Electronic locking device

Abstract

An electronic locking device including a cylinder and a plug located in the cylinder. Within the plug is a solenoid with a pair of shuttles which move in opposite directions. A control processor controls the solenoids activating the shuttles when connected to the correct key. Blocking elements for each shuttle are inserted through the cylinder and into annular channels in the plug. The blocking elements receive and allow linear movement of the shuttles but prevent their rotation within the annular channels. In a locked condition the shuttles are contained only partially within the annular channels thereby preventing rotation of the plug within the cylinder but in an unlocked condition the shuttles are contained within the annular channels thereby allowing rotation of the plug. The plug also includes a weakness defining a point at which it will break upon application of excessive force.

Claims

1. An electronic locking device comprising: a cylinder defining a cylindrical space; a plug received in said cylindrical space, said plug including at least one annular channel formed therein; at least one solenoid including at least one shuttle movable between a first and a second position; at least one control device for receiving a signal from a key and selectively activating said at least one solenoid in response to a correct said signal; at least one blocking element inserted into said cylinder, said at least one blocking element extending into said cylindrical space and into said at least one annular channel, said at least one blocking element receiving and allowing linear movement of said at least one shuttle and preventing rotation of said at least one shuttle within said at least one annular channel, wherein in a locked condition said at least one shuttle is contained only partially within said at least one annular channel thereby preventing rotation of said plug within said cylinder and in an unlocked condition said at least one shuttle is contained within said at least one annular channel thereby allowing rotation of said plug within said cylinder.

2. An electronic locking device according to claim 1, further comprising at least one cam rotatable with said plug.

3. An electronic locking device according to claim 1, further comprising a plurality of blocking elements and said at least one solenoid comprises a plurality of shuttles.

4. An electronic locking device according to claim 1, wherein said cylinder comprises a euro-cylinder.

5. An electronic locking device according to claim 1, wherein said plug comprises at least one weakness defining a point at which said plug will break upon application of excessive force and wherein a cam is located partially along the length of said cylinder thereby dividing said cylinder into a first portion and a second portion, wherein said at least one solenoid is located in one of said first and second portions and said at least one weakness is located in the other of said first and second portions.

6. An electronic locking device comprising a cylinder; a plug received in said cylinder, said plug including at least one weakness defining a point at which said plug will break upon application of excessive force; at least one solenoid including at least one shuttle movable between a first and a second position thereby switching the locking device between a locked and an unlocked condition; at least one control device for receiving a signal from a key and selectively activating said at least one solenoid in response to a correct said signal; at least one cam rotatable with said plug when the locking device is in said unlocked condition, said at least one cam is located partially along the length of said cylinder thereby dividing said cylinder into a first portion and a second portion, wherein said at least one solenoid is located in one of said first and second portions and said at least one weakness is located in the other of said first and second portions.

7. An electronic locking device according to claim 6, wherein said cylinder comprises a euro-cylinder.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) Preferred embodiments of the present invention will now be described, by way of example only, and not in any limitative sense with reference to the accompanying drawings in which:

(2) FIG. 1 is a perspective view of a locking device of the present invention;

(3) FIG. 2 is an exploded perspective view of the locking device of FIG. 1;

(4) FIG. 3 is a sectional perspective view along the axis of the locking device showing the device of FIG. 1;

(5) FIGS. 4 to 7 are perspective from below, side, top and perspective from above views of a blocking element which is a component of the locking device of FIG. 1;

(6) FIG. 8 is a schematic sectional view perpendicular to the axis of the locking device (section taken along the line A-A in FIG. 10) including the component shown in FIGS. 4 to 7; and

(7) FIGS. 9 and 10 are sectional views along the axis of the locking device showing the device of FIG. 1 in locked and unlocked conditions respectively.

DETAILED DESCRIPTION

(8) The following description of the preferred embodiment(s) is merely exemplary in nature and is in no way intended to limit the invention, its application, or uses.

(9) Referring initially to FIG. 1, an electronic locking device 10 includes a cylinder 12 and a plug 14 and in the embodiment shown in FIG. 1 these are in the form commonly referred to as a euro cylinder. The locking device 10 is operated using keys, a portion of which are indicated at 16 in FIGS. 1, 2, 9 and 10 and shown more completely in FIG. 3. The keys include a power supply, a signal generator and one or more connectors for transferring the power and signal to the locking device 10. When in an unlocked condition, the locking device 10 rotates a cam 18 which acts on a further element or elements of a door, window or the like (and which are not shown) in a manner familiar to person skilled in the art.

