This application claims priority to South African Patent Application Number 2012/02067 that was filed on Mar. 20, 2012. The entire content of this application is hereby incorporated herein by reference.
This invention relates generally to a locking arrangement and an access control system.
The Inventor is aware that current access control systems often make use of electro-magnetic locking arrangements for granting access to access-restricted areas (e.g. to control access to expensive equipment which needs to be protected against unauthorised access, e.g. by potential thieves). The disadvantage however of electro-magnetic locks are that they have to be powered all the time; draw large currents (i.e. up to 3 amps); are expensive; relatively difficult to install; and relatively heavy.
It is an object of this invention to provide means which the Inventor believes will at least alleviate some of the above identified problems.
In accordance with one aspect of the invention there is provided a locking arrangement which includes:
a body;
a locking member which is displaceable relative to the body, the locking member defining at least one striker element engagement formation which is configured to engage a striker element for part of its displacement relative to the locking arrangement along a predetermined displacement path, the locking member being displaceable between first and second spaced apart positions in each of which the engagement formation is positioned such that a said striker element is releasably engageable therewith and between which a said striker element is in engagement with the engagement formation; and
a securing mechanism configured to secure the locking member releasably in at least one of the first and second spaced apart positions.
The locking member may be angularly displaceable relative to the body, and the at least one striker element engagement formation of the locking member may be configured to engage a striker element for part of its displacement along the predetermined displacement path, the locking member being angularly displaceable between the first and second positions, which are angularly spaced from each other, in each of which the engagement formation is positioned such that a said striker element is releasably engageable therewith and between which a said striker element is held captive in the engagement formation.
The locking member may be pivotally/rotationally connected to the body.
The locking member may include a first striker element engagement formation which is configured to engage a striker element for part of its displacement relative to the locking arrangement along a predetermined displacement path in a first displacement direction, wherein the locking member is configured to be displaced relative to the body, when the first engagement formation engages with the striker element and as the striker element is displaced relative to the locking arrangement further along the predetermined displacement path in the first displacement direction, away from its first position (hereinafter referred to as the “first locked position”), the locking member also including a second striker element engagement formation, which is either separate from, or forms part of, the first striker element engagement formation, the second engagement formation being configured to engage the striker element for part of its displacement relative to the locking arrangement along the predetermined displacement path in a second displacement direction, wherein the locking element is configured to be displaced relative to the body, when the second engagement formation engages with the striker element and as the striker element is displaced relative to locking arrangement further along the displacement path in the second displacement direction, away from its second position (hereinafter referred to as the “second locked position”).
The first and second engagement formations may be oppositely disposed relative to each other.
The first and second striker element engagement formations may be oppositely disposed relative to each other.
The locking arrangement may include a locating/limiting mechanism which is engageable with the locking member, at least at some stage, during displacement of the locking member relative to the body in order to limit the amount of relative displacement between the locking member and the body. More specifically, the limiting mechanism may be configured to limit the amount of displacement of the locking member, relative to the body, away from its first locked position. The locking arrangement may include a shaft which is rotatably mounted to the body and to which the locking member is connected such that rotation of the shaft causes rotation of the locking member. The limiting mechanism may include a first limiting member which is rotatably fitted over the shaft and rotatable relative to the body, and a second limiting member which projects/protrudes radially outwardly from the shaft and which is engeagable with the first limiting member, at least at some stage, during the displacement of the locking member between its first and second locked positions, in order to limit the amount of relative displacement between the locking member and the body. The limiting mechanism may include a securing element which is configured to secure and fix the first limiting member releasably relative to the body. The securing element may be a type of fastening means such as a screw. The second limiting member may include a stub formation.
The first limiting member may define a recess/cavity which extends along a circumference of the shaft and in which at least part of the second limiting member is located, the recess/cavity defining a path (hereinafter referred to as “path A”) along which the at least part of the second limiting member is displaceable, when the shaft is rotated relative to the first limiting member. The cavity/recess may extend along a circumference of the shaft.
