FR2600369A1 - CLUTCH MECHANISM, IN PARTICULAR FOR ELECTRONIC LOCK - Google Patents

Abstract

THE INVENTION RELATES TO CLUTCH MECHANISMS. IT RELATES TO A CLUTCH MECHANISM 1, 2 FOR USE IN AN ELECTRONIC LOCK. IT CONSUMES MINIMUM ELECTRONIC CURRENT, BY USE OF MECHANICAL ENERGY TO OPERATE THE LOCK. A CAM DEVICE 20, 21 COOPERATES WITH A MOTION SENSOR 40, 42 AND WITH A SHUTTER 11 CONTROLLED BY AN ELECTRO-MAGNET 15. APPLICATION TO THE CONTROL OF DOOR LOCKS.

Description

The invention relates to a clutch mechanism,

  especially for electronic locks.

  The arrival of microprocessor logic circuits and their possibility of operation with very low power consumption has given rise to a large number of remote control applications in which it is not possible in practice to use energy from a source other than batteries. In these operations, it is essential that the energy consumed be

  reduced to a minimum and as a result, that the decision-making time of the microprocessor is extended.

  It has been found that such an application consists of electronic locks with combinations of type that can be reprogrammed. The use of a battery-powered microprocessor eliminates the need for door wiring and further allows the use of such locks in remote locations, where energy is not readily available. A problem so far has been the amount of energy required to put the locking mechanism into operation when the

  microprocessor decided that this operation was suitable.

  U.S. Patent No. 4,526,256 discloses a clutch mechanism which may be considered

  as a mechanism whose invention is an improvement.

  The present invention relates to a clutch mechanism which consumes only a very small current, by using, in part, mechanically applied energy and facilitating the engagement position of the clutch mechanism, and a combination of a set of a locking electromagnet and a motion sensor, synchronized operation, and a mechanical shutter that can be released. the invention therefore relates to a clutch mechanism which requires a very low current for

  operate, when a clutch control command corresponding to a decision has been received.

  The invention also relates to a simple, reliable and cost-effective clutch mechanism. It also relates to a clutch mechanism that can be used in combination with a microprocessor logic circuit in many applications.

  It also relates to a clutch mechanism for use with a combination electric lock that can be powered by a battery.

  More specifically, the invention relates to a clutch mechanism for an electronic lock or the like, and comprising a first rotary clutch element mounted so that it can freely rotate about a spindle and with respect to the latter, this element having a first jaw member, a second clutch member, mounted so that it can move in translation along the spindle and rotate in common with the spindle and having a second member. jaw member for cooperating with the first jaw member to rotate one of the clutch elements as a result of the rotation of the other clutch members, a device placed between the elements clutch and normally retaining them at a distance from each other, a device for elastically pushing one of the clutch elements so that it moves towards the other of the clutch elements, the rotation of one of the clutch elements, so that the jaw elements come into cooperation, a device for selectively preventing the movement of the first clutch element towards the other, so that the first and the second second jaw member can not cause cooperation and rotation of the first clutch member as a result of rotation of the other clutch member, the improvement comprising a locking device incorporated in the device for selectively preventing the clutch member from rotating. moving the first clutch element, a timing device for releasing the latching device, and a motion detection device for otherwise releasing the device

locking.

  Other characteristics and advantages of the invention will emerge more clearly from the description which follows,

  with reference to the accompanying drawings in which: Figure 1 is an exploded perspective of the locking mechanism according to the invention, applied to a lock; FIG. 2 is a side elevation showing, in solid lines, the internal clutch plate, the cam contact, the contact block, the return springs and the return arms, the latter being represented in cooperation with the plate. internal clutch, and in broken lines, the cam and the touch pad, in position displaced or pushed back by cam effect; Figure 3 is a left side elevation of the device of Figure 2 in which however the inner plate of the clutch is shown in phantom; and FIG. 4 is an electronic diagram showing the relationship between the synchronized lock function

  and the motion detection function according to the invention.

