• 专利附录
  • 专利说明
  • 权利要求
  • 类似技术
  • 同族专利
  • 引用文献
  • 法律状态
  • 优先权
    • 专利摘要:
    The electric lock arrangement according to the invention comprises a capacitor unit (6) for storing reserve power and a test circuit (7) for testing the capacitor unit (6). The test circuit (7) is arranged to connect the test load (8) to the capacitor unit (6) to test its condition, and to measure the voltage of the capacitor unit (6) before, shortly after, the test load, and shortly before the test load.
    公开号:FI20175461A1
    申请号:FI20175461
    申请日:2017-05-23
    公开日:2018-11-24
    发明作者:Taneli Härkönen;Mika Purmonen;Markku Makkonen;Esko Strömmer
    申请人:Abloy Oy;
    IPC主号:
    专利说明:

    Electric lock arrangement
    Engineering
    The invention relates to an electric lock arrangement using an external power source. The external power supply supplies the actuator or actuators with the energy required to control the actuator arrangement from the locking state to the unlocked state and vice versa.
    Prior art
    It is known to use an external power source to supply electrical energy to an electrical lock arrangement to provide its electrical actuator or actuators with the energy it requires. The electric actuator is, for example, a solenoid or an electric motor communicating with the rear locking means. The rear locking means 15 may be controlled from the locking position to the unlocked position and vice versa by an electric actuator or actuators.
    Unlocked space means a space where the lock of the locking arrangement can enter the lock body without being blocked by the rear locking means. By locking means is meant that the rear locking means prevent the bolt from moving into the lock body, whereby the part of the bolt outside the lock body locks, for example, the door 20 on which the lock body is mounted against the door frame.
    In addition, the electrical lock arrangement may comprise a button space in which the lock mode is controllable by an open mode. In this case, turning the knob connected to the lock body will release the locking space to the unlocked position. The electric actuator or other electric actuator is arranged to direct the electrical lock arrangement to or from the button space.
    The electrical lock arrangement thus comprises a connection to an external power source which is connected to the electric actuator or actuators. If a fault occurs in the power source or in the transmission link between the electrical lock arrangement and the power source during which it is unable to transfer electrical power to the electrical lock arrangement, it may be detected at the connection of the external power source. For such situations, the electrical lock arrangement often also comprises electrical energy in the emergency power supply circuit, the capacitor unit in the electrical lock arrangement.
    which is to store the storage power when connected to the interface and comprises the reserve power. The electrical power of the emergency power supply circuit may not be obtained from an external power supply
    As the capacitor unit ages, its charge capacity may decrease with age.
    Although capacitors are relatively long-lived, their charge capacity may decrease sufficiently over time, thereby rendering them unable to perform their required function. As a result, the aged capacitor unit of the electric lock arrangement may no longer be able to charge enough electrical energy to satisfy the electrical actuator's energy requirement during an external power failure. This can pose a safety hazard when the electric lock arrangement cannot be controlled to 15 lock or unlock positions. The user of the electrical lock arrangement should periodically determine the condition of the capacitor unit manually. Attention is not always paid to this, so when a fault occurs, the locksmith is called for on-site service.
    20175461 prh 23 -05- 2017
    Brief Description of the Invention
    The object of the invention is to provide an electric lock arrangement in which the condition of the capacitor unit is monitored by the electrical lock arrangement itself. In this case, no special monitoring measures are required of the user of the electric lock arrangement. Potential security incidents can be anticipated, thus avoided or at least minimized. This is achieved as described in the independent claim. The dependent claims describe various embodiments of the invention.
    The electric lock arrangement according to the invention comprises a bogie 1, a bogie locking means 2 and an electric actuator 3 for opening and locking the electric lock arrangement. The rear locking means 2 are in communication with the latch 1, and the electrical actuator 30 is in communication with the rear locking means for controlling them from the locking state to the unlocked state and vice versa. The electric lock arrangement also comprises a connection 4 to an external power supply, which connection is connected to the electric actuator 3 and a backup power supply circuit 5 .. The backup power supply circuit comprises a capacitor unit 6 for storing reserve power.