A limiting formation may be located at at least one end, preferably both ends, of path A, in order to limit the amount by which the second limiting member (and shaft) can be displaced along path A, by engaging with the second limiting member when it reaches the corresponding end of path A. The first limiting member may have an annular disk-shaped body which defines an inner, elongate cut-out which, when the first limiting member is fitted over the shaft, extends along a circumference of the shaft and defines path A.
The locking arrangement may include a securing mechanism which is configured to secure the locking member releasably in the first locked position and/or the second locked position. The securing mechanism may include a securing member which is displaceable relative to the locking member between a secured position where the securing member secures, or releasably secures, the locking member relative to the body in the first and/or second locked positions and an unsecured position where the locking member is allowed to be displaced relative to the body. More specifically, when the securing member is in its secured position, it may releasably secure the locking member relative to the body in the first locked position and/or the second locked position, and the securing mechanism may include a fixing member which is displaceable relative to the securing member between a fixed position wherein the fixing member fixes the securing member in its secured position and a free position wherein the securing member is allowed to be displaced to its unsecured position. More specifically, the fixing member may be displaceable into engagement with the securing member for fixing the securing member in its secured position, thereby locking the locking member in its first locked position and/or its second locked position; and out of engagement with the securing member for allowing the securing member to be displaced to its unsecured position. The fixing member may be connected to an actuator or displacement arrangement, which may include a solenoid, which is configured to displace the fixing member out of engagement with the securing member from its fixed position towards its free position. The fixing member may be connected to the actuator via a lever. The lever may be a first order lever, wherein the fixing member and actuator are connected to the lever on opposite sides of a pivotal connection via which the lever is connected to the body or part of the locking arrangement which is fixed relative to the body. The fixing member may therefore be connected to one end of the lever and the actuator may be connected to an opposite end of the lever. A displacement path (hereinafter referred to as “path B”) of the fixing member as it is displaced into and out of engagement with the securing member may be substantially parallel to a displacement path (hereinafter referred to as “path C”) of the actuator as it actuates and displaces the fixing member. The fixing member and an actuator arm of the actuator may be substantially of the same (or similar) weight. The fixing member may be a lock pin.
The securing member may be configured to engage with a corresponding third engagement formation of the locking member, when the securing member is in its secured position. The securing mechanism may include a biasing means which is configured to bias the securing member towards its secured position. The securing member, when in its secured position, may extend, at least partially, into a recess or opening provided by the third engagement formation, the securing member therefore engaging with a wall(s)/surface(s) of the third engagement formation defining the recess or opening, and wherein the locking arrangement may be configured such that when the locking member is in its first or second locked position, the securing member is in register with the recess or opening of the third engagement formation, thereby allowing the securing member to extend into the recess or opening in order to secure the locking member releasably in its first or second locked position.
The wall(s)/surface(s) of the third engagement formation defining the recess or opening may taper as it leads into the locking member such that when the securing member is in its secured position and a sufficient amount of force/torque is applied to the locking member away from the first or second locked position, relative to the body, the securing member is urged towards its unsecured position as a result of the force acting thereon by the wall(s)/surface(s), against the bias of the biasing means. Therefore, when the securing member is in its secured position, it releasably secures the locking member in its first and/or second locked position, however, once a sufficient amount of force or torque is applied to the locking member, the locking member can be displaced out of its first and/or second locked position. However, when the securing mechanism includes a fixing member, and the fixing member is in its fixed position, the locking member is fixed in its locked position (be it the first or second locked position) and a force/torque applied to the locking member will therefore not force the securing formation into its unsecured position.
The first engagement formation may be configured to be displaceable in a plane as the locking member is displaced towards, or away from, its first locked position, and the securing member may be configured to be displaceable relative to the locking member along a securing path, which is oriented transverse to the said plane, between its secured and unsecured positions. More specifically, the securing path may be oriented substantially perpendicular to the plane. Alternatively, the first engagement formation may be configured to be displaceable generally in a plane as the locking member is displaced towards, or away from, its first locked position, and the securing member may be configured to be displaceable relative to the locking member along a securing path, which is oriented substantially parallel to the said plane, between its secured and unsecured positions.
