DE3208818A1 - Lock - Google Patents

Abstract

The electrical lock, suitable especially for doors or windows, comprises a manually actuable bolt (1). A blocking member (2) moved by an electrical driving device (5) blocks the bolt (1) in at least one of its closing positions. To read off the locking code of a key (11), there is an electrical reading and control device (7, 9) which controls the driving device (5). The driving device (5) and the reading and control device (7, 9) are connected to a mains-independent voltage store (15) which is charged by a generator (19) operable independently of the mains. If a dynamo-electric generator is used, this is driven by means of the opening and closing movement of the door, of the door handle, of the lock or of the key. Electromagnetic or piezoelectric sound transducers for air or structure-borne sound or photoelectric or thermoelectric transducers can also be employed for generating the charging current of the voltage store (15). <IMAGE>

Description

Lock

The invention relates to a lock, in particular for a door or a window with a manually lockable bolt and one with a key lockable locking device for blocking the bolt in at least one of its Closed positions.

Mechanical locks of this type, for example cylinder locks have a lock cylinder rotatably or longitudinally displaceably mounted in a housing which takes the key in a key slot and the actual bolt of the lock via a nose or the like when turning the key manually takes away. Mechanical tumblers are provided as locking devices, which are in notches or the like of the key and release the cylinder when the lock code of the key matches that of the lock.

The number of possible combinations that can be achieved with mechanical locks of locking codes is comparatively low. Let higher combination numbers reach each other.

if the key's locking identifier is through electrical reading devices is read and evaluated. In known electric locks one controls Reading and control device, the drive device of the lock bolt. As the power consumption such drive devices is relatively large, such locks must be attached be connected to the power grid or the like. When using electrical Locks for locking doors or windows result in problems with the power supply.

The object of the invention is to provide a network-independent, which Specify the lock identifier of his key that reads electrically.

This object is achieved according to the invention in that the locking device at least one locking member for moving by an electric drive device has the manually lockable bolt that for reading a lock identifier of the Key is an electrical reading and control device that controls the drive device is provided and that the drive device and the reading and control device to a network-independent voltage storage device and / or one that can be operated independently of the network Generator are connected. With such a lock, the lock identifier of the Key is read and monitored electrically. Such reading and control devices have very little power consumption. Also the power requirement of the drive device is low, because not the bolt, but only its locking element is electrically driven will. The actual bolt of the lock is moved manually. The electricity demand the reading and control device and the drive device are derived from a voltage memory or a generator that has no long supply lines in the area of the lock can be arranged.

The generator is preferably a manually drivable, dynamo-electric generator that works with one when opening and / or Closing the door or window and / or when locking or unlocking the lock and / or inserting or removing the key manually moved part coupled is. The generator can do this with a door or window handle or the hinge The door or the window can be coupled, for example, via a gear drive. as well the generator can be controlled via the rotary movement of the lock cylinder or via the linear Insertion movement of the key are driven. Here, too, are expedient Gear or rack and pinion transmission used.

In embodiments that can also be used when the door or door is locked.

Window enable the generator to be driven, for example at The generator is driven by the door or window handle or by the key, the current of the generator can be used directly to operate the reading and control device or the drive device are used.

However, the generator preferably drives a charging circuit of the voltage storage device, which is a capacitor or, better still, an accumulator or the like acts.

In other embodiments, the generator can be electromagnetic or piezoelectric sound transducer, which is designed in the manner of a microphone responds to airborne noise or structure-borne noise. Photoelectric ones are also suitable Converters, for example photocells or the like, when irradiated with light create a tension. As far as temperature differences can be exploited, thermoelectric converters can be used.

The drive device for the movement of the locking bolt The blocking element is preferably designed as an electromagnet, the blocking element either forms the armature of the electromagnet or is coupled to it. Because the locking organ The drive device can become difficult to move due to corrosion and contamination advantageously designed as a piezoelectric transducer element. Such Transducer elements generate high actuation forces with comparatively low electrical drive energy. In order to achieve sufficiently large strokes of the locking member, this is expedient Via a step-up gear, in particular a step-up lever gear coupled to the transducer element.