    The electric lock arrangement also comprises a test circuit 7 for testing capacitor unit 6. Test circuit 7 is arranged to connect test load 8 to capacitor unit 6 to test its condition, and measure voltage of capacitor unit 6 before, slightly after test load, and shortly before test load is disconnected.
    The electric lock arrangement also comprises a control unit 9 arranged to control the test circuit 7, to calculate on the basis of said measurements the ESR (equivalent series resistance) and capacitance gap of the capacitor unit 6, and to determine the condition of the capacitor unit based on these values.
    List of figures
    The invention will now be described in more detail with reference to the accompanying figures,
    20175461 prh 23 -05- 2017
    whereFigure 1 illustrates an example of the invention 20electronic lock arrangement,Figure 2 shows another example of the inventionelectronic lock arrangement,Figure 3 illustrates an example of a voltage curve of a capacitor unit and a measurement according to the invention, 25 Figure 4 gives another example of the voltage curve of a capacitor unit and the measurement according to the invention,Figure 5 illustrates a circuit diagram example of the inventiontesting the capacitor unit; and
    20175461 prh 23 -05- 2017
    Fig. 6 shows another circuit diagram example of testing a capacitor unit according to the invention.
    Description of the Invention
    Figure 1 shows an example of an electric lock arrangement according to the invention. An electric lock arrangement comprising a caliper 1, a caliper rear locking means 2 and an electric actuator 3 for opening and locking the electrical lock arrangement. The electric actuator 3 is a solenoid or an electric motor. The rear locking means 2 are in communication with the latch 10, and the electrical actuator 3 is in communication with the rear locking means for controlling them from the locking position to the unlocking position and vice versa. The electrical actuator may directly or through some part (s) communicate with the rear locking means to control them.
    The electric lock arrangement also comprises a connection 4 to an external power supply, which connection 15 is connected to the electric actuator 3. The electrical lock arrangement also has a backup power supply circuit 5, which is also connected to the connection 4 and comprises a capacitor unit 6 for storing reserve power. The backup power supply circuit is connected to supply electrical energy to the actuator 3 when there is a fault in the external power supply or its transmission connection that prevents the power transmission to terminal 4. The connection 20 may be a wire connection or a wireless connection (such as an induction connection).
    The electrical lock arrangement comprises a test circuit 7 for testing capacitor unit 6. Test circuit 7 is arranged to connect test load 8 (Figure 5) to capacitor unit 6 to test its condition, and measure capacitor unit 6 voltage before test load 8, after. The electric lock arrangement also comprises a control unit 9 arranged to control the test circuit 7, based on said measurements, to calculate the ESR value and capacitance split of the capacitor unit 6, and on the basis of these values determine the condition of the capacitor unit.
    20175461 prh 23 -05- 2017
    Figure 2 shows an example of another embodiment of an electric lock arrangement. In this embodiment, the electric lock arrangement comprises a lock body 16, as well as the embodiment of Figure 1, in addition to a separate control module 17. When all of the above and other 5 parts not included in the lock body of Figure 1 are provided, the separate control module 17 In the example of Figure 2, the control module comprises a control unit 9, a reserve power supply circuit 5, and a communication unit 18, which will be described in more detail later. Of course, another kind of control between the control module and the lock body is also possible. For example, a control unit 10 and a capacitor unit 6 may be placed in the control module, whereupon the other parts of the emergency power supply circuit are in the lock body 16. It is also possible that only the control unit 9 is located in the control module. parts using a capacitor unit.