  Figures 1 to 4 show a clutch mechanism according to the invention, incorporated in a door lock mechanism. The door lock mechanism is intended to be used with a microprocessor-based or other logic decision or logic mechanism which provides for the energization of a locking electromagnet such as

  that the electromagnet 15 shown in Figure 1.

  It is necessary that the amount of energy consumed, necessary for the operation of the electromagnet 15, is minimal. It is also necessary that the clutch mechanism which provides the connection between the external handle and the spindle, derives its operating energy essentially from the rotation of the external handle. In addition, it is necessary that the engagement of the clutch mechanism allows the rotation of the operating pin of the lock, by the external handle. The lock can be of any convenient or conventional configuration that implements a controlled spindle

  manually for the operation of the locking mechanism.

  Reference is now made to Figure 1; the clutch mechanism according to the invention comprises an external clutch plate 1 mounted so that it rotates around a cylindrical portion of an external pin 7. During assembly, the external clutch plate 1 is not free

  to move axially in translation along the external broach 7.

  An outer handle 5 in the form of a spout 10 is shown attached to the outer clutch plate 1 so that it rotates with it under the control of a device not shown. It should be noted that the outer handle can be manufactured as part of the outer plate 1

  clutch or can be attached thereto by any convenient device.

  The outer clutch plate has a set of opposing outer jaws 3 and a maneuvering cam 21

  placed at the outer periphery of the outer plate 1.

  A cooperating internal clutch plate 2 is mounted on an inner pin 8 of square section. The internal clutch plate 2 rotates with the pin 8 and can move freely in translation along the axis of the spindle from an internal position to an external position in which a female member 4 complementary jaw coo25 father with the organ 3 forming an outer jaw. It will be appreciated by those skilled in the art that the rotation of the outer handle and outer clutch plate does not cause rotation of the outer pin, and that the inner pin does not rotate until the inner clutch plate is rotated. 30 not moved outward and as long as the elements

  additional jaw clutch does not cooperate.

  After being put in cooperation, the internal pin 8 can be

turned by the external handle 5.

  A coil spring 10 is placed around the outer pin 7 and is partially centered in a cavity

  formed in the face of the outer plate 1 clutch.

  The role of the coil spring 10 is to repel elastically

  the clutch inner plate 2 out of the outer plate 1. A mounting plate 9 constitutes a base of

  positioning of the lock mechanism.

  FIG. 1 is an exploded view of the mechanism according to the present invention and it should be noted that, after assembly, the face 31 of the outer plate 1 of clutch is very close to the outer face of the mounting plate 9 or is contact of the latter, the outer clutch jaws being concentric with the hole 32 of the mounting pla10 and partially penetrating into this hole. The diameter of the periphery of the internal clutch plate 2 is slightly smaller than the diameter of the hole 32, so that it can penetrate into the hole and allow the setting

  cooperation of the jaw elements.

  A shutter 11 is shown mounted on the plate 9 via a shutter pin 12. The mounting allows the shutter 11 to rotate about the axis 12. An abutment pin 16 fixed in the mounting plate 9 and protruding outwardly thereof enters a rectangular channel 33 formed in the housing. shutter 11 so that it limits the rotation of this shutter. As shown in FIG. 1, the shutter is in its release or upper position which allows the inner clutch plate to come into contact with the outer clutch plate. Those skilled in the art may also note that the shutter can be rotated counterclockwise as shown in FIG. 1, and in this position it partially blocks the hole 32 and is

  contact of the inner clutch plate which passes through the hole 32.

  The position of the shutter 11 is controlled by the electromagnet 15. The position shown in Figure 1 is the controlled or release position. A clutch spring 17 pushes the shutter 11 to turn counterclockwise to the locking or contact position when the electromagnet 15 is

  not excited. The core of the electromagnet is connected to the obturator

  11 by an axis 14 of electromagnet.

  The mechanism that pushes the inner clutch plate toward the outer clutch plate consists essentially of five elements, a cam pad, a paddle 23, return springs 24, return arms, and a spool. 26. These various elements, in their position of cooperation after assembly, are represented

in Figures 2 and 3.

