RU2209286C2 - Turning door bolt - Google Patents

Abstract

FIELD: locksmith's work. SUBSTANCE: the locking bolt has a locking member in the form of a bar installed on the inner side of the door wing for turning about the axle fastened on the door wing with a shift relative to it of the center of gravity, as well as stopping and locking devices positioned on the same side of the door wing, it has a code disk with fixing holes and slots made along the circumferences concentric on the axis of turn of the locking member and having a width smaller than the diameter of the fixing holes installed on the locking member concentric on the axis of its rotation, as well as stopping devices located on the door wing coaxially with the fixing devices of the code disk and controlled by magnetic keys or by some other method and a stop member installed on the door wing on the side of the locking device. EFFECT: enhanced resistance to burglary. 5 cl, 15 dwg

Description

 The invention relates to locking devices, and more particularly to a device of rotary bolts, and can be used to lock the doors of houses and apartments, gates, gates of various buildings, etc.

 Closest to the device to the object of the invention is a rotary bolt, made according to (1). This deadbolt contains a locking element in the form of a rod (strap) installed with the possibility of rotation around an axis fixed to the leaf, as well as a locking and locking device.

 The bolt allows the execution of both without shifting the center of gravity of the locking element relative to its geometric axis, and with a shift of the center of gravity. An essential feature of the known deadbolt is the implementation of the locking device in the form of a purely mechanical (bolted) connection mounted on the frame rack.

 The main disadvantage of the known deadbolt is that the translation of its locking element from the closed state to the open and vice versa can only be done on the side of the sash with which this deadbolt is installed.

 This disadvantage significantly limits the scope of the known deadbolt and determines the low level of its secrecy. In addition, due to incomplete overlapping of the sash by the locking element (horizontally), this bolt is not sufficiently reliable in operation.

 The aim of the invention is to expand the functionality of the known rotary bolt to a level that allows it to be controlled in a non-contact way from the outside of the sash when installing all elements of the bolt design from the inside of the bolt, facing the locking room, as well as increasing privacy and improving performance.

 The solution of the formulated technical problem is achieved by the fact that the rotary bolt contains a locking element in the form of a rod mounted on the inner side of the leaf with the possibility of rotation around the axis of gravity fixed on the leaf with an offset relative to it, as well as a locking and locking device located on the same side of the leaf, however, it contains a code disk mounted on a locking element concentrically to the axis of its rotation with fixing holes and slots made along circles, concentric axes of rotation of the locking element and having a width smaller than the diameter of the fixing holes, as well as locking devices located on the leaf coaxially with the locking holes of the code disk and controlled by magnetic keys or otherwise and mounted on the leaf from the side of the locking device, a stop element.

 The bolt contains an additional locking device mounted on the opposite rack of the frame, and a locking element elongated to a size that allows the use of both locking devices for locking the flaps.

 The bolt has an additional locking hole on the code disk coaxially located with the locking device at the upper position of the locking element.

 In the code disk of the deadbolt along the axial lines of the slots adjacent to the locking holes on the side opposite to the direction of rotation of the locking element, additional code holes are made in an amount twice as large as the number of cycles of exposure of the deadbolt to the sensitive part of the locking devices by the keys controlling their operation, and on the back along the rotation of the locking element the wall of each code hole close to it is installed blocking the rotation of the disk locking elements in the form , for example, pins with alternating their installation on different sides of the disk through one code hole.

 The bolt contains remote devices for restricting the travel of the stopper rods, each of which is made in the form of a U-shaped bracket that is stationary relative to the leaf and encompasses the code disk, on which the locking device is fixed on one side of the leaf and on the other coaxially with the locking hole of the code a hole of the same or larger diameter is made, closed by a spring-loaded washer with a hole in its central part, mounted in a housing fixed to the same wall of a U-shaped bracket, with an opening at the end facing the inside of its wall lockable space coaxial with the hole in the washer and having a diameter equal to the diameter of the shank of the locking rod.