The drive device is preferably designed so that they Lock member can drive in two opposite directions of movement. This reading and control device gi-bt depending on the agreement or non-agreement the read locking ID with a predetermined locking ID different Signals to unlock or lock the bolt to the drive device. For the two opposite directions of movement can be separate electromagnets or piezoelectric transducer elements may be present; but it can also be an and the same electromagnet or a single piezoelectric transducer element with voltage different polarity are applied. The locking member is from the drive device driven into one of two end positions, in which there are locking organs or Holding magnets or the like is locked.

In another embodiment, the drive device drives that Lock member only in a single, predetermined direction of movement. In the in the opposite direction of movement, the locking element is biased by a return spring. Depending on whether the locking member is in the rest position determined by the return spring locks or unlocks the bolt, the reading and control device releases the drive device off if the key's locking ID matches the specified locking ID of the lock matches or does not match.

The reading and control device is used to actuate the drive device preferably one current pulse each away. The duration of the current pulse is dimensioned so that the locking member moves from one rest position to the other will. As far as the locking member by a return spring in a locking the bolt End position biases, the reading and control device holds the locking member above it in addition, for the duration of the manual movement of the bolt in the unlocked position.

The reading and control device can use the lock identifier of the key scan mechanically by means of electrical switching contacts. The switching contacts can here indirectly via pins of notches, depressions or knobs of the key controlled, or the key has conductive or non-conductive areas, which together with brushes or the like form the switching contacts. In other In embodiments, the key can be magnetic or optical information elements have which the reading and control device scans in a contactless manner. Additionally to the locking identifier scanned by the reading and control device can also a lock identifier that can be scanned by mechanical tumblers of the lock is provided be.

The lock is preferably a cylinder lock in a housing by means of a rotatable cylinder the actual bolt of the lock. The locking element locks the cylinder relative to the housing. However, the invention is not limited to such embodiments. For example the locking member can block a longitudinally displaceable core that carries the bolt or it drives the bolt.

In the following, embodiments of the invention will be based on Drawings are explained in more detail. It shows: FIG. 1 a block diagram of an electrical, mains-independent electric lock operated by a local generator for a door or a window; 2 to 5 different embodiments with a dynamo-electric, manually driven generator; 6 shows a dynamoelectric Generator in which the key of the lock is part of the generator; 7 and 8 are schematic sectional views of two in the circuit of FIG. 1 usable cylinder locks; 9 to 12 partial views of the drive devices of other electric locks according to FIG. 1 and FIG. 13, a schematic representation a magnetically coded key with associated reading device.

Fig. 1 shows schematically a directly or indirectly manually displaceable Bolt 1 of a lock, in particular a door or window lock, which by means of a locking member 3 can be locked in one or more of its closed positions is. The blocking element 3 is dependent on an electric drive device 5 of a control signal from a controller 7 either in its locked position in which it locks the bolt 1 against manual movement or its unlocked position in which the bolt 1 is manually movable controls. The controller 7 speaks to that Signal from an electrical reader 9, which the locking identifier of a key 11 scans either mechanically by means of electrical contacts or the closing code reads contact-free with magnetically or optically coded keys.

Depending on the design of the lock, the control unit unlocks or locks 7 the bolt 1 if the lock identifier of the key 11 with a predetermined Lock identification of the lock matches or does not match.

The drive device 5, the controller 7 and the reading device 9 are connected to a common, network-independent, local voltage source 13. The voltage source 13 comprises a voltage store 15, for example a chargeable one Accumulator or a capacitor, which via a rectifier circuit 17 of a generator which is also arranged locally, that is to say in the vicinity of the lock 1 19 is loaded. A voltage regulating circuit connected downstream of the voltage memory 15 21 ensures a constant voltage regardless of the state of charge of the voltage store 15 Output voltage.

Such an electric lock has high locking security due to the electrical coding of the locking identifier and is at the same time locally independent, similar to a mechanical lock.

