This application is a national stage filing under 35 USC §371 of International application number PCT/IB2006/003600, filed Dec. 13, 2006, which claims priority to South African application number 2005/10146, filed Dec. 13, 2005.
This invention relates to a lock and to an electromechanical locking system.
The wide deployment of electromechanical locking devices is in part hampered by the power requirements and size of the actuation mechanisms needed to effect unlocking of such electromechanical locking devices. In order to unlock an electromechanical locking device, the locking device requires an actuator which is operable to move a mechanism within the locking device in response to an electrical signal being received from the locking device's electronic control unit. This electrical signal typically causes the actuator to either release a blocking pin which enables a user to turn or slide a mechanism in order to extract a bolt or it may exert sufficient power to extract the bolt without mechanical assistance from a user's hand. In the latter case, the locking device would typically have to be supplied with external power from a mains power supply which restricts the field of application of such locking devices.
An electromechanical locking device which relies upon the strength of a human hand to extract the lock bolt consumes much less power and can be operated by battery-powered sources thereby widening the field of application of such devices. However, existing electromechanical locking devices typically include a locking mechanism in the form of a blocking device which prevents the mechanical component to which a user has access from moving unless an actuator has received an actuation signal from the control unit of the locking device to release the blocking mechanism. As the blocking mechanism is vulnerable to brute force attack in which sufficient strength may be applied to the lock causing the blocking mechanism to fail, such blocking mechanisms are designed to withstand large external forces and as a result are relatively large and heavy. Consequently, the strength requirements of such blocking mechanisms imposes a burden upon the actuators which are required to release such blocking mechanisms, thereby increasing the actuator size and power consumption. This limits the practicality of using battery powered sources for lock actuation. A further problem with such electromechanical locking devices is related to the time it takes to perform lock actuation. Typically, a user should be able to insert a key and open a lock without perceptible delay. To accomplish this, the actuator needs to be relatively fast in its operation. The actuator must also not stick in the event that the user begins to exert a force against the lock before the actuator has had time to release the lock. Such speed and absence of sticking are difficult to accomplish with a relatively heavy blocking device.
It is an object of the present invention to ameliorate the above-mentioned limitations of electromechanical locking devices.
According to the invention there is provided a lock comprising:
The locking mechanism may include second urging means for urging the locking member into engagement with the first and second locking formations.
The clutch mechanism may be housed within the cylinder.
The electronic control means may be housed within the cylinder.
The locking member and the blocking member may define common axes of rotation which are common to the axes of rotation of the cylinder and the tailpiece.
The first urging means may be in the form of a compression spring.
The locking member may be located rearwardly of the blocking member, the locking member being of relatively higher mass than that of the blocking member and the second urging means applying a sufficiently low urging force to the locking member so that if an external shock is applied to the lock in a longitudinal direction from the front end of the cylinder towards the tailpiece sufficient to cause the locking member to be displaced rearwardly into disengagement with the first and second locking formations, the blocking member will only be displaced from its blocking position at a relatively higher acceleration, thereby preventing coupling of the cylinder and the tailpiece.
The invention extends to an electromechanical locking system including a key having an electrical power source and a lock as defined hereinabove.
Further features of the invention are described hereinafter by way of a non-limiting example of the invention, with reference to and as illustrated in the accompanying diagrammatic drawings. In the drawings:
With reference to the drawings, a lock in accordance with the invention is designated generally by the reference numeral 12. The lock 12 is configured for use with a key 14. The lock 12 and the key 14 together forming an electromechanical locking system 8. The lock 12 has a front end 10 and a rear end 11 and includes a cylinder 16 which is rotatably mounted to a first component to be locked, an electronic control unit 18 which is housed within the cylinder, a tailpiece 20, a clutch mechanism 22 which is housed within the cylinder 16 and a tailpiece adapter 24. The tailpiece adapter 24 is connected to a lock bolt (not shown) or other conventional locking device which interferes with movement of a second component to be locked to the first component.
The key 14 comprises a metal split key blade 26 which is split into two key blade portions 26.1 and 26.2 and a key body 28. The key blade portions 26.1 and 26.2 provide for a 2-wire electrical contact with the lock 12. The key blade thus provides a means by which electrical power, data and mechanical effort is transmitted to the lock 12. The key blade portion 26.1 is notched on one or both sides thereof with pyramidal notches in a manner similar to a conventional key. The key body contains a SIM smart card in which an authorisation code can be stored and a printed circuit board which supports the key's electronics. The electronics of the key consists of a power regulator, a micro-controller supporting the lock protocol and power management functions. The key body further includes a battery supplying power to the key and lock electronics. A button 27 is provided which permits a user to selectively input data to the lock 12.
The lock 12 is sized so as to provide a drop-in replacement for conventional mechanical cylinder locks. It will be appreciated that the electromechanical locking system may be used in any application wherein a lock may be required. The cylinder 16 and the tailpiece 20 are of plastics material and are coupled to one another in an arrangement wherein the cylinder and tailpiece are rotatable relative to one another in a disengaged condition of the lock 12. In an engaged condition of the lock, the cylinder 16 and the tailpiece 20 are releasably connected to one another by the clutch mechanism, thereby causing the tailpiece and the cylinder to be rotatably coupled.
