FR3119411A1 - Method of operation of an access control system - Google Patents

Abstract

Method of operating an access control system This method of operating an access control system comprises: - the electrical connection (306) of first and second electrodes of a capacitor of an electronic cylinder, respectively , to first and second electrical contacts of the electronic cylinder to charge this capacitor from a battery housed inside a key when this key is inserted inside the electronic cylinder, and - the power supply (324 ) of an electric actuator of the electronic cylinder from this capacitor. Before an evaluation (320) of the validity of the access rights of the key is completed, the method includes the electrical connection (304) of the first and second electrodes of the capacitor, respectively, to the first and second electrical contacts of the electronic cylinder and the start of capacitor charging. Fig. 5

Description

Method of operation of an access control system

The invention relates to a method of operating an access control system as well as an electronic cylinder for the implementation of this method.

There are electronic lock cylinders which are only powered by the key inserted in this cylinder. This is advantageous because it is then not necessary to incorporate a battery inside the electronic cylinder. However, the operations to replace the battery of an electronic cylinder are always complicated operations to carry out and, in any case, more complicated to carry out than the replacement of a battery housed inside a key. For example, such an electronic cylinder is disclosed in application EP3431684.

In this context, before the user can turn his key inside the electronic cylinder, the electronic cylinder must have finished performing the following operations:
1) evaluate the validity of the access rights of the key in order to determine if this key is authorized to unlock the cylinder,
2) charge a capacitor housed inside the electronic cylinder from the energy stored in the key battery, then
3) if the key is an authorized key, powering an electric actuator which moves the cylinder from its locked position to its unlocked position from the energy stored in the capacitor.

Then the user of the key 16 turns the key inside the cylinder to unlock the lock and open the door.

So that the user does not feel any difference between the use of an electronic cylinder and the use of a mechanical cylinder, it is necessary that the operations 1) to 3) are carried out in less than 200 ms and, preferably, in less than 150ms. In addition, it is necessary to save as much as possible the energy stored in the battery of the key.

The invention aims to propose a method of operating an access control system which makes it possible to carry out operations 1) to 3) more quickly than in known access control systems. It therefore relates to such a method of operating an access control system comprising an electronic lock cylinder that can be moved between an unlocked position in which it authorizes access to a building and, alternately, a locked position in which he prohibits access to this building, this process comprising the following steps:
- when inserting a key inside the electronic cylinder, bringing into mechanical and electrical contact a first and a second electrical contact of the electronic cylinder on, respectively, first and second electrical contacts of the key, the first and second electrical contacts of the key being electrically connected to respective electrodes of a battery housed inside the key,
- the electrical connection of first and second electrodes of a capacitor of the electronic cylinder, respectively, to the first and second electrical contacts of the electronic cylinder to charge this capacitor from the battery housed inside the key when this key is inserted inside the electronic cylinder,
- the evaluation of the validity of the access rights of the key introduced inside this electronic cylinder and, only if the access rights are evaluated as being valid, the generation of a command to unlock the electronic cylinder ,
- only in response to the unlock command and only when the capacitor is charged, powering an electric actuator of the electronic cylinder from this capacitor, then
- when the electric actuator is powered, it moves:
- from an active position in which it holds the electronic cylinder in its locked position, towards
- an inactive position in which it allows movement of the cylinder to its unlocked position,
wherein, before the evaluation (320) of the validity of the access rights of the key is completed, the method includes the electrical connection (304) of the first and second electrodes of the capacitor, respectively, to the first and second electrical contacts of the electronic cylinder and the beginning of the charging of the capacitor.

Embodiments of this method of operation may include one or more of the following features:
1) the process comprises:
- the closing of a first switch which electrically connects the first electrode of the capacitor to the first electrical contact of the electronic cylinder, then
- the measurement of the state of charge of the capacitor and the triggering of the power supply of the electric actuator only if the state of charge thus measured of the capacitor exceeds a predetermined threshold, then
- After the measured state of charge has exceeded the predetermined threshold, controlling the opening of the first switch to electrically isolate the first electrode of the capacitor from the first electrical contact of the electronic cylinder.
2) the process comprises:
- the closing of a second switch which electrically connects the first electrode of the capacitor to an input port of a microcontroller of the electronic cylinder, then
- the measurement of the state of charge of the capacitor from the voltage present on this input port of the microcontroller and the triggering of the power supply of the electric actuator only if the state of charge thus measured of the capacitor exceeds a predetermined threshold, then
- after the measured state of charge has exceeded the predetermined threshold, the control of the opening of this second switch to electrically isolate the first electrode of the capacitor from the input port of the microcontroller.
3) after the power supply to the electric actuator from this capacitor, the method comprises the systematic interruption of the power supply to the electric actuator after a predetermined period long enough to allow the displacement of the electric actuator from its active position to its inactive position, this predetermined time also being shorter than the time required for the capacitor to discharge completely through the electric actuator.
4) the beginning of the charging of the capacitor begins systematically as soon as the first and second electrical contacts of the electronic cylinder are brought into mechanical and electrical contact on, respectively, the first and second electrical contacts of the key.
5)
- from the moment when the mechanical and electrical contacting of the first and second electrical contacts of the electronic cylinder took place on, respectively, the first and second electrical contacts of the key, the microcontroller counts down a predetermined duration greater than 15 ms, then
- Only after this predetermined duration has elapsed, the microcontroller triggers the evaluation of the validity of the access rights of the key.
6) The microcontroller activates a capacitor charging voltage boost only after the predetermined time has elapsed.
7) the method includes connecting power ports of a microcontroller of the electronic cylinder to the first and second electrical contacts of the electronic cylinder to power this microcontroller from the battery housed inside the key.