 In a rotary bolt containing a locking element in the form of a rod mounted on the inner side of the valves with the possibility of rotation around the axis of gravity fixed to the valve with an offset from it, the center of gravity, as well as locking and locking devices located on the same side of the valve, on the locking element with the rear ( facing the inner surface of the sash) side concentrically to the axis of its rotation, a code disk is installed (fixed) with fixing holes and slots made along the circles concentrically to the axis of rotation the mouth of the locking element and having a width less than the diameter of the locking holes.

 To solve the same problem, the proposed bolt contains locking devices located on the leaf coaxially with the fixing holes of the code disk and controlled by magnetic keys or in another way, and a stop element mounted on the leaf from the side of the locking device. By locking devices controlled in another way, are meant electromagnetic and electromechanical locking devices, locking devices controlled by radio engineering means and others. Since the design features of the locking devices and the methods for controlling them do not change the essence of the invention, it is advisable to explain it using the most simple and clear for understanding the principle of the device and operation of the bolt option. An example of such a deadbolt variant is shown in the accompanying drawings.

 In figures 1, 2 and 3, the device of one of the possible designs of the magnetically controlled deadbolt is shown in the closed position when viewed from the inside of the lockable room (Fig. 1) and from above (Fig. 2), as well as a view of the end surface of the sash along A- A (figure 3). In FIG. 4 and 5 show the positions of the movable elements of the locking devices relative to the code disk in the absence of magnetic keys in their sensitivity zones (Fig. 4) and after the latter is introduced into these zones (Fig. 5). Figures 6 and 7 show the relative position of the bolt elements at the moment of its transition from an open to a closed position (Fig. 6) and immediately after its transition from a closed to an open position.

 The bolt contains a locking element 1 in the form of a rod of rectangular cross-section mounted on an axis 3 fixed on the leaf 2 with an offset of the center of gravity of the OST relative to it. The axis of rotation 3 of the locking element is made in the considered deadbolt in the form of a bolt 4, mounted on a thread on a support plate 5, fixed relative to the leaf 2 (fixed on it with screws).

 On the locking element 1, on its rear side, a code disk 6 is installed concentrically with the axis of rotation of the bolt OO 6 with two fixing holes and slots on both sides of each of these holes made along a circle concentric with the axis of rotation OO of the locking element (this circle in FIG. 1, 2, 3 and 4 are shown by dashed-dotted lines). The width of all the slots Δpr (Fig. 1) under the condition of ensuring the health of the bolt and reliable fixation of the locking element when it is closed, is made smaller than the diameter of the fixing holes df (Fig. 5) of the code disk 6.

 The design of the bolt in the case of the execution of the code disk 6 according to figure 1 allows the use of one or two locking devices. Since the latter option is more preferable from the point of view of the security of the bolt, a further description of the description of the invention is carried out in relation to it. In the bolt drawings, the locking devices are indicated by digital indices 7 and 8. They are placed on the leaf coaxially with the fixing holes of the code disk. To ensure alignment in the design of the bolt provided mounting plate 9 (Fig. 5). These plates are mounted on the surface of the sash together with locking devices fixed to them on the thread.

 Locking devices can be made in accordance with (2) or (3).

 More preferred from the point of view of sensitivity to the effects of magnetic keys is the embodiment of the locking device described in (2). Each locking device made in accordance with (2) comprises a locking rod 10 (Fig. 4) with a permanent magnet (s) 11 at one of its ends (at its free end) and a fixing element in the form of a protrusion 12 of a cylindrical shape on the other (fixing it end). The locking rod has two stable positions, one of which is characterized by the placement of the protrusion 12 with a diameter Df in the fixing hole of the code disk 6 coaxially located with it (Fig. 4), and the second by placing at the same place a portion of the locking rod adjacent to the fixing protrusion 12 with side of the housing 13 of the locking device (figure 5). The diameter Dc of this portion of the stopper rod is less than the diameter Df and less than the width Δpr. slots. Changing the position of the locking rod (control of the locking device) is carried out by magnetic keys 14 and 15 (in the general case, magnetic keys 14 and 15 by the nature and results of their impact on the locking devices 7 and 8 may differ). The maximum movement of the rod (its stroke) under the condition of ensuring the health of the bolt is greater than the thickness of the code disk. To enable the control of the bolt from the inside of the lockable room, a shank 16 is provided on the stopper rod 10.