    Figures 1 and 2 show that the lock body has a breast plate 19 having a hole for the bolt 1. The lock body may also be provided with a button connection 20 whereby by turning the button connected thereto, the lock 1 can be moved inside the lock body. The button locked electrical lock arrangement may also be arranged to comprise a button space in which the lock lock mode of the electrical lock arrangement is operable by a button 20 (i.e., by turning the button). In an electric lock arrangement comprising a button space, an electric actuator 3 or another electric actuator 15 is arranged to direct the electrical lock arrangement into or out of the button space.
    Figures 1 and 2 also show that the electric lock arrangement may also be provided with an audio signal device 13, a light signal device 14 or a communication unit 18 connected to the control unit 9 and arranged to inform the user of the electrical lock arrangement of the capacitor unit 6 if the capacitor unit is defective. It is cost effective to use only one device to inform the user, but it is also possible to use multiple devices. The audio signal device may be, for example, a buzzer or other audio device. The light signal device may be, for example, an LED lamp or other light source. The communication unit can transfer information about the condition of the capacitor unit to, for example, a monitoring center that monitors all
    20175461 prh 23 -05- 2017 electric lock arrangements and their status. It can also be seen from Figures 1 and 2 that the electric lock arrangement may also comprise a switching circuit 5A, which may be integrated into a backup power supply circuit 5, or may be a separate circuit connected to the emergency power supply circuit. The switching circuit directs electrical energy from the connection 4 to the backup power supply circuit 5 and to the actuator (s). It is practical that the control unit also receives its electrical energy from the connection 4, although it is not shown in the figures. Also, a control unit, such as other electrical devices of the electric lock arrangement, may be arranged to receive electrical energy from the capacitor unit during a fault. The figures in this description are simplified exemplary descriptions, so that in addition to the parts shown therein, the actual embodiments that may be implemented may also include other parts that are not essential to the practice of the invention. Thus, an electric lock arrangement according to the invention can be prepared by one skilled in the art on the basis of this description.
    As can be seen in Figure 2, the electric power supply can be provided directly 15 to both the lock body 16 and the control module 17 depending on how the parts of the electrical lock arrangement are divided between the lock body and the control module. The electric power transmission can also be implemented in other ways, for example, so that the power supply connection of the external power source is solely to the control module 17, from which electrical energy is further transmitted to the lock body 16. The control module 17 and its components such as the control unit 9
    The electric lock arrangement may also comprise a temperature sensor 12, the operation of which will be described in more detail later.
    Figures 3 and 4 show examples of the voltage curve 21 of capacitor unit 6 during testing and measurement according to the invention. Before the actual test time 10, the voltage of the capacitor unit 6 is measured, at the time T1 in the example of Figure 3. The test time begins when the test load 8 (Fig. 5) is connected to the capacitor unit at time TA. The test time ends when the test load is disconnected from the capacitor unit at TL. When the test load is applied at 30 TA, the voltage drops as current flows through the test load. Assume that the current is constant with a voltage change
    20175461 prh 23 -05- 2017
    AUi = ResrI (1) where AUi is the voltage drop at TA, R E sr is the ESR value of the capacitor unit and I is the current flowing through it.
    Voltage Uta with a lower instantaneous TA can be estimated by interpolation using values from other measurement moments and the time difference between measurements. The voltage is measured a second time shortly after the test load is applied at time T2 to give Ut2. The voltage is also measured for the third time at T3 shortly before the test load is disconnected at TL to obtain a measurement value U T 3. The voltage curve has decreased sufficiently between T2 and T3 so that there is a clear difference between T2 and T3. Measurements give the slope k = (U T2 - U T3 ) / (T3 - T2) (2)
    Uta = U T2 + k (T2-TA) (3)
    Assume that current I remains constant throughout the measurement and passes through the test load. When Equation 1 is also used as a test load voltage formula, R ES r can be derived from the formula
    Resr = Rl (Uti-Uta) / Uta (4) where R l is the test load 8 or load resistance.
    Using the slope k, the equation for the capacitance is obtained
    C = (U T 2 + U T 3 ) / 2k (R ESR + R 1) (5)
    As can be seen, three voltage measurements can determine the ESR value and capacitance value of a capacitor unit. Accuracy to the measurement is obtained when using, for example, the method of Figure 4.