Finally, the subject of the invention is an electronic cylinder for implementing the above method, this electronic cylinder being movable between an unlocked position in which it allows access to a building and, alternately, a locked position in which he prohibits access to this building, this electronic cylinder comprising:
- a reversibly movable blocking member between:
- a locking position in which it holds the electronic cylinder in its locked position, and
- a retracted position which corresponds to the unlocked position of the electronic cylinder,
- an electric actuator able, in response to receiving an unlocking command, to move:
- from an active position in which it maintains the blocking member in its blocking position, towards
- an inactive position in which it authorizes the movement of the blocking member towards its retracted position,
- a configured microcontroller:
- to assess the validity of access rights of a key introduced inside this electronic cylinder and,
- only if the access rights are evaluated as valid, generate the unlock command,
- a capacitor capable of supplying the electric actuator when it is charged to move the actuator from its active position to its inactive position, this capacitor comprising a first and a second electrode,
- a first and a second electrical contact capable of coming directly into electrical and mechanical contact on, respectively, first and second electrical contacts of the key when this key is inserted inside the electronic cylinder, to electrically connect these first and second electrical contacts of the electronic cylinder to respective electrodes of a battery housed inside this key,
- a first switch comprising a control terminal, this first switch being capable, in response to the reception of an electrical closing signal, of switching into a closed state in which it electrically connects the first electrode of the capacitor to the first electrical contact for charge the capacitor from the key battery,
wherein the electronic cylinder is configured to generate the electrical closing signal before the microcontroller has completed the evaluation of the validity of the access rights of the key.

The embodiments of this cylinder may include the following feature:
1) the cylinder comprises a voltage booster connected between the first electrical contact and the first electrode of the capacitor to raise the voltage of the battery of the key used to charge the capacitor.

The invention will be better understood on reading the following description, given solely by way of non-limiting example and made with reference to the drawings in which:
- there is a schematic illustration of a door equipped with an electronic cylinder;
- there is a schematic illustration, in perspective, of an access control system comprising the cylinder of the and a key;
- there is a schematic illustration, in vertical and longitudinal section, of the electronic cylinder of the ;
- there is a schematic illustration of part of the electronic circuit implemented in the electronic cylinder of the system of the ;
- there is a flowchart of a method of operating the system of the .

In these figures, the same reference numerals are used to designate the same elements. In the remainder of this description, the characteristics and functions well known to those skilled in the art are not described in detail.

In this description, detailed examples of embodiments are first described in a chapter I with reference to the figures. Then, in a chapter II, variants of these embodiments are presented. Finally, the advantages of the different embodiments are presented in a chapter III.

Chapter I: Examples of embodiments

Figure 1 shows a door 2 for access to a building. This door 2 has an interior side, typically located inside a room, and an exterior side on the opposite side. Hereafter, the terms “interior” and “exterior” refer, respectively, to the interior and exterior sides of the door 2. The door 2 here extends in a vertical plane. Thereafter, the vertical direction is designated by the Z direction of an XYZ orthogonal frame. The direction X is perpendicular to the vertical plane in which the door 2 mainly extends. All of the figures in which mechanical components are shown are oriented with respect to this reference XYZ.

Door 2 is equipped with a handle 4 and an electronic lock 6. To simplify Figure 1, only part of door 2 is shown.

The general mechanical architecture of lock 6 is, for example, identical to that described in applications FR3025236 and EP3431684. For this reason, only the details necessary for understanding the invention are given here. For further details, the reader is referred to these requests.

The lock 6 comprises a bolt 10 movable in translation, parallel to the direction Y, alternately and reversibly, between an extended position and a retracted position. In the extended position, the bolt 10 protrudes beyond the edge of the door 2 to engage in a keeper fixed without any degree of freedom on the frame of the door 2. In the extended position, the bolt 10 locks door 2 in its closed position. In the retracted position, the bolt 10 is retracted inside the door 2 and no longer protrudes beyond the edge of this door 2. In the retracted position, the door 2 can be moved by a user of a closed position to an open position by operating the handle 4.

The lock 6 also includes an electronic cylinder 12 and a screw 14 for fixing the cylinder 12 in the door 2.

The cylinder 12 is movable between an unlocked position and, alternately, a locked position. In the unlocked position, it authorizes the opening of the door 2 and therefore access to the building. In the locked position, it prohibits the opening of the door 2 and therefore access to a building. For this, the cylinder 12 moves the bolt 10 from its extended position to its retracted position when a key 16 (FIG. 2), authorized to unlock the lock 6, is inserted, then turned inside this cylinder 12. The cylinder 12 also moves the bolt 10 from its retracted position to its extended position when the authorized key is introduced and then turned in the opposite direction inside this cylinder. Conversely, when an unauthorized key is introduced inside the cylinder 12, this cylinder prevents the movement of the bolt 10 from its extended position to its retracted position.

Here, the key 16 can be introduced inside the cylinder 12 from the exterior side and, alternately, from the interior side of the door 2. For this purpose, the cylinder 12 emerges on each side of the door 2.

Screw 14 has a head that is flush with the edge of door 2. The threaded end of screw 14 is screwed into cylinder 12 to hold it in place inside door 2.