Preferably, the locking member may be displaceable between its first and second locked positions and the locking member may therefore the third engagement formation with which the securing member engages when the locking member is in its first locked position and the securing member is in its secured position; and a fourth engagement formation with which the securing member engages when the locking member is in its second locked position and the securing member is in its secured position. The fourth engagement formation may be similar to the third engagement formation and may therefore have a recess or opening into which the securing member extends, at least partially, when the locking member is in its second locked position and the securing member is in its secured position, thereby engaging with a wall(s)/surface(s) of the fourth engagement formation defining the recess or opening. The locking arrangement may be configured such that when the locking member is in its second locked position, the securing member is in register with the recess or opening of the fourth engagement formation, thereby allowing the securing member to extend into the recess or opening in order to secure the locking member releasably in its second locked position. The locking arrangement may, in this case, include an insert which is insertable into one of the recesses of the third or fourth engagement formation for inhibiting the securing member from extending into the particular recess and therefore inhibiting the securing formation from securing the locking member into the particular locked position, be it the first or second locked position.
The locking member may include a first locking member element which defines the third and/or fourth engagement formations; and a second locking member element, which is connected to, but spaced from, the first locking member element, and which defines the first and second engagement formations. The first and second locking member elements may be interconnected by means of a shaft such that rotation of the shaft causes both locking member elements to rotate, the locking member elements therefore being angularly/rotationally displaceable relative to the body about an axis of rotation defined by the shaft.
The locking arrangement may be configured to engage with a second striker element to thereby create a type of dual-locking arrangement. The locking member may therefore include a third locking member element, which is configured in a similar fashion to the second locking member element, the third locking member element therefore including two engagement formations, namely a fourth and fifth engagement formation, which are configured to engage with a second striker element in a similar fashion to the first and second engagement formations located on the second locking member element. The third locking member element may be connected to the first and second locking member elements by means of the shaft.
In an alternative embodiment, the locking member may be slidably displaceable relative to the body, towards and away from, a first locked position. The locking member may be biased by a biasing means towards its first locked position. When in the first locked position, the first and/or second engagement formations of the locking member may be positioned in the displacement path (i.e. the relative displacement path between the locking arrangement and the striker element) and may therefore be configured to engage, at some stage, with a striker element when, in use, the locking arrangement and striker element are displaced relative to each other along the displacement path. When the striker element engages with the first or second engagement formation and is displaced further along the displacement path, the locking member is urged/forced, against the bias of the biasing means, away from its first locked position to thereby allow the striker element to pass. Once passed, the biasing means will return the locking member to its first locked position.
In accordance with another aspect of the invention there is provided a lock installation which includes:
a door which is displaceably mounted to the support structure and which is displaceable between a closed position in which the door closes off the access opening in order to prohibit access to the access-restricted enclosure, and an open position where the access opening is not closed off by the door, thereby providing access to the access-restricted enclosure through the access opening;
a locking arrangement which is mounted to one of the door and the support member; and
a striker element which is mounted to the other of the door and the support member, the locking arrangement and striker element therefore being displaceable relative to each other along a predetermined displacement path when the door is displaced between its open and its closed positions, wherein the locking arrangement includes
The locking member may be configured to allow the striker element to be spaced from, and therefore not in constant engagement with, the striker element engagement formation, when the locking member is in its first and/or second positions. The striker element may be displaceable between two extremities along its predetermined displacement path and the locking member may be configured to allow the striker element to be spaced from the striker element engagement formation when in one of its two extremities and only to engage with the striker element engagement formation when the striker element is displaced between its two extremities.
The locking arrangement may be a locking arrangement as defined above.
In accordance with a further aspect of the invention there is provided an access control system which includes:
a locking arrangement as defined above; and
a control unit which is connected to the locking arrangement and which is configured to receive an input from a user; determine whether, based on the input received from the user, access may be granted; and if so, to grant access by communicating with the locking arrangement to allow the locking member to be displaced, relative to the body of the locking arrangement, away from its first locked position.