To perform the bolt procedure of automatic (without the use of magnetic keys) locking of the sash 2 when it is closed in the recess 17 (Fig. 3) of the sash, made on its left end side, a stop element is installed on the axis 18 with an offset of the center of gravity O'ct 19, made in this case in the form of a plate of triangular shape with the stop shoulder 21 projecting towards the locking device 20. The locking device itself, in the considered embodiment of the bolt design, to provide high strength To lock the sash, it is made of a U-shape with a plate bent from one of its walls at an angle of 90 ^° with holes for attaching it to the door frame 22.

 The work of the bolt is characterized by the movement of its movable element 1 between the following three stable positions.

 The first (horizontal) position of the movable element corresponds to the closed state of the deadbolt (figures 1 and 4). With this position, the locking protrusions 12 of the rods of the locking devices 7 and 8 are located inside the locking holes of the code disk 6, thereby eliminating the possibility of turning the locking element and moving it to other stable positions without affecting the locking devices 7 and 8 with magnetic keys 14 and 16 s the outer side of the sash or "pulling" the locking rods 10 by the shanks 16 until the locking tabs 12 exit completely from the fixing holes of the code disk 6 from its inner side. The leftmost portion of the locking element is in this case located in the inner cavity of the locking device, thereby preventing the sash from being opened when it is exposed to force from both its internal and external sides.

 The second (lower) and third (upper) stable positions of the locking element (Fig.6 and 7) correspond to the open state of the bolt. The locking protrusions 12 of the rods 10 of the locking devices 7 and 8 are located at these two positions of the locking element above the code disk, in contact with the end surfaces.

 In the lower position, the locking element is kept from further rotation under the influence of gravity by the rods of the locking devices (the code disk is supported by the edges of them). In the upper position, the locking element is kept from turning by the stop element 19, but only with the sash open (Fig. 3a). When closing the casement, the thrust element with the lower edge of the flange contacts the surface of the strut 22 and, forcibly turning, leaves the locking element into a recess 17 in the casement specially made for its placement.

 The content of operations to change the condition of the bolt depends on which side of the sash they are performed.

 To transfer the bolt from the open state (the locking element occupies its lower position), it is sufficient to lift the locking element by the left shoulder with the sash closed. In the process of lifting, the fixing holes of the code disc come close to the locking protrusions 12 of the locking rods 10 until they coincide with them when the locking element reaches a horizontal position. Freed from contact with the surface of the disk, the rods of the locking devices are retracted into the housings, ensuring the locking element is fixed with its fixing protrusions 12.

 To transfer the bolt from the open state to the closed one when leaving the locked room, with the leaf open, it is necessary to raise the left shoulder of the locking element slightly higher than the recess 17 in the leaf, lower it on the part of the stop element 19 protruding from the leaf, and close the leaf. When the sash is completely closed, this part of the thrust element moves into the recess 17, thereby removing the restriction on the return of the locking element to its lower positions. When the horizontal position is reached, the locking element is locked by the locking protrusions 12 of the rods 10 and remains in this position “closed” until the locking keys 7 and 8 of the magnetic keys 14 and 15 are inserted into the sensitivity zones.

 The result of the action of magnetic keys on the locking devices is the movement of the locking device rods, the output of the locking protrusions 12 from the holes of the code disk and, as a result, the locking element is moved to the lower position corresponding to the open state of the bolt.

 The bolt is removed from the closed state from the inside of the room also by moving the rods of the locking devices, but manually using 16 shafts for this.

 The bolt made in accordance with FIGS. 1-7 cannot always satisfy the requirement of mechanical strength due to incomplete overlapping of the leaf by the locking element along its width and the use of one locking device. It is possible to increase the mechanical strength of the bolt by installing (see Fig. 8, 9) an additional locking device 23 on the opposite rack of the frame (rack 24) and lengthening the locking element to a size that makes it possible to use both locking devices for locking the shutters (Fig. 8, 9).

 The use of a rotary bolt, which turns into a closed state when the sash is closed without affecting the sensitive part by the keys that control it, can lead to a situation critical for the user. If the user is the only key holder and before leaving the room, without making sure that he has the keys, slams the shutter, then he can return to the room only by breaking it.