Cylinder 12 has no internal power source. In particular, it lacks:
- a battery capable of storing enough energy to allow the cylinder 12 to switch more than a hundred times between its unlocked and locked positions without an external energy supply, and
- A mechanism capable of generating enough electricity to move the cylinder 12 into its unlocked position from, for example, the movement of the key inside the cylinder.

Figure 2 shows in more detail the access control system produced using the lock 6 and the key 16.

Here, cylinder 12 conforms to the European format. The cylinder 12 extends along a longitudinal axis 20 parallel to the direction X. It comprises a stator 22 fixed without any degree of freedom to the door 2 by means of the screw 14 and a bit 24 housed at the inside a transverse notch 26.

The notch 26 extends in a transverse plane 28 parallel to the directions Y, Z. Here, only part of the plane 28 is shown in Figure 2. The plane 28 is a plane of symmetry for the bit 24.

The bit 24 rotates counterclockwise around the axis 20 to move the bolt 10 from its extended position to its retracted position and in the opposite direction to move the bolt 10 from its retracted position to its extended position.

The plane 28 also divides the stator 22 into two parts. The part of the stator 22 located on the inner side of door 2 is called "inner half-stator" and bears the reference 30. The part of stator 22 located on the outer side of door 2 is called "outer half-stator" and bears the reference the reference 32. In this particular embodiment, the half-stators 30 and 32 are almost symmetrical to each other with respect to the plane 28. Thus, only the half-stator 32 is described in more detail by the following.

The half-stator 32 comprises a front cover 34 parallel to the plane 28 and directly exposed outside the door 2. This front cover prevents having direct access to the moving parts located inside the cylinder 12 so as to protect them against break-in attempts. This cover 34 is crossed by an orifice 36 intended to receive a blade 38 of the key 16. The orifice 36 is centered on the axis 20. The orifice 36 is shaped so as to allow the introduction of the blade 38 to inside the cylinder 12 by a translation movement parallel to the direction X. The orifice 36 is also shaped to allow the key 16 introduced inside the cylinder 12 to turn on itself around the axis 20 .

Here, the key 16 is an electronic key capable of transmitting an access code to the cylinder 12 so that the latter, in response:
- authorizes the unlocking of cylinder 12 if the access code received is a valid access code which authorizes the key to open door 2, and alternately
- prohibits the unlocking of cylinder 12 if the access code received is an invalid access code which does not authorize the key to open door 2.

To this end, the key 16 comprises a transceiver 40 and a battery 41.

Here, the blade 38 has no pattern in relief intended to move the pins of the lock to cause mechanical unlocking of the lock 6. On the other hand, the blade 38 comprises at least one pattern capable of cooperating with a pattern of complementary shape on a rotor of cylinder 12 to drive this rotor in rotation when the key turns. Here, this pattern on blade 38 is a flat 42 located on its distal end.

The transceiver 40 is in particular capable of transmitting, via an electrical connection, the access code to the cylinder 12.

Battery 41 is used here to power cylinder 12 via electrical connections. These electrical connections are established only when the blade 38 is introduced inside the cylinder 12. For this purpose, the blade 38 comprises electrical contacts capable of cooperating with corresponding electrical contacts of the cylinder 12 to establish these electrical connections between the key 16 and the cylinder 12. By way of illustration, here, the blade 38 comprises six electrical contacts arranged symmetrically on either side of the axis of the blade 38. For example, the symmetrical contacts one of the other are part of the same conductive ring. In the figures, only the contacts 44 to 46 located on the same side of the blade 38 are visible.

FIG. 3 shows the inside of cylinder 12 in greater detail. Stator 22 comprises a cylindrical channel 50, of circular cross-section, crossing right through stator 22 and therefore the two half-stators 30 and 32. This channel 50 extends along the axis 20. Here, the axis 20 coincides with the axis of symmetry of revolution of the channel 50.

_{The channel 50 receives a rotor 52. The rotor 52 is for example identical to that described in more detail, in particular, with reference to FIGS. 5 and 6 of application FR3025236. In particular, the rotor 52 comprises a housing 96 capable of receiving the end of the blade 38. The cross section of this housing 96 comprises at least one shape complementary to the end of the blade 38 so as to be meshed in rotation by the blade 38. Here, this complementary shape is a flat capable of meshing with the flat 42 of the blade 38. Thus, when an authorized key is turned inside the lock 6, the rotation of the key 16 causes the rotation of the rotor 52 which itself causes the rotation of the bit 24.}

At its ends, channel 50 opens into cover 34 opposite orifice 36.

Here, the half-stator 32 comprises a shell 54 located entirely on the exterior side of the plane 28 and half of a strip 56 located on the exterior side of this plane 28. The strip 56 is symmetrical with respect to the plane 28.

The shell 54 includes the front cover 34, the orifice 36 and half of the channel 50 located on the exterior side. Preferably, the shell 54 is formed from a single block of rigid material. By “rigid material” or “rigid material”, is meant a material whose Young's modulus at 25° C. is greater than 100 GPa or 150 GPa and, preferably, greater than 200 GPa.

The half-stator 32 comprises a controllable mechanism 76 for unlocking the cylinder. This mechanism 76 is able to move a member 80 for blocking the rotation of the rotor 52. This mechanism 76 is fixed, without degree of freedom, on the shell 54. For example, the mechanism 76 and the member 80 are similar or identical. to those described in application FR3025236. To increase the readability of FIG. 3, the representations of the mechanism 76 and of the member 80 have been simplified.