The cylinder 16 comprises a cylinder casing 29 and a key housing 30 which is fixedly connected to the cylinder casing 29 by means of a cylindrical spigot formation 31 which fits into a socket 32 defined by the cylinder casing. The spigot formation 31 defines a pair of annular ridges 33 and the socket defines a pair of complementary annular grooves 34 in which the ridges are received, providing a snap joint. The key housing defines a keyway 35 in which the key blade 26 is received. The key housing 30 includes two electrical contacts 37 which each comprise a pair of wiping contacts which make electrical contact on opposite sides of each of the two key blade portions. The wiping contacts for each key blade portion ensure that an adequate electrical connection is maintained between the lock and the key from the point of entry of the key blade 26 into the keyway 35, providing at least 150 μs during which the authorisation process may take place before the key is fully inserted and the user starts to turn the key. The contacts 37 are connected to the control unit 18 via electrical connectors 21.
The key housing 30 further includes a key blade locking pin 23 of a conventional design which interacts with the groove 23.1 in the key blade portion 26.1, preventing the key blade from being withdrawn from the key housing 30 when the cylinder 16 is rotated. A second cylinder locking pin 25 interacts with an annular groove 9 within the key housing 30 preventing the cylinder 16 from being displaced axially and thereby removed from the lock.
The cylinder 16 is rotatably connected to the tailpiece 20 by means of an annular snap joint wherein the cylinder casing 29 defines three annular ridges 36 and the tailpiece 20 defines three complementary annular grooves 38 which receive the ridges 36 in an arrangement permitting rotation of the cylinder relative to the tailpiece. As such, the cylinder and the tailpiece define common axes of rotation.
The control unit 18 includes electronic control means in the form of an electronic key interface which provides an electrical connection with the key blade 26 of the key 14 and for data transmission between the key 14 and the lock 12. When electrical contact is made between the key and the key interface, the key supplies a pulse of electrical power to the lock 12. The control unit 18 includes a power capacitor which releases sufficient electrical power to the lock enabling it to operate for a short period of time and to communicate with the key via the two-wire bus between power pulses using a Manchester bit-encoding scheme. The control unit 18 includes a microcontroller which is connected to the clutch mechanism 22 and the key interface and which is operable to send an actuation signal to the clutch mechanism for actuating the clutch mechanism.
The clutch mechanism 22 comprises a 0.3 mm thick silicone steel cup 40, a locking member in the form of a coupler 42, a coil 46 and a cylindrical Neodymium magnet 48 which contacts the steel cup 40 at a rear end of the magnet and which is partially located within the coil 46 at the front end of the magnet. The clutch mechanism 22 further includes a blocking member in the form of a bobbin 50 which is displaceable over the magnet 48 and which is acted upon by urging means in the form of a 5 mN bobbin return spring 52. The spring is a compression coil spring. Electrical wires (not shown) extend from the coil 46 via holes 54 in the steel cup 40 to the control unit 18 for energising the coil.
With reference to
With reference to
With reference to
In the assembled condition of the clutch mechanism 22, the rear end of the coupler 42 abuts the front end of the tailpiece 20, with the bobbin, having the coil 46 wound thereon, being located within the coupler, the assembled clutch mechanism being received within the cylinder casing 29. With reference to
With reference to
The coil 46 has a resistance of 300Ω drawing 6.67 mA at 2V. The coil is fixedly coupled to the bobbin 50 which permits it to be slid over the front end of the magnet 48. The force generated by the coil 46 ranges from 10.7 mN to 12.7 mN as the coil is displaced across its operating range of 1.3 mm (see
The cup 40 has a baseplate 41 defining two electrical wire channel holes 54 and a cylindrical side wall 58 which extends from baseplate 41. The cup 40 serves three functions: firstly, to conduct the magnetic flux from the far pole of the magnet 48 across the coil 46, which increases the coil force by about 30%; secondly, to prevent excessive magnetic flux from escaping which may interfere with other devices and/or attract metallic particulate matter; and thirdly, to provide protection against external magnetic interference. The bobbin return spring 52 is seated between the baseplate 41 of the cup 40 and the coil 46.
With reference to
When received within the casing 29, the ribs 86.1 and 86.2 are received within the circumferential spaces 78.1 and 78.2, respectively. As such, when the cylinder casing 29 is caused to rotate in an anti-clockwise direction (viewed from the rear end of the lock), the abutment faces 92.1 and 92.2 are brought into abutment with the ribs 86.2 and 86.1, respectively, thereby permitting a torque which is applied to the cylinder casing 29 to be transmitted to the coupler 42.
The casing 29 defines a number of locating formations 87 at its front end for locating and connecting the key housing 30 thereto.