 This situation can be avoided by providing a bolt in the design of the bolt, ensuring the translation of its locking element from the upper position to the horizontal on the outside of the sash with keys only.

 This principle of controlling the position of the locking element in the proposed deadbolt can be realized by supplementing the code part of the disk with an additional locking hole located coaxially with one of the locking devices contained in the deadbolt with the upper position of the locking element.

 An example of the implementation of the stated technical proposal can serve as an additional, shown in FIG. 6 by dashed lines, hole, fixing the locking element in the same position as the stop element 19.

 If there is an additional locking hole in the bolt, the rotation of the locking element from the upper to the lower position is possible only after the magnetic key is introduced into the sensitivity zone of the locking device 7. The procedure for removing restrictions on the rotation of the locking element from the upper position to the lower is similar to the procedure described above for removing the restriction on moving it from a horizontal position to a lower one. Since the deadbolt is closed when there is an additional locking hole on the code disk without using the stop element 19, there is no need to use it in the deadbolt.

 The level of secrecy of the proposed pivot bolt according to FIG. 1-9, is determined by the device of its sensitive part, presented in these drawings by the sensitive elements 11 of the locking devices 7 and 8.

 In cases where the level of secrecy of the bolt thus achieved is insufficient, it can be increased by complicating the algorithm for managing the bolt with keys, for example, by constructing it in such a way that the bolt goes from closed to open not after a single exposure to the sensitive part of the lock devices with keys, and after repeating this procedure repeatedly.

 You can implement this control algorithm, for example, if in the code disk of the proposed deadbolt, which has a combination of the essential features listed above, along the axial lines of the slots adjacent to the locking holes from the side opposite to the direction of rotation of the locking element (disk), additional (code) holes are made in an amount twice the number of cycles required for unlocking the deadbolt to affect the sensitive part of the locking devices by signals (keys) controlling their operation, and install on the code disk behind the back wall of each code hole in the direction of rotation, the locking elements in the form of, for example, pins with alternating installation on different sides of the disk through one code hole, adjacent to it, against the wall of the code hole.

 The formulated technical proposal is illustrated by drawings. are shown in FIGS. 10 and 11. FIG. 10 shows an inside view of a lockable room on top of a code disk with code holes and restriction pins made therein, and FIG. 11 shows a section of a code disk in plane A -A. The same figures show partially the contours of the elements of the locking device.

 Four code holes are made in the upper part of the disc. The number of code holes in the lower part of the disk is of no fundamental importance when considering the operation of the proposed deadbolt. In order to obtain more visual representations of the operation of the bolt, we assume that there are no code holes in the lower part of the disk 6 and it looks the same in its graphic representation as in FIG. 1, i.e. It has only one hole made in it - the fixing one.

 On the code disk 6, behind the wall in the direction of rotation of the disk (the direction of rotation of the disk is shown by an arrow), each hole, including fixing holes, is mounted close to it (the wall) (it can be threaded or by other means) two elements preventing the disk from turning in the form pins 25 with alternating their installation on opposite sides of the disk through one code hole. In the upper part of the disk, the first pair of pins 25 is mounted on the back side behind the rear fixing wall of the code disk along the rotation of the code disk. The next (left) of the two visible (in FIG. 10) pair of pins is installed from the inside of the locked room (the outer) side of the disk close to the back wall of the first code hole on the left. A third pair of pins 25 is mounted again from the back of the code disc, adjacent to the back wall of the second code hole on the left, etc. up to the installation of the fifth pair of pins, on the back of the disk behind the rear wall of the last fourth code hole.

 With the operation of the bolt in the process of translating it from a closed state, characterized by the horizontal position of the locking element 1 shown in FIGS. 10 and 11 and placing its ends in the internal cavities of the locking devices 20 and 23 into its open state, characterized by the complete withdrawal of the ends of the locking element from them, familiarize yourself by following only one of its stages identical in content. For example, during the first stage of operation of the magnetically-controlling deadbolt.