    Measuring the voltage of the capacitor unit 6 before applying the test load 8, the second time slightly after the test load is applied, and the third time slightly before the test load is disconnected, can be arranged to be performed.
    20175461 prh 23 -05-2017 at predefined measurement intervals T1P, T2P, T3P such that multiple voltage measurements are performed during each measurement interval. The control unit 9 is arranged to calculate from the voltage measurements of the measurement interval an average value of the voltage used as the measurement value of each measurement interval T1P, T2P, T3P. In such a method 5, the average time of the measurement interval can be considered as the measurement moment. Thus, in the manner of Figure 4, the effect of a single measurement error, such as the effect of measurement noise, can be reduced.
    The measurement interval can be, for example, between 50 and 150 ms and the number of measurements within the measurement interval can vary, e.g., between 10 and 150. A second measurement 10 after disconnecting the test load 8 can be arranged to be performed within 5 to 400 ms of the disconnection of the test load, and said third measurement before disconnecting the test load 8 can be arranged to be performed 5 to 300 ms before the test load is disconnected. The control unit 9 is arranged to use a predetermined test time 10 for the test circuit 7. The predetermined 15 test times can be, for example, about 1 second. When the test time is long enough, the voltage is lowered sufficiently so that the aforementioned slope k can be calculated more reliably. The test time is predefined, as are the measurement moments T1, T2 and T3.
    Because the actuator (s) of the electrical lock arrangement affect how large the 20 and the capacitive capacitor unit should be in order to supply sufficient electrical energy during a fault, the capacitance split of the capacitor unit is specific to the electrical lock arrangement. Accordingly, since there are many electrical lock arrangements, the value of the capacitor unit may vary greatly between different electrical lock arrangements.
    The capacitor unit and also the load resistor therefore also affect the test time, which is also specific to the electrical lock arrangement. Testing time ranges from 0.8 to 10 s with different electric lock arrangements. Testing time for a special purpose electric lock arrangement may also be outside this time period.
    20175461 prh 23 -05- 2017
    Thus, the test time is such that there is sufficient time between the second and third measurements mentioned above to obtain accuracy for calculating the capacitance based on the measurements, and on the other hand it is sought to keep the test time short in order to leave sufficient charge in the capacitor unit.
    Thus, the control unit 9 is arranged to control the test circuit 7, to calculate on the basis of said measurements the ESR value and capacitance of the capacitor unit 6 and to determine the condition of the capacitor based on these values. The control unit 9 is also arranged to control the test circuit 7 at certain intervals to test the condition of the capacitor unit 6. The time between tests can be e.g. 10-11-14 hours.
    The test and test circuit 7 are dimensioned such that sufficient capacitance remains on the capacitor unit 6 after the test load 8 is disconnected.
    In addition, the control unit 9 is arranged to interrupt the testing of the capacitor unit 6 if a failure of the connection 4 to the external power supply 15 is detected during the test time 10. In other words, the capacitor unit can supply reserve power to the electric actuator outside of the test time and, if necessary, during the predetermined test time when the test is interrupted.
    Figures 5 and 6 illustrate exemplary circuit diagrams of test circuit 7 and reserve power supply circuit 5. When the capacitor unit 6 is not tested, the backup power supply circuit 20 may charge the capacitor unit to maintain its maximum charge. The control unit 9 can monitor the reserve power supply circuit 5. When the capacitor unit is fully charged / charged, it need not be charged and charging may be interrupted. Charging will be suspended during testing. When charging is interrupted in the embodiment of Figure 5, transistor TR2 25 is driven to a conductive state by a CHARGE control set to a suitable value by resistor R6. The conducting state of transistor TR2 changes the control of transistor TR3 through resistor R5, whereby transistor TR3 does not conduct, and the charging current does not pass through resistor R4. Diode D1 prevents a direct connection of the charging current to the capacitor unit.