(10) With additional reference to FIGS. 2 and 3, the cylinder 12 defines a cylindrical space 20 into which the plug 14 is located. Because the cylinder 12 is in the euro cylinder form the cam 18 divides the cylindrical space 20 into a pair of such spaces on either side of the cam. The plug 14 is substantially cylindrical in its shape, that is its radially outermost dimensions fit within the cylindrical space 20 and when the plug 14 is formed with its associated components the plug assembly can be inserted into the cylindrical space 20 from one end.

(11) The device 10 further includes a solenoid 22 which is positioned coaxially with an axis of rotation 24 of the plug 14. The solenoid 22 as a pair of shuttles 26 and 28 which contain magnets 30 and 32. The shuttles and their associated magnets operate at either end of the solenoid 22 in opposite directions to each other. In other words, when power is supplied to the electromagnet within solenoid 22 the magnets 30 and 32 of shuttles 26 and 28 are repelled in opposite directions.

(12) Formed as part of the plug are a pair of annular channels 34 and 36 which extend at least partially around the axis 24 of plug 14. The annular channels 34 and 36 are sized to receive and contain the shuttles 26 and 28 respectively. As a result, when the shuttles 26 and 28 are within the annular channels 34 and 36 the plug 14 can rotate around axis 24 without the shuttles 26 and 28 rotating. The channels 34 and 36 are defined by circular walls 34a and 34b and by 36a and 36b respectively, with walls 34a and 36a being those immediately adjacent the solenoid 22 therefore being the innermost walls with respect to the solenoid. In both of those innermost walls 34a and 36a a notch is formed which is sized to allow the shuttles 26 and 28 to pass therethrough. These notches are hereinafter referred to using the reference numerals 34c and 36c although in the figures only notch 34c can be seen in FIG. 2.

(13) Formed into the cylinder 12 are a pair of apertures 38 and 40 into which extend a pair of blocking elements 42 and 44. The blocking elements 42 and 44 are shown in more detail in FIGS. 4 to 7 and are substantially cylindrical in their form. The purpose of the blocking elements 42 and 44 is to receive the shuttles 26 and 28 by allowing the linear movement of the shuttles in response to power being supplied to the solenoid 22. However, the shape of the upper ends of the blocking elements 42 and 44 prevent the shuttles 26 and 28 rotating within the annular channels 34 and 36 when the plug 14 rotates within the cylinder 12. Detail of this upper end is shown in FIGS. 4 to 8 and indicated with reference numeral 46. In particular, the upper end 46 is shaped as though formed with an aperture extending perpendicular to the main cylindrical body 48 having a radius similar to the radius of the curve which forms the body 48. The body 48 is not perfectly cylindrical and has flat portions 50 which prevent the rotation of the blocking elements 42 and 44 within the apertures 38 and 40 which are shaped to match and receive the blocking elements. The upper end 46 of the blocking element 42 has a curved top surface 52 which end in tips 54 at the very top of the blocking element. When correctly located in the cylinder the bottommost portion of the curved surface 52 is approximately aligned with the radially outermost edge 56 of the annular channel 34. This outermost edge of the annular channel coincides with the outer surface of the cylindrical space 20. Because the bottom of curved surface 52 is aligned with the outermost edge 56 of the annular channel 34 the tips 54 of blocking element 42 extend into the annular space 34.

(14) The locking device 10 further includes a control device in the form of a processor which is located in the space indicated at 58 in the figures. The processor 58 receives a signal from either of the keys 16 and determines whether to activate the solenoid 22.