 At the very beginning of this stage, the locking protrusions 12 (figure 10, 11) of the locking devices 7 and 8 are located on the back side of the code disk (below it) and in contact with the first pair of locking pins 25 installed in the upper part of the disk and a single pair of pins, installed on the same side of the disk in its lower part, keep the disk from turning under the action of the force P. When introducing magnetic keys 14 and 15 into the sensitivity zones of the locking devices, their rods 10 are pulled out of the bodies 13 by a distance equal to their travel, as a result of which the locking you stupid are over 12 coded disc. The disk itself, freed from connections with the locking protrusions, will rotate by an angle corresponding to the distance along the symmetry axis of the slots between the centers of the code holes, and if the magnetic key is not removed from the sensitivity zone of the locking device 7, it will stop (Fig. 11b). If the magnetic key 14 during the rotation of the code disk was removed from this zone, then the rod 10 of the locking device 7 immediately after the contact of the locking lug 12 belonging to it with the second pair of locking pins 25 is retracted inside this locking device, moving the protrusion 12 under the code disk and thereby creating conditions for further rotation of the code disk 6 until the second code hole of the third pair of locking pins installed on the rear side behind the rear wall of the second code hole contacts the protrusion 12 of the locking device roystva 7.

 This completes the first phase of the bolt. The subsequent stages of its operation (in the bolt variant under consideration, the second stage) differ from the first only in that the locking device 8 is not involved in them, since the locking protrusion 12 of its rod 10, having left the code disk at the first stage of operation, is no longer falls down until the locking element 1 returns to its original horizontal position. If, after the ends of the locking element exit the cavities of the locking devices 20 and 23, it becomes necessary to transfer the locking element to the lowest position set for it, this is achieved by additionally introducing the magnetic key 14 into the sensitivity zone of the locking device 7 at the end of the final (in the case under consideration second) step deadbolt work.

 The same algorithm for controlling the bolt at the stage of transferring it from a closed state to an open one and the same positive effect from its implementation can be obtained if the code zones on disk 6 are performed similarly to the code zone of the rail described in (2), by positioning the code zones the holes on the disk are not along a straight line, but along arcs of circles that are the axis of symmetry of the slots made in it. However, the implementation of such a code zone is associated with the use of more complex and labor-intensive technological operations and high costs.

 Increasing the security of a deadbolt by making code holes in the disk, along with an obvious positive effect, manifested in increasing the security of transferring a deadbolt from a closed state to an open one, complicates the procedure for moving its locking element from a lower position to a horizontal one. When performing this procedure, it is necessary periodically after turning the bolt at an angle corresponding to the distance along the axial line of the slots between the centers of the code holes, manually lifting the locking protrusion 12 above the code disk, repeating essentially the whole set of effects on the rod of the locking device 7, which he experiences from the side magnetic key 14 when opening the deadbolt.

 This drawback can be eliminated by introducing additional devices into the deadbolt design with openings made in the code disk, which, during the process of transferring the deadbolt from the closed state to the open one, restrict the movement of the stopper rods, preventing the protrusions fixing them from entering beyond the code holes, and when moving the deadbolt locking element from the lower position to the horizontal one allows to remove these restrictions, thereby providing the possibility of withdrawing the fixing protrusions of the rods beyond th placement of the surface of the code disk. Naturally, in the case of the use of such (remote) devices, restricting the travel of the rods of the locking devices, the locking devices themselves can be performed without limiting the movement of the rods or with the restriction of their movement, but with a distance necessarily greater than the thickness of the code disk when measuring it along the tops of the locking pins. When executing the code area of the disk in accordance with (2), the stroke of the rods should be greater than the thickness of the disk.

 In FIG. 12 shows a general view of one of the design options of the remote limiter of the stop of the locking device and its section through a vertical plane passing through the axis of the locking device.

 The remote limiter of the stroke of the stopper rod is made in the form of a U-shaped bracket 26, which is fixed relative to the leaf 2 and encompasses the code disk 6, on which the locking device 7 is fixed on the side of the leaf and on the other wall is aligned with the fixing hole of the code disk a hole of the same or slightly larger diameter is made, closed by a spring-loaded (spring-loaded 27) washer 28 with a hole in its central part installed in a U-shaped bracket 26 fixed to the same wall 29, having a hole in the end wall facing the inside of the lockable room, coaxial with the hole in the washer and having a diameter equal to the diameter of the shank 16, of the stopper rod 7.