The member 80 moves in translation between a locking position (shown in Figure 3) and a retracted position. In the blocking position, a distal end of the member 80 is received inside a crevice arranged in the rotor 52 to prevent the rotation of this rotor around the axis 20. In the retracted position, the distal end of the member 80 is located outside the crevice, so that the rotor 52 can be driven in rotation by the key 16 around the axis 20. For example, the member 80 moves only in translation between its blocking position and its retracted position. Here, this translational displacement is parallel to the Z direction.

The mechanism 76 typically comprises a controllable electric actuator 82 and an electronic unit 84 for controlling this actuator 82. Here, in response to an unlocking command transmitted by the unit 84, the actuator 82 moves from an active position to a idle position. In the inactive position, the member 80 can be freely moved from its locking position to its retracted position when the key 16 is turned inside the cylinder 12. In its active position, the actuator 82 holds the member 80 in its locked position. In the absence of an unlocking command, actuator 82 is in its active position and member 80 cannot be moved to its retracted position. Once the actuator 82 has reached its inactive position, it remains in its inactive position until the key 16 is removed from the cylinder 12. Typically, the actuator 82 is maintained in its inactive position without consuming energy. electric energy. For example, for this, it comprises a magnet mechanism which keeps it in its inactive position until the removal of the key 16. The displacement of the actuator 82 from its inactive position to its active position is here mechanically driven by the movement of the key when it is removed from the cylinder 12.

Unit 84 is suitable:
- to receive the access code transmitted by the key introduced into the cylinder 12, then
- Depending on the access code received, to transmit to the actuator 82 the unlocking command and, alternately, to inhibit the transmission of this unlocking command to maintain the member 80 in its locking position.

To authorize or, on the contrary, inhibit the transmission of the unlocking command, the unit 84 compares the access code received with pre-recorded access codes. If the access code received corresponds to one of the prerecorded access codes, then unit 84 transmits the unlock command. Otherwise, the unit 84 does not transmit this unlocking command.

Here, the unit 84 communicates with the transceiver 40 via an electrical link 106 which is established when the key 16 is completely inserted inside the channel 50. At the same time, the battery 41 transmits the energy required to power mechanism 76 via two electrical connections 107 and 108. Connection 106 is established via contact 44 and an electrical contact 100 of half-stator 32. Connections 107 and 108 are established via contacts 45, 46 and two electrical contacts 101 and 102 of half-stator 32.

_{The electrical contacts 100 to 102 are, for example, structurally identical to each other. For example, these contacts 100 to 102 are made as described in application EP3431684.}

There mainly represents the part of the electronic circuit of the control unit 84 implemented to reduce the time required to unlock the cylinder 12.

Unit 84 includes:
- a microcontroller 200,
- a transceiver 202,
- a circuit 212 for protecting the microcontroller 200 and the transceiver 202 against overvoltages, and
- a capacitor C3 able to store enough electrical energy to supply the actuator 82.

In this diagram, the mass is connected to the electrical contact 101. Thus, to simplify the , the wire connections between a component of unit 84 and electrical contact 101 are sometimes represented by a symbol indicating that this component is electrically connected to the ground of unit 84.

In this text, unless otherwise specified, the term "connected" means electrically connected. The term "directly connected" means that two components of the unit 84 are connected by a wired link which does not cross another component different from a wired link.

The term “wire connection” denotes both a wire having, for example, a circular cross-section and an electrical track of a printed circuit.

The microcontroller 200 comprises a power supply port 204 connected to ground and a power supply port 208 connected to the electrical contact 102 via a diode CR1. The anode of diode CR1 is directly connected to electrical contact 102.

The microcontroller 200 also includes a communication port 226 connected to the transceiver 202 to receive and transmit to the transceiver 202 baseband information. Transceiver 202 encodes the information and then transmits it over electrical link 106. Conversely, transceiver 202 decodes the information received via electrical link 106 and transmits the decoded information over the port. 226 of the microcontroller 200. For this purpose, the transceiver 202 is connected to the electrical contact 100.

A measurement port 228 of the microcontroller 200 is connected:
- on one side, to an electrode 230 of capacitor C3 via a switch Q8 and a resistor R8, and
- on the other side, to ground via a resistor R9.

Capacitor C3 also includes an electrode 232 electrically insulated from electrode 230 and directly connected to ground.

Switch Q8 has a control terminal 240 and two power terminals 242 and 244. Terminal 242 is directly connected to resistor R8. Terminal 244 is directly connected to port 228. Terminal 240 is directly connected to an output port 246 of microcontroller 200. In response to an electrical open signal on terminal 240, switch Q8 switches from a closed state to an open state. In the closed state, switch Q8 connects terminals 242 and 244 together. In the open state, switch Q8 electrically isolates terminals 242 and 244 from each other. For example, switch Q8 is an N-type Metal Oxide Semiconductor Field Effect Transistor (MOSFET). In this case, terminals 240, 242 and 244 correspond, respectively, to the gate, drain and source of this switch. transistor.

An output port 250 of the microcontroller 200 is connected via a resistor R4 to a control terminal 252 of a switch Q6. The Q6 switch also includes:
- a power terminal 254 connected to the electrical contact 102 via a diode CR10, and
- A power terminal 256 connected to the electrode 230 of capacitor C3 via a voltage booster 260.

The anode of diode CR10 is directly connected to electrical contact 102.

In response to an electrical open signal on terminal 252, switch Q6 switches from a closed state to an open state. In the closed state, it electrically connects the terminals 254 and 256. In the closed state, the electrode 230 of the capacitor C3 is therefore connected to the electrical contact 102. In the open state, the switch Q6 electrically isolates the terminals 254 and 256 from each other, which also electrically isolates capacitor C3 from electrical contact 102.