    When the capacitor unit is tested, it is not charged. The test load 8 30 is coupled to the capacitor unit 6 by supplying a resistor R3 to a suitable value
    20175461 prh 23 -05- 2017 set control voltage TEST to transistor TR1, whereby it goes into conductive state and current can pass through load resistor. The voltage measurement V of the capacitor unit is set to a suitable level by resistors R1 and R2 and filtered by capacitor C1. It should be noted that the capacitor unit 6 may comprise one or more capacitors 6A. If there are several capacitors, they are connected in series and / or in parallel. The capacitor or capacitors may also be so-called. supercapacitors.
    FIG. 6 illustrates connections between the test circuit 7 and the backup power supply 5 to other parts, such as the control unit 9. As described above, the switching circuit 5A may be integrated with the backup power supply 5 or be a separate circuit connected to the backup power supply. Figure 6 illustrates the operation of the switching circuit with switches 5B and 5C. When the switch 5C is closed and the switch 5B is open, the actuator 3 receives its energy from an external power source (denoted as supply voltage in Figures 5 and 6). When the switch 5C is open and the switch 5B is closed, the actuator 3 receives its energy from the reserve power supply circuit 5.
    The representation of Fig. 6 is a simplified circuit diagram representation, so it is clear that the structure of the switching circuit 5A may be different from that of Fig. 6.
    The electric lock arrangement comprises an ESR limit and a capacitance limit. The control unit 9 is arranged to compare the measured ESR value and the capacitance value with the threshold values, and in response to determine the condition of the capacitor unit 6.
    The limit values may thus comprise, at their simplest, one ESR value and one capacitance value, such as 800 mQ for the ESR limit and 350 mF for the capacitance. However, to increase accuracy, it is possible to include ESR limits and capacitance limits for different temperatures. The ESR and capacitance limits used are then higher as the temperature drops. Correspondingly, the limit values 25 used are lower when the temperature rises. The limit values can be expressed in the form of a table, so that the electrical lock arrangement comprises a limit table. In order to benefit from the various temperature limits, the electrical lock arrangement may comprise a temperature sensor 12 for measuring temperature. The temperature sensor is connected to the control unit 9. Since the table does not necessarily include the values mentioned for each different temperature, but only for some temperatures, the control unit can be arranged to interpolate the ESR limit.
    20175461 prh 23 -05- 2017 value and capacitance limit value for the measured temperature using the limit table values if the measured temperature is not in the limit value table.
    If the measured ESR value is greater than the ESR threshold, then the control unit can determine, based on one comparison, that the capacitor unit 5 is defective. Correspondingly, if the measured capacitance gap is less than the limit value for capacitance, then the control unit may determine based on one comparison that the capacitor unit is defective. However, it is more certain that the control unit 9 is arranged to operate several times to determine the condition of the capacitor unit 6 from a functioning capacitor unit to a faulty capacitor unit. For example, if six consecutive comparisons indicate a capacitor unit is defective, it is only then that the capacitor unit is determined to be defective. For the purpose of fault indication, it is sufficient for either of the measured ESR values or capacitance values to indicate by comparison that the ESR value is too high or the capacitance gap is too small. When the capacitor unit is determined to be defective 15, the user may be informed by the audio signal device 13, the light signal device 14, or by the communication unit 18.
    The ESF and capacitance limits are related to the actuator used in the electric lock arrangement, e.g., the power and dimensioning of the solenoid or electric motor. The design, design and dimensioning of the test circuit affect the limit values. In other words, the limit values depend on the embodiment of the electric lock arrangement.
    It is convenient to implement the control unit so that it comprises a processor and a memory. The memory may include the above-mentioned thresholds, for example as a table of thresholds. In addition, the control unit may be arranged to perform the necessary control commands so that the actuator (s) and possibly other components receive electrical energy during the failure of the external power supply, at least at the beginning of the fault, to move the electric lock arrangement to the desired state.
