will then remove the locking element 20 from the recess 18, and the anchor 8 will withdraw the locking element 19 from the recess 16. The released slider 2 under the action of the expanding spring 6 begins to move to the left. In this case, the side wall 24 will pull along the side wall 23, as a result of which the crossbar will begin to move to the left. The movement will occur until the right edge of the longitudinal groove 26 of the crossbar 3 rests against the protrusion 25. As a result of this movement, the crossbar 3 will come out of the hole of the locking bracket 4 and be pulled into the housing 1.

 The electrical circuit shown in FIG. 5, works as follows. When the button 35 is closed, the DC voltage from the source 32 is supplied to the winding 13 and the electromagnet is activated, and the pre-cocked latch is locked, while the diode 33 prevents the DC voltage from entering the winding 13.

When you close the button 34, which is the unlocking, the DC voltage from the source 32 is supplied directly to the winding 9, and through the diode 33
to winding 13. Both electromagnets work and the latch unlocks.

 When using the latch in the room in which the patient is located, unable to get up, the buttons 34 and 35 are placed in a place accessible to the patient. The visitor, leaving the room, cocks the latch springs and closes the door behind him. After that, the patient presses the button 35 and the door is locked. If necessary, open the door, the patient presses the button 34, thereby unlocking the door.

 When using the latch to lock the safe, it is located on the inside of the safe door. The wires supplying DC voltage to the windings 9 and 13 are led out through a small hole and masked by plastering in the wall, gluing wallpaper, etc. Buttons 34 and 35 are installed in a hidden place.

 The latch can also be used to lock rooms in which people do not stay. In this case, it should be supplemented with a code device and a keyboard on which the unlock code is dialed. The code device is located inside the lockable object along with the latch. The keypad for dialing the code is displayed together with the locking button on the outer surface of the door of the locked room or go to the safe door or cabinet.

 The operation of the latch, the construction of which is shown in FIG. 4 occurs in a similar manner.

Claims (5)

 1. A remote-controlled valve containing a housing, a bolt placed inside the housing with the possibility of longitudinal movement, a first compression spring in contact with one of the ends of the bolt, a mechanism for fixing the position of the bolt mounted in the wall of the housing, the fixing element of which interacts with the first fixing recess on the side the surface of the bolt, and the locking plate with a hole coaxial with the bolt, located opposite the other end of the bolt, characterized in that coaxially with the bolt mounted slider in contact one end with the first compression spring, and the other end of the slider is equipped with an end stop located outside the body, the valve is equipped with a second compression spring located on the slider between the end stop and the outer surface of the body, a slide position fixing mechanism installed in the body wall, the fixing element of which interacts with a fixing recess made on the side surface of the slider and a limiter for moving the crossbar, and a second fixing recess is made on the side surface of the crossbar a position located relative to the first one at a distance equal to the working stroke of the crossbar, and the slider and the crossbar are installed with the possibility of mutual movement and interaction with one another over part of their length.  2. The valve according to claim 1, characterized in that at the ends of the crossbar and the slider facing one another, there are transverse grooves, the side wall of the transverse groove of the crossbar and the first compression spring located in the transverse groove of the slider, and the side wall of the transverse groove of the slider in the transverse groove of the crossbar, while the limiter for moving the crossbar is made in the form of a protrusion on the inner surface of the wall of the housing interacting with a longitudinal groove that is made on the side surface of the crossbar.  3. The valve according to claim 1, characterized in that at the end of the slider, opposite the end with an end stop, an axial channel is made in which a first compression spring and a bolt are installed, two longitudinal slots are made in the wall of the axial channel, and the limiter for moving the bolt is made in a protrusion on the side surface of the crossbar interacting with one of the longitudinal slits, the length of which is not less than the working stroke of the crossbar, while the position of the second longitudinal slot coincides with the positions of the first and second fixing recesses in the lateral surface crossbar stiffness.  4. The valve according to claims 1 and 3, characterized in that a second protrusion is made on the lateral surface of the crossbar located diametrically opposite to the first protrusion and interacting with a third longitudinal slot made in the wall of the axial channel.  5. The valve according to claim 1, characterized in that the bolt position fixing mechanism or the slide position fixation mechanism is made in the form of an electromagnet mounted in the wall of the body perpendicular to the bolt axis and closed with a plug on the outside of the body, while one end of the electromagnet armature is connected to the fixing element, and between its other end and the plug is placed an additional compression spring.

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