Switch Q6 is here a P-type MOSFET transistor. In this case, terminals 252, 254 and 256 correspond, respectively, to the gate, source and drain of this transistor.

Terminal 252 is also connected to ground through a resistor R3. Thus, in the absence of an opening signal generated by the microcontroller 200, the switch Q8 is permanently maintained in its closed state.

The booster 260 makes it possible to raise the voltage present between the electrical contacts 101 and 102 to charge the capacitor C3 with a higher voltage. In this embodiment, it comprises:
- an inductance L1,
- a diode CR9, and
- a Q7 switch.

One end of inductor L1 is directly connected to terminal 256 of switch Q6. The other end of inductor L1 is connected to electrode 230 of capacitor C3 via diode CR9. The cathode of diode CR9 is directly connected to electrode 230 of capacitor C3.

Switch Q7 has a control terminal 270 and two power terminals 272 and 274. Terminal 270 is directly connected to a port 276 of microcontroller 200. Terminal 270 is also connected to ground through a resistor R16.

Terminal 272 is directly connected between inductance L1 and the anode of diode CR9. Terminal 274 is directly connected to ground.

Switch Q7 switches between an open state and a closed state. In the open state, it connects terminals 272 and 274 together. In the closed state, it electrically isolates terminals 272 and 274 from each other.

Here, switch Q7 is an N-type MOSFET transistor. Terminals 270, 272 and 274 then correspond, respectively, to the gate, drain and source of this transistor.

The electrode 230 is connected via a switch Q9 to a terminal 82A supplying the actuator 82. The other terminal 82B supplying the actuator 82 is connected to the mass of the unit. 84.

Switch Q9 has a control terminal 280 and two power terminals 282, 284. Terminal 282 is directly connected to electrode 230. Terminal 284 is directly connected to terminal 82A of actuator 82. Terminal 280 is directly connected to an output port 286 of microcontroller 200. Switch Q9 switches between a closed state and an open state. In the open state, it electrically isolates terminals 282 and 284 from each other so that actuator 82 is not powered. In the closed state, switch Q9 connects terminals 282 and 284 so that terminal 82A is connected to electrode 230 of capacitor C3. Thus, in the closed state, the switch Q9 enables the supply of the actuator 82 when the capacitor C3 is sufficiently charged. Switch Q9 switches from its open state to its closed state in response to the reception on terminal 280 of an electrical closing signal. In the absence of a signal transmitted by the microcontroller 200, the switch Q9 is in its open state.

The microcontroller 200 comprises:
- a memory 216 which comprises instructions necessary for the execution of the method of the , And
- a microprocessor 218 capable of executing the instructions recorded in the memory 216.

The memory 216 comprises in particular the instructions of an access control module 222 and of a module 290 for charging the capacitor C3.

When the instructions of module 222 are executed by microprocessor 218, cylinder 12 interacts with key 16 to assess the validity of the access code transmitted by key 16.

When the instructions of module 290 are executed by microprocessor 218, microcontroller 200 controls switches Q6, Q8 and Q9 and booster 260 to manage the charge of capacitor C3. The operations performed by modules 222 and 290 are described in more detail with reference to the method of the .

The operation of the cylinder 12 will now be described using the .

Initially, during a step 300, the key 16 is removed from the cylinder 12. The microcontroller 200 is therefore not powered. Switch Q6 is in its closed state and switches Q7, Q8 and Q9 are in their open states. Capacitor C3 is partially or totally discharged. Actuator 82 is not powered. Therefore, the blocking member 80 is maintained in its blocking position.

During a step 302, the blade 38 of the key 16 is introduced, through the orifice 36, inside the channel 50 of the cylinder 12. The electrical contacts 44 to 46 then come directly into mechanical and electrical contact, respectively, on electrical contacts 100 to 102 of cylinder 12. Electrical connections 106 to 108 between key 16 and cylinder 12 are then established and cylinder 12 is now powered by battery 41 of key 16.

During a step 304, as soon as the electrical connections 107 and 108 are established, the capacitor C3 begins to charge. Indeed, the switch Q6 is in its closed state and therefore the electrodes 230, 232 of this capacitor C3 are connected, respectively, to the contacts 102, 101. The charge of the capacitor C3 continues as long as the key 16 is inserted in the cylinder 12 and switch Q6 is in its closed state.

When capacitor C3 is completely discharged, it has been observed that the voltage between the electrodes of opposite polarities of battery 41 collapses for a duration D _e . The duration D _e is generally less than 10 ms or 15 ms and, typically, greater than 1 ms or 5 ms.

In parallel with step 304, at the same time as the charging of capacitor C3 begins, the supply of microcontroller 200 begins.

When the microcontroller 200 is powered, during a step 306, it begins by counting down a predetermined duration D _i during which the activity of the microcontroller 200 is reduced to the maximum so as to limit its energy consumption. This duration D _i is chosen between D _{e and 2D e or between D e and 1.5D e} . Here, the duration D _i is equal to 20 ms. Thus, it is only after the duration D _i has completely elapsed that the microcontroller 200 immediately triggers the execution of the modules 222 and 290. This prevents the voltage drop observed at the start of the charging of the capacitor C3 from cumulates with a voltage drop caused by the consumption of the microcontroller 200 when it executes the modules 222 and 290. Indeed, the accumulation of these two voltage drops can cause the voltage between the electrical contacts 101 and 102 to drop below a threshold S _off where the voltage is no longer sufficient to supply the microcontroller 200. When the voltage between the contacts 101 and 102 falls below the threshold S _off , the microcontroller 200 switches off automatically before attempting to restart a few moments longer late. Such successive restarts result in unnecessary consumption of the energy stored in the battery 41. In addition, this slows down the charging of the capacitor C3. The fact of limiting the consumption of the microcontroller 200 during this duration D _i makes it possible to avoid these drawbacks.