Fig. 2 shows the arrangement of a dynamo-electric generator, the charging current for the voltage store of the electric lock according to Fig. 1 generated. A dynamo-electric generator is attached to a door leaf 23 of a door 25 attached, the drive pinion 27 with a fixed gear segment 29 a Door hinge 31 combs. The generator 25 generates during manual opening and closing the door electricity. The generator 25 can of course be arranged in a stationary manner and are driven by a toothed segment connected to the door leaf 23.

Another dynamo-electric generator 33 is via a transmission 35 in drive connection with a lock cylinder 37 or core of a by means of a Key manually lockable door lock. Turning the key will turn the one hand a bolt 39 of the lock is moved and, on the other hand, the generator 33 is driven. The generators 25 and 33 can be used together to charge the voltage store of the electric lock be present; however, it is only sufficient in individual cases a single of these generators.

Fig. 3 shows another embodiment in which a dynamoelectric Generator 41 via a gear train 43 by the pivoting movement of a door handle 45 is driven. Alternatively, the drive movement of the generator can also be carried out by any other rotating, swiveling or sliding element can be caused on the door.

Fig. 4 shows a drive pinion 47 of a dynamo-electric generator, which protrudes into a key channel 49 and one with teeth 51 into the key channel 49 insertable key 53 of the lock combs. When manually plugging in or Removing the key 53 drives the generator.

Fig. 5 shows a drive pinion 55 of a dynamo-electric generator, which meshes with a rack 57. The rack 57 is one in the longitudinal direction Key channel 59 against the action of a compression spring 61 when inserting a key 63 movable. The generator is activated when the key 63 is inserted into the key channel 59 manually driven. When the key 63 is removed, the compression spring 61 drives the generator.

6 shows an induction coil 65 which has a key channel 67 or a yoke (not shown) ending on both sides of the key channel 67. In the key channel 67 there is at least one magnet held on a key 69 71 can be introduced which, when being pushed in or pulled out, generates a current in the coil 65 induced. In this embodiment, the key 69 is part of the generator.

Fig. 7 shows a cylinder lock with a housing 73 and one therein rotatable core or cylinder 75. An eccentric nose 77 or the like drives A sliding bolt via a link opening 79 or a cam or the like 81.

By means of a flat key which can be inserted into a key receiving slot 83 85, the sliding bolt 81 can be moved manually and the lock locked or unlocked will.

Radially displaceable probe segments 87 are resilient in the housing 73 guided through the circumferential slots 89 of the cylinder 75 in the keyway 83 intervention. The key segments 87 divided in the present exemplary embodiment key the key lock identifier determined by notches 91 of different depths 85 off and actuate switching contacts 93, if the locking ID of the key 85 matches the lock identifier. The switching contacts 93 form an electrical reading device, which has a pulse generator circuit, not shown Emits drive pulses to piezoelectric elements 95 and 97, respectively. The at feed a drive pulse pushing expanding piezoelectric elements 95 and 97, respectively a lever 99 which at its free end has a locking cam facing the cylinder 75 101 carries, in opposite directions. The locking cam 101 engages in his the end position closer to the cylinder 75 in a latching recess 103 on the circumference of the cylinder 75 and locks it. The cylinder is in the other end position 75 rotatable. Snap-in magnets 105 resp.

107 hold the at least in the area of these magnets made of ferromagnetic Material existing lever 99 in its end positions. The piezoelectric Element 95 is energized by a pulse when the lock is locked is not fulfilled, for example when removing the key 85 or when inserting it of a key with an incorrect locking ID. When inserting the key with a suitable closing identifier, the piezoelectric element 97 is activated by means of a Pulse excited, which the lever 99 in its cylinder 75 releasing position presses. Alternatively, a magnet can also be attached to the lever 99, which with ferromagnetic wall areas of the housing 73 cooperates.

With the aid of the piezoelectric elements 95, 97, relative achieve high levels of actuation that too when dirty or can safely lock or unlock clamping locking cam 101. The piezoelectric Elements 95, 97 are arranged relatively close to the pivot axis 109 of the lever even with a small change in the dimensions of the piezoelectric elements 95, 97 one to achieve a sufficiently large stroke of the locking cam 101.