  The spool 26 is fixed to the inner clutch plate 2 and is free to move axially in translation along the spindle 8. The cam flap 20 has a cam shaft 22 which penetrates into a support hole formed in the touch 20. The touch 20 can be retained by any

  suitable device on the shaft 22; for example by an elastic ring.

  It should be noted that the cam shaft 12 can rotate freely in its holder, in the preferred embodiment; however, it is not necessary that the touch

  cam turns, other than for the reduction of friction and the increase in the convenience of maneuvering.

  The cam contact 20 is placed in the cam 21 and constitutes a device for positioning the handle and a device for rotating the contact block 23 when this contact 20 is driven out of the cam 21 and moves to the periphery of maximum diameter of the outer plate 1 clutch. The block 23 of the contact has two springs 24 of return. Only the right spring is visible in figure 1. A corresponding spring is placed

  on the left side of the block 23 of the touch.

  The return arms are mounted so that they rotate about the contact block 23 on a common mounting axis 27. It will be appreciated by those skilled in the art that, since the return arms 24 are located between the contact block 23 and the return arms, the movement of the cam contact and consequently of the contact block causes the rotation drive return arms in a clockwise direction to the left in FIG. 1, under the action of the restoring force created by the springs

24 reminder.

  The contact block 23 and the return arms 25 are mounted on the mounting plate 9 in a U-shaped saddle 28, via the mounting pin 27, as shown. It should be noted that the rotation of the handle 5 causes a clockwise rotation of the return arms which cooperate in turn with the

  coil 26 and push back the inner clutch plate to the outer clutch plate.

  It should also be noted that when the shutter 11 is in its cooperation position, the relative movement of the contact block 23 and the return arms is absorbed by the return springs 24. This allows rotation of the outer handle 5 without rotation of the spindle 8

nor operation of the lock.

  When the electromagnet 15 is excited, by any device, the shutter 11 rotates towards a po7 sition in which it is, along its length, ob20 stacle for the inner plate clutch, and the return arms repel the clutch inner plate in contact with the outer clutch plate when the handle is turned. As a result, the members 4 and 3 forming the inner and outer jaws come into cooperation. Thus, the continued rotation of the handle 5 causes rotation of the spindle 8. When the spindle 8 constitutes an operating element in a lock, its rotation can be used to ensure the operation of the spindle.

lock or its mechanism.

  An internal handle 6 is directly mounted on the spindle 8 and can be used for the rotation of the spindle directly at any time, without putting in cooperation

clutch plates.

  For this purpose, apart from the use of a locking electromagnet, the operation of the clutch mechanism is as described in United States Patent No. 4,526,256, assigned to Schlage Lock. Company. The present invention considerably reduces the energy consumed by reducing the time required for excitation of the electromagnet. In addition to this energy reduction consumed, the security of the lock is increased by using a motion detection device combined with the locking electromagnet and a synchronization device. The combination can be used for detecting the operation of the

  lock and for the indication of an attempt to open 10 unauthorized.

  Reference is now made to Figure 1; it represents an electronic device for detecting motion, such as an optical analysis device 40, advantageously mounted on the plate 9 by means of rivets 44. A target 42 or an identity code 15 is shown attached to the external plate 1 clutch. After assembly and during operation, the optical analyzer "reads" or detects the passage of the target 42 in a well-known manner in a square slot 43 cut

in plate 1 for this purpose.

  Figure 4 is a diagram illustrating the operation of the various elements implemented according to the invention. According to the prior art, the clutch mechanism has been excited following an opening command transmitted by the logic circuit 50 of the lock. Electromagnet 15 was energized for a convenient period of time, e.g. 8 seconds, as determined by timing or timing device 55. If the operator was not fast enough, he could arrive at the end of the counting period and he would have to trigger the lock again for a second cycle of operation. During this second cycle, the electromagnet was constantly powered

  and consumed a current from the battery.

  According to the invention, the electromagnet 15 'operating in direct current is pulsed or excited for a short time which is only sufficient for the withdrawal of the plunger and its magnetic locking in the open position. For this purpose, a positive voltage is applied for example to a terminal A of the electromagnet 15 '. At this moment, the circuit

  synchronization and the detector or motion sensor 40 are controlled, and two operations are possible.