Here, the charging of capacitor C3 therefore begins systematically before the execution of modules 222 and 290.

When the module 290 is executed, during a step 310, the microcontroller 200 activates the booster 260 so that the latter increases the voltage delivered by the battery 41 to charge the capacitor C3. For example, here, the voltage delivered by battery 41 is 3.3 Vdc and it is raised to 4 Vdc to rapidly charge capacitor C3.

Microcontroller 200 activates lift 260 by periodically switching switch Q7 between its open and closed states. For example, here the switching frequency of switch Q7 is 330 kHz and the duty cycle is 36%. A duty cycle of 36% means that for 36% of the duration of a period of the control signal for switch Q7, this signal is in the high state and controls the closing of switch Q7. During the remaining time of a period, the control signal is in the low state and the switch Q7 is in its open state.

In parallel with step 310, during a step 312, module 290 measures the state of charge of capacitor C3. For this, here, module 290 measures the voltage between electrodes 230 and 232 of capacitor C3. To this end, from the start of the execution of the module 290, the microcontroller 200 generates a closing signal on the port 246 to switch the switch Q8 in its closed state. A voltage depending on the state of charge of capacitor C3 is then present on port 228 of measurement.

Then, at regular intervals, during a step 313, the microcontroller 200 compares the voltage present on the port 228 with a predetermined threshold S _c . As long as the voltage on port 228 does not exceed this threshold S _c , capacitor C3 is considered not yet to be sufficiently charged to supply actuator 82. The method then returns to steps 310 and 312.

Conversely, from the moment the threshold S _c is crossed, the capacitor C3 is considered to be sufficiently charged. In this case, the module 290 interrupts the execution of steps 310, 312 and proceeds to a step 314.

During step 314, the microcontroller 200 transmits opening signals to the switches Q6, Q7 and Q8. Thus, capacitor C3 is electrically isolated from all the electrical components of unit 84. This greatly limits the discharge of capacitor C3 caused by leakage currents. In particular, the opening of switch Q8 prevents part of the energy of capacitor C3 from being unnecessarily consumed by resistors R8 and R9 and via measurement port 228. Similarly, opening switch Q7 prevents energy from leaking unnecessarily through resistor R16 and port 276. Diode CR9 prevents capacitor C3 from discharging into battery 41. The opening of the switch Q6 prevents recharging of the capacitor C3 as soon as the latter has been discharged to supply the actuator 82. During step 314, a charging indicator of the capacitor C3 is updated to indicate that now capacitor C3 is sufficiently charged. The value of this indicator is recorded in memory 216. The execution of module 290 stops at the end of step 314.

In parallel with the execution of the module 290, the microprocessor 218 executes the module 222 of access control. Therefore, during a step 320, the microprocessor 218 evaluates the access rights of the key 16 to determine whether they are valid access rights and therefore a key authorized to unlock the cylinder 12. For this, here, the key 16 transmits the access code, via the electrical connection 106, as soon as it is inserted inside the cylinder 12. During step 320, this code access is compared, by the microprocessor 218, with the access rights prerecorded in the memory 216.

If the access code received does not correspond to the pre-recorded access rights, the access code received is invalid and the microcontroller 200 prohibits, during a step 322, the displacement of the cylinder 12 towards its unlocked position. For this, during step 322, the microcontroller 200 inhibits the transmission of the closing signal of switch Q9. The actuator 82 is therefore not powered, which keeps the actuator 82 in its active position and prevents the movement of the blocking member 80 to its retracted position. In this case, capacitor C3 remains charged and the energy stored in this capacitor C3 will be used later to unlock cylinder 12 using another key. Thus, the energy stored in capacitor C3 is not lost even if the access code transmitted by key 16 does not unlock cylinder 12.

Conversely, if the access code received is a valid access code, during a step 324, the module 222 generates an unlocking command for the cylinder 12. More specifically, this unlocking command is generated as soon as the following two conditions are satisfied:
- Condition 1): the access code received is a valid access code which corresponds to the access rights prerecorded in the memory 216, and
- Condition 2): the charging indicator recorded in the memory 216 indicates that the capacitor C3 is sufficiently charged.
In this embodiment, the command to unlock cylinder 12 is a signal to close switch Q9. The microcontroller 200 generates the close signal continuously for a duration D _f . The duration D _f is greater than 1.05D _b or 1.3D _b , where the duration D _b is equal to the time necessary for the actuator 82 to move from its active position to its inactive position. The duration D _f is also less than 0.85D _d or 0.7D _d , where the duration D _d is the time required for the capacitor C3 to fully discharge through the actuator 82.

Thus, throughout the duration D _f , the actuator 82 is powered solely from the electrical energy stored in the capacitor C3. In response, it moves from its active position to its inactive position.

At the end of the duration D _f , during a step 326, the microcontroller 200 interrupts the power supply to the actuator 82. For this, the microcontroller 200 interrupts the generation of the closing signal of the switch Q9. Switch Q9 therefore returns to its open state and cuts the power supply to actuator 82. However, actuator 82 remains in its inactive position without consuming electrical energy.