The lock of Fig. 7 is operated exclusively by the electrically Locking cam 101 locked. Fig. 8 shows a cylinder lock, which is additionally through mechanical guard locking is blocked. In a housing 111 is in turn rotatable a cylinder 113 is arranged, which via an eccentric cam 115 or the like moves the lock bolt.

A flat key is in a key channel 117 of the cylinder 113 119 can be inserted, the notches 121 of which control spring-loaded tumbler pins 123. The tumbler pins 123 divided in a conventional manner allow rotation of the cylinder 113, if the mechanical locking identifier of the key 119 with the mechanical locking code of the lock matches. In addition to the mechanical Tumblers are in accordance with the lock of FIG. 7 scanning segments 125 in the housing 111 out resiliently displaceable. The scanning segments 125 feel further notches of the Key 119 and close with a matching lock code electrical Contacts 127. Another electrical contact 129 on one of the mechanical tumblers 123 responds when the correct key has been inserted completely.

In the housing 111, a lever 131 is at one end thereof around a Pivot axis 133 pivotally mounted. The lever 131 carries at its other end a locking cam 135 facing the cylinder 113, which is used to lock the cylinder 113 can engage in a recess 137 on its circumference. A return spring 139 biases the lever 131 so that the locking cam 135 in the rest state from the recess 137 disengages. A piezoelectric element 141, which one is close the pivot axis 133 is arranged, expands when a drive signal is supplied off, whereby the locking cam 135 engages in the recess 137.

The lock of FIG. 8 is normally operated by the mechanical tumblers 123 locked. If a key 119 is introduced, the locking identifier of which is the mechanical locking identification of the lock is fulfilled, but not the electrical, in this way the piezoelectric element 141 is energized and the lock is electrically locked. When the key 119 is removed, the contact 129 ensures that the piezoelectric Element 141 is not energized and does not consume power.

Fig. 9 shows another embodiment in which in a housing 143 of a cylinder lock has a lever 145 at one end about a pivot axis 147 is pivotally mounted. The lever 145 contributes one to its other end a rotatable lock cylinder 149 facing locking cam 151, which is from a biasing spring 153 biased to engage in a latching recess 155 on the circumference of the lock cylinder 149 is. A piezoelectric element arranged in the vicinity of the pivot axis 147 157 pushes the locking cam 151 out of the recess 155 when energized. Not closer an electrical reader is shown, which reads the locking code of an in a key channel 159 scans an insertable key. So much for the locking code of the key matches the lock ID of the lock, generates a Control a drive pulse of predetermined duration that the piezoelectric element 157 is supplied. The lock cylinder 149 is unlocked for the duration of the pulse and can be moved manually to unlock the lock.

Fig. 10 shows a detail of a cylinder lock, which in his Housing 161 an electromagnet 163 with radially movable to a lock cylinder 165 Includes anchor 167.

The armature 167 is from a biasing spring in the direction of the lock cylinder 165 too biased and carries a locking cam at its end on the lock cylinder side 171, which engages in a recess 173 on the circumference of the lock cylinder 165. One Reader, also not shown, scans the lock identifier of an in a key slot 179 of the lock cylinder 165 inserted from the key generates an excitation current pulse that can be fed to the electromagnet 163 when the closing code on the key matches the lock identifier. The electromagnet 163 attracts armature 167 for the duration of the excitation current pulse and unlocks it the lock cylinder 165. During the duration of the excitation current pulse, the Lock can be opened or locked.