In the inactivated (home) condition of the clutch mechanism 22, the bobbin 50 is located within the coupler 42 in an arrangement wherein the front end of the boss 66 of the coupler is received within the aperture 57 of the bobbin.
In an uncoupled condition of the lock, the cylinder 16 is not engaged by the clutch mechanism and thus not coupled to the tailpiece 20. As such, when the key housing 30 is rotated by the key, the cylinder 16 rotates in synchrony with the key housing 30 but the tailpiece 20 and thereby the tailpiece adapter 24, is left unmoved.
In use, when the key 14 is inserted into the keyway in the key housing 30 and the code communicated to the control unit 18 is authenticated, an energy pulse is sent from the key to the control unit energizing the coil 46 thereby to actuate the clutch mechanism. The bobbin 50, actuated by the coil 46, is impelled into the steel cup 40. With reference to
With reference to
The coupler is lifted off the tailpiece 20 (see
An essential requirement for the clutch is that it must not be possible to engage it by means of external acceleration or shock, and this is accomplished in the following manner. The mass of coupler 42 is balanced by a torsion spring 96 which extends between curved step formations 98.1 and 98.2 extending inwardly from the wall sections 68.1 and 68.2 of the coupler, and the step formation 88 of the cylinder casing. As such, when the clutch mechanism is accelerated from the front end of the lock towards the tailpiece 20 at an acceleration exceeding 3 g, the coupler 42 sinks into the cylinder casing. The bobbin 50 and coil 46 are relatively light and as such, will only sink into the cup 40 against the force of the spring 52 at a relatively higher acceleration. For all accelerations, the bobbin 50 thus rests on the coupler in its blocking position, and any attempt to turn the cylinder will result in the clutch mechanism being disengaged.
When subjected to rapid shock or violent vibration, however, the motion of the bobbin with respect to the coupler is mostly random. In this event, the coupler bounces up and down along the cylinder casing. With reference to
In addition to longitudinal shock the cylinder could be subjected to angular shock, in which event the force of the torsion spring could be overcome, causing the cog to become re-engaged. However, there is no theoretical limit to the strength of the torsion spring that can be employed, and the slopes of the engaging faces 74.2 and 76.2 can be correspondingly adjusted to compensate for the friction on the slopes to ensure that the shock response of the coupler remains un-affected when torqued by the torsion spring. Even with a relatively weak torsion spring, it proves in practice to be exceedingly difficult if not impossible to engage the clutch mechanism by means of external shock alone.
A design target is to minimize the turn angle required from the home position to the point at which the clutch mechanism engages; usually a lock set requires this turn to be less than 35°. This is accomplished, firstly, by making the angular width of the bobbin blocking cogs 60.1 and 60.3 as small as is compatible with mechanical requirements; and, secondly, by employing slanted retreating faces 88.4 and 88.5 of the guide arms 88.1 and 88.2 of the cylinder casing 29. The retreating faces are angled such that when the bobbin 50 is lifted up the guide column, the bobbin faces 60.5 and 60.6 on the bobbin guide cogs 60.2 and 60.4 interact with the retreating faces 88.4 and 88.5 to cause the bobbin to rotate in a clockwise direction as seen from the rear end of the lock. This rotation brings about an additional clearance between the engaging faces 62.1 and 62.2 on the bobbin and the engaging faces 71.1 and 71.2 on the cog, permitting the engaging faces to be partially engaged prior to actuation of the coil and consequently requiring a smaller turn before the clutch mechanism is engaged.
The clutch mechanism 22 may include a clutch actuation position indicator mechanism which is operable to notify the microcontroller of the control unit 18 when the clutch mechanism is in a position to be actuated. The clutch actuation position indicator mechanism is facilitated by a formation within the cylinder which generates a small clicking sound that is detectable as a voltage spike in the coil 46. The microcontroller is operable to generate an actuation signal in response to the voltage spike being detected by the microcontroller.
The benefit of such a mechanism is that the power need only be applied to the actuator when the user starts to turn the cylinder, thereby prolonging the key's battery life. In practice however the key's power consumption is dominated by the standby current required by the key's electronics, and such mechanisms are therefore optional in a real-world application.
It will be appreciated that the exact configuration of the lock and of the key may vary greatly while still incorporating the general principles of the invention described hereinabove. In particular, the applicant envisages that engagement of the cylinder and tailpiece can be achieved by means other than cogs, such as ball bearings, pins, ratchets, toothed wheels or friction-engaging members all of which are comprehended by the above invention. The exact configuration of the clutch mechanism may also vary while still incorporating the essential features defined herein.
The application of the clutch mechanism may be extended to any application for which a clutch is required and for which speed, low power consumption, low cost and shock resistance are important requirements. Possible application areas include robotics, valves, and power distribution in toys or other mechanical devices.
Number | Date | Country | Kind |
---|---|---|---|
2005/10146 | Dec 2005 | ZA | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/IB2006/003600 | 12/13/2006 | WO | 00 | 12/23/2008 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2007/069047 | 6/21/2007 | WO | A |
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20090308119 A1 | Dec 2009 | US |