 The mutual arrangement of the elements of the locking device and the remote device for restricting the travel of the locking rod shown in FIG. 12 is characteristic of the closed state of the bolt and all the stable positions of the locking element that occur when moving it from a horizontal position to a lower position using magnetic keys. For all these positions of the locking element, as well as during its movement between them, the protrusion of the washer 29 (its cylindrical part is smaller in diameter) is located inside the hole in the wall of the bracket 26, and the washer 28 itself is firmly pressed against the wall of the bracket by a spring 27. For normal operation of the bolt with transferring it from a closed state to an open spring stiffness 27 must be selected so that the force transmitted from it to the washer 28 is significantly greater than the force acting on the lock washer from the opposite side after introducing into the sensitivity zone of the locking device 7 of the magnetic key 14.

 When this condition is met, the operation of the bolt containing the remote device for restricting the stroke of the stopper rod at the stage of its transfer from the closed state to the open one on the outside of the sash does not differ from the work of the deadbolt with the restriction of the stroke of the stopper bars by the locking devices themselves.

 To freely rotate the bolt locking element from the lower position to the horizontal and vice versa from the inside of the locked room, it is sufficient to use the shank of the stopper rod to move the locking protrusion 12 from the code holes of the disk 6 into the opening of the housing 28 of the stopper stroke limiting device, overcoming the counter spring 27, and keep it in the housing for the entire time the bolt moves. In this case, the movement of the locking element up is carried out manually, and vice versa without the participation of the user under the action of gravity of the locking element of the bolt. The locking bolt element is moved from the horizontal position to the upper position without hindrance, regardless of whether the locking protrusion of the locking rod is inside the housing 29 of the device for restricting its travel or outside this housing. It is only important that it is located above the code disk.

Sources of information
1. Patent of Russia 2002933, cl. E 05 C 3/04, 1993

 2. Patent of Russia 2099499, cl. E 05 B 47/00, E 05 C 17/56, 19/16, publ. 1997 year

 3. Patent SU 8710, cl. E 05 B 63/22, publ. 1929

Claims (5)

 1. The bolt is rotary, containing a locking element in the form of a rod mounted on the inner side of the sash with the possibility of rotation around an axis fixed to the sash with an offset of the center of gravity relative to it, as well as a locking and locking device located on the same side of the sash, characterized in that it contains a code disk mounted on the locking element concentrically to the axis of its rotation with fixing holes and slots made along circles concentric with the axis of rotation of the locking element and having a width well, a smaller diameter of the fixing holes, as well as controlled locking devices located on the leaf coaxially with the locking holes of the code disc and a stop element mounted on the leaf on the side of the locking device.  2. The bolt according to claim 1, characterized in that it contains an additional locking device mounted on the opposite rack of the frame, and a locking element elongated to a size that makes it possible to use both locking devices for locking the shutters.  3. The bolt according to claim 1 or 2, characterized in that it has an additional locking hole on the code disk coaxially located with the locking device at the upper position of the locking element.  4. The bolt according to any one of claims 1 to 3, characterized in that in the code disk along the axial lines of the slots adjacent to the locking holes on the side opposite to the direction of rotation of the locking element, additional code holes are made in an amount twice as large as required to unlock the bolt the number of cycles of action on the sensitive part of the locking devices by the keys controlling their work, and on the back along the rotation of the locking element, the walls of each code hole are fitted with barriers rotating the disc locking elements in the form of, for example, pins with alternating their installation on opposite sides of the disk through one hole code.  5. The bolt according to claim 4, characterized in that it contains remote devices to limit the stroke of the stopper rods, each of which is made in the form of a U-shaped bracket that is stationary relative to the leaf and encompasses a code disk, on which the locking device is fixed on one of its side walls and on the other, coaxial with it and the fixing hole of the code disk, a hole of the same or larger diameter is made, closed by a spring-loaded washer with a hole in its central part, mounted in a U-shaped mounted on the same wall a staple housing, with a hole in the end wall facing the inside of the locked room, coaxial with the hole in the washer and having a diameter equal to the diameter of the shank of the stopper rod.

Images