More specifically, the control unit may be configured to communicate with the actuator or displacement arrangement of the locking arrangement for displacing the lock pin out of engagement with the securing member, when access is granted.
The invention will now be described, by way of example, with reference to the accompanying diagrammatic drawings. In the drawings:
In the drawings reference numeral 10 refers generally to a locking arrangement in accordance with the invention.
The locking arrangement 10 includes a body 12, a locking member 14, which is rotationally mounted to the body 12; and a securing mechanism 16.
The locking member 14 is rotationally mounted onto the body 12 by means of a shaft 15 and bearing arrangement generally indicated by reference numeral 13 (the bearing arrangement is not illustrated in detail). The locking member 14 defines a recess or cut-out 17 (see
The securing mechanism 16 includes a securing member 26, a fixing member in the form of an elongate lock pin 28, a displacement arrangement 30 and a biasing means 32. The securing member 26 has body 121 which can generally be divided into a circular cylindrical main body portion 122; a circular cylindrical operatively upper portion 125 which protrudes from an end of, and has a smaller diameter than, the main body portion 122; and an operatively lower portion 123 (see
The securing member 26 is therefore displaceable along the channel 34 between an unsecured position (shown in
The tapered surfaces 21.1, 21.2 of the locking member 14 defining the recesses 20.1, 20.2 of the third and fourth engagement formations 23.1, 23.2 and a complementary tapered surface of the operatively lower portion 123 of the securing member 26 function as a detent or cam arrangement. Accordingly, when a sufficient amount of angular force or torque is applied to the locking member 14, relative to the body 12 (about the axis 110), the securing member 26 is urged upwards towards its unsecured position, against the bias of the biasing means 32, due to the force(s) acting thereon by the tapered surfaces 21.1, 21.2 in the manner of a cam and follower. The securing member 26 therefore only releasably secures the locking member 14 into its first and second locked positions.
The lock pin 28 is displaceable into and out of engagement with the shoulder 40 of the securing member 26. More specifically, when the securing member 26 is in its unsecured position (see
In use, the locking arrangement 10 may form part of an access control system 200 (see
The card reader 204 is configured to read identification cards of users and to send the details thereof to the control unit 202 (see
Similarly, when the user wants to exit the restricted access area, the lock pin 28 may be disengaged from the securing member 26 via another card reader (not shown) which is positioned inside the access restricted area. With the lock pin 28 in its free position, the user may again push the door (in the opposite direction) which will cause the striker element 100 to engage with the second engagement formation 19.2, thereby displacing the locking member 14 towards its first locked position.
The locking arrangement 10 need not necessarily form part of a sophisticated access control system 200 but may also be operated by a simple switch.
By inserting an insert 24 into one of the recesses 20.1, 20.2 of the third or fourth engagement formations 23.1, 23.2, the locking arrangement 10 can be configured to be lockable in only one position, i.e. by inhibiting the securing member 26 from extending into a particular recess 20.1, 20.2 of one of the engagement formations 23.1, 23.2, the locking member 14 is inhibited from being locked into one of the two locked positions (see
If the locking member 14 constantly engages with the striker element 100, forces acting on the locking member by the striker element 100 (e.g. as a result of a door seal or a person pressing on the door) may end up being transferred to the securing member 26 which in turn may press against the lock pin 28. The lock pin 28 may therefore as a result require more force to be operated in order to disengage from the securing member 26, which would mean the use of a larger solenoid (which will draw larger current).
However, by using the locking arrangement 10 set out above, this problem is alleviated by the fact that the striker element 100 is disengaged from the locking member 14 when in its closed or open position. The lock pin 28 will therefore require less force to be operated which, in turn, means the use of a smaller solenoid.