Then, the user turns the key 16 inside the cylinder 12 to open the door 2. This then causes the movement of the member 80 to its retracted position and the cylinder 12 is moved to its unlocked position.

When the user withdraws the key 16 from the cylinder 12, this brings the actuator 12 back to its active position. The cylinder 12 is therefore again in its locked position.

Chapter II: Variants:

Alternatively, if the voltage between the electrodes of the battery 41 is sufficiently high and, for example, here equal to 4 Vdc, the voltage booster 260 can be omitted.

In variants, switch Q6 can be omitted and replaced by a simple wire connection which connects electrode 230 to electrical contact 102. In this case, the duration D _f during which switch Q9 is in its closed state is chosen sufficiently short so as not to allow the capacitor C3 to be completely discharged. Indeed, in the opposite case, the actuator 82 is directly powered by the battery 41 which can cause a collapse of the voltage between the electrodes of this battery. This is the case, for example, if capacitor C3 does not risk being discharged in battery 41 because the voltage between the electrodes of this battery is systematically greater than the voltage between electrodes 230, 232 when capacitor C3 is fully charged.

In variants, the module 290 measures the voltage present between the electrical contacts 101 and 102. The temporal succession of these measurements forms a function representative of the temporal evolution of the voltage between the contacts 101 and 102. The microcontroller 200 is then programmed to detect the instant from which this function begins to increase again. The microcontroller 200 then triggers the execution of the access control module 222 as soon as this event is detected. Thus, execution of module 222 is triggered, in general, rather than in previous embodiments. Indeed, the duration D _i is generally chosen to suit the worst case, that is to say in the case where the battery 41 is weakly charged. However, the worst case is not systematically encountered.

Alternatively, step 306 is omitted. In this case, microcontroller 200 immediately starts running modules 222 and 290. If this causes the microcontroller 200 supply voltage to drop below the S _off threshold, microcontroller 200 shuts down and then restarts a few moments later . Thus, in the absence of an initial timeout, the microcontroller 200 may have to restart several times before being able to execute the module 290 correctly.

In variants, the access rights are evaluated by key 16 and not by cylinder 12. For example, for this, it is cylinder 12 which transmits its identifier to key 16. If the identifier received by the key 16 belongs to a list, pre-recorded in a memory of the key, of cylinder identifiers that this key can unlock, then the key transmits to the cylinder, in response, an opening command . When the microcontroller 200 receives this opening command, it in turn generates the closing command for switch Q9 as soon as capacitor C3 is sufficiently charged.

Chapter III: Advantages of the embodiments described:

The fact of starting to charge the capacitor C3 before the evaluation of the validity of the access rights has been completed, that is to say before knowing whether the key 16 is authorized to unlock the cylinder 12, makes it possible to start to charge this capacitor C3 rather than in known access control systems. Indeed, in known access control systems, the charging of the capacitor begins only if the access rights are evaluated as being valid and therefore systematically and only after the end of the evaluation of the access rights of the key. .

Moreover, the fact of triggering the evaluation of the access rights before the capacitor C3 is completely charged makes it possible to execute, at least in part, these operations of evaluation of the access rights received in parallel with the charging of the capacitor C3. Ultimately, this reduces the period of time that elapses between the moment the user inserts his key inside the cylinder and the moment the cylinder moves to its unlocked position when the entered key is an authorized key.

Finally, it is emphasized that the process practically does not increase the electrical consumption of the cylinder and does not modify, or practically does not modify, the average life of the batteries of the keys. Indeed, in the case where the key is not authorized to unlock the cylinder, the capacitor C3 remains charged. Thus, when a following key is introduced into the interior of cylinder 12, capacitor C3 is already charged or at least partially charged. Therefore, the energy drawn from the battery of the next key to charge capacitor C3 is lower, or even zero. Thus, the energy drawn from the battery of an unauthorized key is not lost but used to limit the energy drawn from the battery of a following key. Therefore, the average battery life of the keys is not substantially changed.

The fact of isolating the capacitor C3 from the electrical contact 102 as soon as the capacitor C3 is discharged makes it possible to prevent it from recharging immediately after having powered the actuator 82. This makes it possible to increase the life of the batteries 41 by keys.

The fact of systematically cutting off the power supply to the actuator 82 after the duration D _f makes it possible to avoid systematically completely discharging the capacitor C3. Thus, when the next key is introduced into cylinder 12, capacitor C3 is not completely discharged and the energy drawn from battery 41 of the next key is lower. This therefore extends the life of the key batteries.

The fact of electrically isolating the resistors R8, R9 and the measuring port 228 of the electrode 230 of the capacitor after the latter has been sufficiently charged makes it possible to limit the leakage currents which discharge the capacitor C3 and therefore to preserve the capacitor C3 charged longer. Since the leakage currents which discharge capacitor C3 are limited, the life of the key batteries is extended.

The fact of triggering the evaluation of the access rights received after the duration D _i , makes it possible to prevent the supply voltage of the microcontroller 200 from falling below the threshold S _off which leads to the stopping of this microcontroller then to a restart of it. This therefore avoids untimely shutdowns of the microcontroller 200.

The fact of connecting the capacitor C3 to the electrical contact 102 even before activating the voltage booster 260 makes it possible to start charging this capacitor C3 even more quickly.