  When the handle of the lock is not turned so that it itself turns the outer plate 1 of the clutch, the synchronization circuit resets the lock after a relatively long period, for example 15 seconds, by applying a positive voltage to the terminal B for a period that is sufficient to unlock the electromagnet. The motion detector can also be de-energized. In the second possibility, the handle of the lock is rotated so that the lock is open and the motion detector 40 detects a sufficient rotation for the lock to be opened, and the lock is then rearmed by a short application of the positive voltage. at the terminal B. Those skilled in the art can note that the time required for the excitation of the electromagnet 15 'has been

  reduced from about 8 seconds to a time of about 1 second to less.

  The presence of the motion detector 40 may have a useful second function in that, when the handle of the lock is rotated without proper triggering of the operation of the lock, an alarm device 25 may transmit a sound signal for a period of time. , thus warning the occupants of an attempt to penetrate. Of course, various modifications may be made by those skilled in the art to the mechanisms which have just been described as examples only.

  limiting, without departing from the scope of the invention.

Claims (8)

  A clutch apparatus consuming very little energy, for an electronic lock or the like, of the type which comprises an electro-magnet engaging mechanism controlled by a logic device, characterized in that it comprises a motion detection device (40, 42) placed near the clutch mechanism and for detecting the operation of a part of the clutch mechanism, and the electromagnet (15) is an electromagnet locking. intended to allow the clutch mechanism (3, 4) to co-operate, the electromagnet (15) being unlocked so that it prevents the clutch mechanism (3, 4) from cooperating when the movement detected the end of operation.   2. Apparatus according to claim 1, characterized in that it further comprises a timing device (55) for unlocking the electromagnet (15) so that it suppresses the cooperation of the clutch mechanism (3,   4) after the lapse of a certain time.   Clutch mechanism for an electronic lock or the like, of the type which comprises a first clutch rotary member (1) mounted so that it rotates freely about a pin (8) and with respect to it, this element having a first jaw member (3), a second clutch member (2), mounted so that it can move in translation on the spindle (7, 8) and rotate in common with this pin, the second clutch member having a second jaw member (4) for cooperating with the first jaw member (3) and for rotating one of the clutch members (2) as a result of the rotation of the other of the clutch elements (1), a device (11) placed between the clutch elements and normally keeping them at a distance from one another, a device (20, 21 , 22, 23, 24, 25) for resiliently urging one of the clutch members (4) to move toward the other clutch elements (3) following the rotation of one of the clutch elements and causes the jaw elements to co-operate, and a device (11, 15) for selectively preventing the moving the first clutch member (2) to the other clutch member (1) so that the first and second jaw members (3, 4) can not co-operate and can not rotate the first clutch element (2) following the rotation of the other clutch element (1), said mechanism being characterized in that it comprises a locking device (15) incorporated in the device (11). 15) for selectively preventing movement of the first clutch member (2), a timing device (55) for releasing the locking device (15), and a motion detection device (40,42). intended to otherwise release the locking device   (11, 15) as a result of a selected operation of the lock.   Clutch mechanism according to Claim 3, characterized in that the locking device (15)   is a locking electromagnet which is no longer powered after operation so that it allows continuous operation of the lock without energy consumption.   5. Clutch mechanism according to claim 4, characterized in that the synchronization device (55) applies energy ensuring the unlocking of the   locking device (11, 15) after a predetermined time.   Clutch mechanism according to claim 4, characterized in that the motion detection device (40, 42) applies energy for unlocking the locking device after detection of a selected movement associated with the operation. and when the lock is opened.   The clutch mechanism according to claim 4, further characterized in that the motion detection device (40, 42) further detects an unauthorized attempt to lock the lock in operation by detecting the motion of the first rotary member. em10 clutch (1), and by triggering an alarm device (60). Clutch mechanism according to claim 6, further characterized in that the detection device   movement is an optical analyzer (40, 42).