In
The first locking member element 61.1 includes third, fourth and fifth engagement formations which are in the form of three angularly spaced recesses 92.1, 92.2, 92.3 which lead into the body 102.1 of the first locking member element 61.1 from a radially outer side thereof. The securing member 26 is positioned on the radially outer side of the first locking member element 61.1 such that when the locking member 14 is rotated about the axis 110, the recesses 92.1, 92.2, 92.3 of the third, fourth and fifth engagement formations will, at some stage, come into register, or in line, with the securing member 26.
The second and third locking member elements 61.2, 61.3 each defines two angularly spaced recesses 63.1, 63.2, 65.1, 65.2 which are similar to the recess 17 shown in
When, for instance, striker element 100.2 is displaced towards its open position, it engages the recess 65.1 and as a result rotates the third locking member element 61.3 (assuming that the lock pin 28 is in its free or unlocked position and a sufficient amount of force is applied to the third locking member element 61.3 to displace the securing member 26 towards its unlocked position) which causes the first and second locking member elements 61.1, 61.2 also to rotate to a position shown in
In
In
In this embodiment, the locking member 14 is mounted on a thick shaft 15 such that rotation of the shaft 15 about an axis 110 causes rotation of the locking member 14 (see
The locking arrangement 10 includes a first order lever 109 which is pivotally connected to the body 12 via a pivotal connection 111. One end of the lever 109 is connected to an actuator arm 113 of the displacement arrangement 30, while the other end of the lever 109 is connected to the lock pin 28 which is generally thicker than the lock pin 28 illustrated in
If the locking arrangement 10 illustrated in
The locking arrangement 10 includes a switch arrangement 127 which is configured to operate an operating light such as an LED 129 and which is operatively connected to the displacement arrangement 30 such that when the displacement arrangement 30 displaces the lock pin 28 out of engagement with the shoulder 40 (i.e. into its unlocked position), it causes the switch arrangement 127 to power the LED 129.
An operating device 201 can be used, to operate the locking arrangement 10 in a key-like fashion (see
When the solenoid 37 is not powered, the actuator arm 113 is locked in an extended/erect position. As a result, the lever 109 urges/forces the lock pin 28 into its locked position. When the correct operating device 201 is inserted into the receiving device 203, the receiving device 203 establishes (e.g. by means of a switch) an electrical connection between the power source 205 and the solenoid 37. As soon as the solenoid 37 is powered, it displaces the actuator arm 113 from its extended/erect position towards a retracted position (i.e. the actuator arm 113 is displaced in the direction of arrow 133 along the displacement path 115). As a result, the lever 109 urges/forces the lock pin 28 out of engagement with the shoulder 40 of the securing mechanism 16 into its unlocked position, thereby allowing the locking member 14 to rotate (e.g. to open a door to which the locking arrangement 10 is mounted) by applying a sufficient amount of torque/rotational force on the shaft 15 and locking member 14 (as described earlier in the specification). The actuator arm 113 is operatively connected to the switch arrangement 127 such that when the actuator arm 113 is in its extended/erect position, a switch 189 of the switch arrangement 127 is in an open condition (i.e. the LED 129 is disconnected from the circuit 207) and when the actuator arm 113 is displaced towards its retracted position, to switch the switch 189 to a closed condition, thereby connecting the LED 129 to the circuit 207 (and power source 205).
The locking arrangement 10 defines a light transmitting rod 139 which extends from the LED 129 towards an outer side of the body 12 and which is configured to channel the light from the LED 129 towards the outside, which can then be viewed by an operator. The light from the LED 129 will therefore be indicative that the correct operating device 201 has been inserted into the receiving device 203 and that the locking pin 28 is in its unlocked position.
From the above, it is clear that the locking arrangement 10 does not require a power source to ensure that a door to which the locking arrangement 10 is mounted remains locked. The locking arrangement 10 in fact only requires power in order to unlock the locking pin 28 of the locking arrangement 10. (The operating device 201, receiving device 203 and circuit 207 can also be implemented in the other embodiments of the locking arrangement 10 described above.)