Figures 11 and 12 show a further embodiment of a Cylinder lock with a housing 181 in which a key receiving core 183, which in turn moves the lock bolt, is rotatably mounted. One radial Locking pin 185, which is mounted displaceably in the housing 181 in relation to the core 183, is of a spring 187 is biased against the jacket of the core 183. At least in the closed positions of the core 183 there are provided domes 189 tapering to the shell surface, into which the locking pin 185 engages. A lever 191 is also located in the housing 181 about an axis running approximately parallel to the sliding direction of the locking pin 185 193 pivoted. One on the side of the llebel191 remote from the locking pin on the housing 181 attached in the area of the pivot axis 193 piezoelectric element 195 presses when energized, the lever 191 in a locking recess 197 of the locking pin 185. The Locking recess 197 is arranged so that the locking pin 185 is in the locking trough 189 locked and the core 183 is thus secured against rotation. A return spring 199 pushes the lever 191 out of the locking recess when the piezoelectric element 195 is de-energized 197. The core 183 can thus be rotated, whereby the inclined surfaces of the locking trough 189 push the locking pin 185 out of the locking trough.

In the exemplary embodiments explained above, the bolt moved manually by means of the key inserted in the lock cylinder. Other Embodiments are also conceivable, in particular those in which the key only carries the locking code, but the manual movement of the bolt over other organs, such as knobs, push handles or the like executed will. In particular, it can be provided that the locking cams are directly in the Engage the bolt and do not block the lock cylinder acting on the bolt.

Fig. 13 shows a magnetically encoded key 201, whose in a key slot 203 of a reader 205 insertable shaft 207 in one the locking identifier-forming grid magnets 209 carries, which are from magnetic field probes, for example liallgenerators 211 or reed contacts can be read. The key 201 can be used to generate a manual closing movement of the bolt; but it can also be designed in the form of a 'plug-in card'.

Claims (27)