(15) The cylinder 12 and plug 14 are provided with weakness portions respectively indicated at 60 and 62. In the embodiment shown in the figures these weaknesses are in the form of slits cut into the cylinder 12 and plug 14. The purpose of these weakness portions is to ensure that if a strong mechanical force is applied to the outside of the locking device 10 (that is the left-hand end in FIGS. 2, 9 and 10 and the right-hand end in FIGS. 1 and 3) that the cylinder and/or plug break at this point. In the locking device 10 the cam 18 is fixed to the plug 14 so that rotation of the plug also rotates the cam. The cam 18 can be regarded as dividing the cylinder 12 into two portions with the weakness portions being located in one portion and the locking mechanism, that is the solenoid, blocking elements and the annular channels, being in the other portion. As a result, simply breaking the cylinder and/or plug will not allow the device to be unlocked as the shuttles 26 and 28 of the solenoid 22 will remain an activated and therefore in the locked condition.

(16) A protection plate 64 is located in slit 60. The protection plate 64 is formed from a material, such as hardened steel, which is harder, or more resistant to an attack by a tool such as a drill, than the material of the cylinder 12 (which is typically brass or stainless steel). The protection plate 64 is held in place by an additional blocking element 66 which is associated with a respective aperture 68 (similar to apertures 38 and 40) and a respective annular channel 70 (similar to channels 34 and 36). Alternative components could be used to fix the protection plate in place.

(17) Operation of the locking device 10 will now be described with particular reference to FIGS. 9 and 10. FIG. 9 shows the locking device 10 engaged with key portions 16. In the normal operation of the locking device 10 only a single key is required to unlock the device. In FIG. 9 the solenoid 22 is not activated and the magnets 30 and 32 of the shuttles 26 and 28 are attracted to the iron core which forms part of the solenoid 22 and, as a result, the shuttles 26 and 28 but the ends of the solenoid 22. The locking device 10 is therefore in a locked condition meaning that the plug 14 is unable to rotate within the cylinder 12 thereby also preventing movement of the cam 18. This prevention of rotation of the plug 14 within the cylinder 12 results from the shuttles 26 and 28 extending only partially into the annular channels 34 and 36. This in turn means that the shuttles 26 and 28 extend into the notches 34c and 36c in the walls 34a and 36a. As a result, when a turning force is applied to the plug 14 the edge of notches 34c and 36c engage and press against their respective shuttles 26 and 28. Rotational movement of the shuttles is in turn prevented by the shuttles pressing against the curved surface 52 of the blocking elements 42 and 44.

(18) The power supply for the locking device is contained within the key 16 and when the key engages the end portion of the plug 14 power and a signal is sent to the processor 58 along wires which are not shown. The power results in activation of the processor which compares the signal to determine whether it is the correct signal for that lock. If the signal is correct the processor further uses the power to activate the solenoid 22 which creates a magnetic field. The magnets 30 and 32 in shuttles 26 and 28 are aligned so as to be repelled by this magnetic field therefore moving away from the solenoid 22 and into the annular channels 34 and 36. The shuttles 26 and 28 therefore no longer extend into the notches 34c and 36c and the plug 14 is no longer prevented from rotating within the cylinder 12. Because the curved surface 52 is shaped to fit shuttles 26 and 28, the shuttles cannot rotate with the plug 14 as it turns. The power from the key 16 only activates the solenoid 22 for a short period of time, typically 2 seconds, which is sufficient time for the operator to apply a turning force to the plug 14 whilst the solenoid is pushing the shuttles 26 and 28 into the annular channels 34 and 36 (as shown in FIG. 10). After this period of time, when the solenoid is no longer receiving power the magnets 30 and 32 in shuttles 26 and 28 are no longer repelled from the solenoid 22 and are indeed attracted to the ferrous core of the solenoid. However, the innermost walls 34a and 36a prevent the shuttles re-engaging with the solenoid until the plug is rotated back to its starting position and the notches 34c and 36c are aligned with the shuttles. Once these components are realigned the shuttles 26 and 28 will pass back into the notches 34c and 36c thereby returning the locking device 10 to its locked condition.

(19) It will be appreciated by persons skilled in the art that the above embodiments have been described by way of example only and not in any limitative sense, and that various alterations and modifications are possible without departure from the scope of the protection which is defined by the appended claims. For example, in the embodiment described above the annular channels 34 and 36 extend around the whole of the circumference of the plug 14. However, the channels need only extend as far as the rotation of the plug in normal operation of the locking device requires. The channel extending around the whole of the circumference of the plug allows the plug to rotate through 360 or more and is easier to manufacture than a partial annular channel.