The locking arrangement 10 further includes a limiting mechanism 191 which is configured to limit the amount of rotation of the locking member 14 and shaft 15 relative to the body 12. More specifically, the limiting mechanism 191 is configured to help preserve/maintain the relative rotational position of the locking member 14 relative to the body 12, when the locking member 14 has been displaced into a fully open position. The limiting mechanism 191 includes a first limiting member 143 which has an annular disk-shaped body 171 which is rotatably fitted over the shaft 15 and which is rotatable relative to the body 12. The limiting mechanism 191 also includes a second limiting member in the form of a stub formation 149 which projects/protrudes radially outwardly from the shaft 15.
The first limiting member 143 defines an inner, elongate cut-out 147 which, when the first limiting member 143 is fitted over the shaft 15, extends along a circumference of the shaft 15. The cut-out 147 defines a path 151. The stub formation 149 is located in the cut-out 147 and can therefore move along the displacement path 151 as the shaft 15 (and locking member 14) is rotated relative to the first limiting member 143. The limiting mechanism 191 further includes a securing element in the form of a screw which can be used to secure the first limiting member 143 to the body 12 in a specific relative rotational position.
The relative rotational position can be determined by displacing the striker element 100 along its displacement path from a closed position towards an open position such that it, at some stage, engages with the locking member 14 by extending into the recess 17 (which is positioned in the displacement path of the striker element 100) and rotates the locking member 14 (as well as the shaft 15) until the striker element 100 disengages from the locking member 14 (more specifically the recess 17). When the locking member 14 is in this position it is in a fully open position. As the locking member 14 is rotated towards its fully open position, the securing member 26 will at some stage be displaced out of its secured position inside the recess 93 and into its unsecured position where it abuts a radially outer surface 181 of the shaft 15. As the shaft 15 rotates, a portion 161 of the body 171, which defines one of the ends of the path 151, engages, at some stage, with the stub formation 149, which causes the first limiting member 143 to rotate together with the shaft 15. When the locking member 14 has been rotated into its fully open position, the screw is inserted via an access hole 155 in order to engage frictionally with an annular surface 157 of the body 171 to thereby prevent relative rotation between the first limiting member 143 and the body 12 in the same direction. The screw, when inserted, is oriented generally perpendicular to a plane in which the annular surface 157 extends. The insertion of the screw is conducted during the installation of the locking arrangement 10.
If, when in its fully open position, the locking member 14 is inadvertently rotated back towards a closed position such that the recess 17 is displaced out of register with the displacement path of the striker element 100, then the striker element 100, when displaced back along its displacement path towards its closed position, will engage a radially outer side 199 of the locking member 14 instead of the recess 17. In order to correct the rotational position of the locking member 14 it can merely be rotated manually (relative to the body 12) towards its fully open position until the locking member 14 cannot rotate any further as a result of the screw and the portion 161 which engages with the stub formation 149, which prevent further rotation in the same direction. When the locking member 14 reaches this position, it will be in its fully open position and the recess 17 will be in register with the displacement path of the striker element 100. The screw, together with the portion 161 and stub formation 149, also helps prevent the locking member 14 from being inadvertent rotated past its fully open position.
The lock installation 400 illustrated in
The door frame 402 defines an access opening 408 through which access is granted to an access-restricted enclosure/area of which the door 404 and door frame 402 form part of. The door 404 is hingidly displaceable relative to the door frame 402 between a closed position in which the door 404 closes off the access opening 408 in order to prohibit access to the access-restricted enclosure/area through the access opening 408, and an open position where the access opening 408 is not closed off by the door 404, thereby providing access to the access-restricted enclosure/area through the access opening 408.
The Inventor believes that the invention provides both a cost effective locking arrangement and access controlled system. The Inventor also believes that the locking arrangement 10 is relatively easy to install and inexpensive. The locking arrangement 10 also draws significantly less current than current electro-magnetic locks the Inventor is aware of, i.e. 300 mA versus 5 A, which is largely due to the fact that the striker element 100 is not in constant engagement with the locking member 14.
A further advantage of this invention is the fact that in the embodiment illustrated in
Number | Date | Country | Kind |
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2012/02067 | Mar 2012 | ZA | national |