Lock patent claims lock, in particular for a door or a Window, with a manually lockable bolt (1; 81) and one with a key (11; 53; 63; 69; 85; 119; 181) lockable locking device (3, 5; 95, 97, 101; 135, 141; 151, 157; 163, 171; 185) to block the bolt in at least one of its Closed positions, thereby indicated that the locking device at least one of an electric drive device (5; 95, 97; 141; 157; 163; 195) moving locking member (3; 101; 135; 151; 171) for the manually lockable Bolt has that for reading a locking code of the key an electrical, reading and control device (7, 9; 87, 93; 125, 127; 191) is provided and that the drive device and the reading and control device to a network-independent voltage store (15) and / or one that can be operated independently of the network Generator (19; 25, 33; 41; 65) are connected. 2. Lock according to claim 1, characterized in that g e k e n n z e i c h -n e t, that the generator as a manually drivable, dynamo-electric generator (25, 33; 41; 65) is formed. 3. Lock according to claim 2, characterized in that g e k e n n z e i c h -n e t, that the generator (25, 33; 41) with one when opening and / or closing the door (23) or the window and / or when locking or unlocking the lock and / or Insertion or removal of the key is coupled manually moving part. 4. Lock according to claim 3, characterized in that g e k e n n z e i c h -n e t, that the generator (41) with a door resp. Window handle (45) is coupled. 5. Lock according to claim 3, characterized in that g e k e n n z e i c h -n e t, that the generator (25) is coupled to a hinge (31) of the door (23) or the window is. 6. Lock according to claim 3, characterized in that g e k e n n z e i c h -n e t, that the generator (33) with a lock cylinder (37) of the lock, preferably whose core is coupled. 7. Lock according to claim 3, characterized in that g e k e n n z e i c h -n e t, that the key (53) has a rack (51; 57) displaceable in the insertion direction drives or forms with a drive pinion (47; 55) of the generator if necessary Engagement of a gear meshes. 8. Lock according to claim 1, characterized in that g e k e n n z e i c h -n e t, that the key (69) for the formation of the generator carries a magnet (71), the Introduction or Withdrawal is moved relative to an induction coil assembly (65). 9. Lock according to claim 1, characterized in that g e k e n n z e i c h -n e t, that the generator (19) as an electromagnetic or piezoelectric sound transducer or designed as a photoelectric converter or as a thermoelectric converter is. 10. Lock according to claim 1, characterized in that g e k e n n -z e i c h n e t, that the generator (19) is connected to a charging circuit (17) for the voltage store (15) is. 11. Lock according to claim 1, characterized in that g e k e n n z e i c h -n e t, that the drive device is designed as an electromagnet (163). 12. Lock according to claim 1, characterized in that g e k e n n z e i c h -n e t, that the drive device as a piezoelectric transducer element (95, 97; 141; 157) is trained. 13. Lock according to claim 12, characterized in that g e k e n n z e i c h -n e t that the piezoelectric transducer element (95, 97; 141; 157) via a transmission gear, in particular a translating lever mechanism (99; 131; 145) with the locking member (101; 135; 151) is connected. 14. Lock according to claim 1, characterized in that g e k e n n z e i c h -n e t, that the drive device moves the locking member (101) in two opposite directions of movement drives and that the reading and control device (87, 93) is dependent on the match or mismatch between the read locking code and a specified locking code different signals for unlocking or locking the bolt (81) to the drive device (95, 97) gives. 15. Lock according to claim 1, characterized in that g e k e n n z e i c h -n e t, that the drive device (141; 157; 163) the Blocking element (135; 151; 171) drives in a predetermined direction of movement and that a return spring (139; 153; 169) biases the locking member in the opposite direction of movement. 16. Lock according to claim 15, characterized in that g e k e n n z e i c h -n e t that the return spring (139) the locking member (135) in the unlocking the bolt Direction biases that the lock is additionally mechanical, by means of the key (119) has lockable tumblers (113) and that the reading and control device (125, 127) drives the drive device (141) in the reverse direction when the read Lock identifier deviates from a specified lock identifier. 17. Lock according to claim 15, characterized in that g e k e n n z e i c h -n e t that the return spring (153; 169) the locking member (151; 171) in the locking the bolt Direction biases and that the reading and control device, the drive device (157; 163) drives in the unlocking direction, if the read locking identifier with a specified locking code matches. 18. Lock according to one of claims 14 to 17, characterized in that g e k e n n z e i c h n e t that the reading and control device (7, 9) for actuating the Drive device each emits a current pulse. 19. Lock according to claim 1, characterized in that g e k e n n z e i c h -n e t, that the reading and control device has electrical switching contacts (93; 127), which mechanically scan the key's locking ID. 20. Lock according to claim 1, characterized in that g e k e n n z e i c h -n e t, that the key (181) has magnetic (189) or optical information elements, which scans the reading and control device (191) without contact. 21. Lock according to claim 1, characterized in that g-e k e n n z e i c h -n e t, that it is designed as a cylinder lock whose in a housing (73; 111; 143; 161) rotatable, the key receiving cylinder (75; 117; 149; 165) the bolt (81) drives and can be locked on the housing by the locking member (101; 135; 151; 171) is. 22. Lock according to claim 1, characterized in that g e k e n n z e i c h -n e t, that the key (11) in addition to that of the reading and control device (125, 127) scanned locking identifier is one of mechanical tumblers (113) of the lock includes scannable locking identifier. 23. Lock according to claim 14 or 15, characterized in that g e k e n n -z e i c h n e t that the locking member (-101) at least one stabilized by a locking member Has end position. 24. Lock according to claim 23, characterized in that g e k e n n z e i c h -n e t that as a locking member at least one permanent magnet (105, 107) is provided, the one ferromagnetic anchor piece (99) is assigned. 25. Lock according to claim 1, characterized in that g e k e n n z e i c h -n e t, that the locking member (131) is designed so that it is de-energized or defective Drive device (141) or reading and control device in its releasing the bolt Position. 26. Lock according to claim 1, characterized in that g e k e n n z e i c h -n e t, that the locking member (191) moved by the drive device (195) is an oblique to the direction of movement extending control and locking surfaces (189) of the bolt or a part (183) coupled to the bolt, in particular the movable part Locking member (185) blocked. 27. Lock according to claim 26, characterized in that it is not possible to use it that the locking member (185) is movably mounted in the housing (181) of the lock and from a spring (187) against one with at least one inclined locking trough (189) provided surface of the bolt or a part (183) coupled to it is prestressed is and that the locking member (197) the locking member (185) in the in the locking trough (189) engaging position locked positively.