Claims (10)

Method of operating an access control system comprising an electronic lock cylinder that can be moved between an unlocked position in which it authorizes access to a building and, alternately, a locked position in which it prohibits access to this building, this method comprising the following steps:
- when inserting a key inside the electronic cylinder, the mechanical and electrical contacting (302) of first and second electrical contacts of the electronic cylinder on, respectively, first and second electrical contacts of the key, the first and second electrical contacts of the key being electrically connected to respective electrodes of a battery housed inside the key,
- the electrical connection (306) of first and second electrodes of a capacitor of the electronic cylinder, respectively, to the first and second electrical contacts of the electronic cylinder to charge this capacitor from the battery housed inside the key when this key is inserted inside the electronic cylinder,
- the evaluation (320) of the validity of the access rights of the key introduced inside this electronic cylinder and, only if the access rights are evaluated as being valid, the generation of an unlocking command of the electronic cylinder,
- only in response to the unlocking command and only when the capacitor is charged, the supply (324) of an electric actuator of the electronic cylinder from this capacitor, then
- when the electric actuator is powered, it moves (324):
- from an active position in which it holds the electronic cylinder in its locked position, towards
- an inactive position in which it allows movement of the cylinder to its unlocked position,
characterized in that, before the evaluation (320) of the validity of the access rights of the key is completed, the method includes the electrical connection (304) of the first and second electrodes of the capacitor, respectively, to the first and second electrical contacts of the electronic cylinder and the beginning of the charging of the capacitor. A method according to claim 1, wherein the method comprises:
- the closing of a first switch which electrically connects the first electrode of the capacitor to the first electrical contact of the electronic cylinder, then
- the measurement (312) of the state of charge of the capacitor and the triggering (324) of the supply of the electric actuator only if the state of charge thus measured of the capacitor exceeds a predetermined threshold, then
- After the measured state of charge has exceeded the predetermined threshold, the control (314) of the opening of the first switch to electrically isolate the first electrode of the capacitor from the first electrical contact of the electronic cylinder. A method according to any preceding claim, wherein the method comprises:
- closing (312) a second switch which electrically connects the first electrode of the capacitor to an input port of a microcontroller of the electronic cylinder, then
- the measurement (312) of the state of charge of the capacitor from the voltage present on this input port of the microcontroller and the triggering (324) of the power supply of the electric actuator only if the state of charge thus measured of the capacitor exceeds a predetermined threshold, then
- after the measured state of charge has exceeded the predetermined threshold, the control (314) of the opening of this second switch to electrically isolate the first electrode of the capacitor from the input port of the microcontroller. Method according to any one of the preceding claims, in which after the supply of the electric actuator from this capacitor, the method includes the systematic interruption (326) of the supply of the electric actuator after a predetermined period long enough to allow movement of the electric actuator from its active position to its inactive position, this predetermined time also being shorter than the time required for the capacitor to discharge completely through the electric actuator. Method according to any one of the preceding claims, in which the beginning of the charging of the capacitor begins systematically as soon as the first and second electrical contacts of the electronic cylinder are brought into mechanical and electrical contact (302) on, respectively, the first and second contacts electrics of the key. A method according to claim 5, wherein:
- from the moment when the mechanical and electrical contacting (302) of the first and second electrical contacts of the electronic cylinder took place on, respectively, the first and second electrical contacts of the key, the microcontroller counts down (306 ) a predetermined duration greater than 15 ms, then
- Only after this predetermined time has elapsed, the microcontroller triggers the evaluation (320) of the validity of the access rights of the key. A method according to claim 6, wherein the microcontroller activates (310) a capacitor charging voltage boost only after the predetermined time has elapsed. A method according to any preceding claim, wherein the method includes connecting (302) power ports of a microcontroller of the electronic cylinder to the first and second electrical contacts of the electronic cylinder to power that microcontroller from the battery housed inside the key. Electronic lock cylinder for implementing a method in accordance with any one of the preceding claims, this electronic cylinder being movable between an unlocked position in which it authorizes access to a building and, alternately, a locked position in which he prohibits access to this building, this electronic cylinder comprising:
- a reversibly movable blocking member (80) between:
- a locking position in which it holds the electronic cylinder in its locked position, and
- a retracted position which corresponds to the unlocked position of the electronic cylinder,
- an electric actuator (82) able, in response to receiving an unlocking command, to move:
- from an active position in which it maintains the blocking member in its blocking position, towards
- an inactive position in which it authorizes the movement of the blocking member towards its retracted position,
- a microcontroller (200) configured:
- to assess the validity of access rights of a key introduced inside this electronic cylinder and,
- only if the access rights are evaluated as valid, generate the unlock command,
- a capacitor (C3) capable of supplying the electric actuator when it is charged to move the actuator from its active position to its inactive position, this capacitor comprising a first and a second electrode (230, 232),
- first and second electrical contacts (101, 102) capable of coming directly into electrical and mechanical contact on, respectively, first and second electrical contacts of the key when this key is inserted inside the electronic cylinder, to connect electrically these first and second electrical contacts (101, 102) of the electronic cylinder to respective electrodes of a battery housed inside this key,
- a first switch (Q6) comprising a control terminal (252), this first switch being able, in response to the reception of an electrical closing signal, to switch into a closed state in which it electrically connects the first electrode ( 230) from the capacitor to the first electrical contact (102) to charge the capacitor from the key battery,
characterized in that the electronic cylinder is configured to generate the electrical closing signal before the microcontroller has completed the evaluation of the validity of the access rights of the key. Cylinder according to claim 9, in which the cylinder comprises a voltage booster (260) connected between the first electrical contact (102) and the first electrode (230) of the capacitor (C3) to raise the voltage of the battery of the key used to charge the capacitor.