    The invention provides a relatively simple, robust, and reliable way of measuring the condition of an capacitor unit of an electric lock arrangement without user intervention. Since the electrical lock arrangement itself monitors the condition of the capacitor unit 6, maintenance of the electrical lock system 30 is easier. Thus, the reliability and safety of the electric lock arrangement will also be improved, as its functionality and condition will be more reliable.
    The electric lock arrangement according to the invention can be implemented by various embodiments. Thus, the invention is not limited to the examples set forth herein, but may be implemented in various ways within the scope of the independent claim.
    权利要求:
    Claims (18)
    [1]
    An electric lock arrangement comprising a caliper (1), a caliper rear locking means (2) and an electric actuator (3) for opening and locking an electrical lock assembly, which lock locking means (2) is connected to a caliper (1), and
    5 for locking means for controlling them from the locking state to the unlocked state, and vice versa, the electric locking arrangement also comprising a connection (4) to an external power source which is connected to the electrical actuator (3); capacitor unit (6) for storing reserve power, characterized in that the electric lock arrangement comprises a test circuit (7) for testing a capacitor unit (6) arranged to connect a test load (8) to the capacitor unit (6) for testing its condition; the voltage before the test load (8) is applied, the second time after the test load is applied, and the third time before the test load is disconnected a second time, and wherein the electric lock arrangement comprises a control unit (9) to calculate the ESR value and capacitance value of 20 capacitor units (6) based on said measurements, and to determine the condition of the capacitor unit based on these values.
    [2]
    An electric lock arrangement according to claim 1, characterized in that the control unit (9) is arranged to use a predetermined test time (10) for the test circuit (7).
    25
    [3]
    An electric lock arrangement according to claim 1 or 2, characterized in that the limit values comprise ESR limit values and capacitance limit values for different temperatures, which the control unit (9) is arranged to compare the measured ESR value and the capacitance value with the limit values. (6) fitness.
    30
    [4]
    An electric lock arrangement according to claim 3, characterized in that it comprises a limit value table comprising ESR and capacitance limit values.
    20175461 prh 23 -05- 2017
    [5]
    An electric lock arrangement according to claim 3 or 4, characterized in that the electrical lock arrangement comprises a temperature sensor (12) for measuring the temperature which the temperature sensor is connected to the control unit (9), and the control unit arranged to interpolate the ESR limit and capacitance limit using temperature
    5 limit values if the measured temperature is not within the limits.
    [6]
    An electric lock arrangement according to claim 5, characterized in that the control unit (9) is arranged to operate several times to determine the condition of the capacitor unit (6) from a functioning capacitor unit to a faulty capacitor unit.
    10
    [7]
    An electric lock arrangement according to any one of claims 2 to 6, characterized in that the control unit (9) is arranged to control the test circuit (7) at certain intervals to test the condition of the capacitor unit (6).
    [8]
    An electric lock arrangement according to claim 7, characterized in that the test circuit (7) is dimensioned so that sufficient capacitance is left in the capacitor unit (6).
    15 after disconnecting the test load (8).
    [9]
    An electric lock arrangement according to claim 8, characterized in that the control unit (9) is arranged to interrupt the testing of the capacitor unit (6) if a fault in the connection (4) to the external power source is detected during the testing time (10).
    [10]
    An electric lock arrangement according to one of claims 1 to 9, characterized in that the electrical lock arrangement 20 comprises an audio signal device (13), a light signal device (14) or a communication unit (18) connected to the control unit (9) and arranged to inform the user of the electrical lock arrangement if the capacitor unit is defective.
    [11]
    An electric lock arrangement according to claims 2-10, characterized in that the 25 pre-determined test times (10) are 0.8 to 10 seconds.
    [12]
    An electrical lock arrangement according to claim 11, characterized in that the voltage measurements of the capacitor unit (6) before the test load (8), the second time after the test load is applied, and the third time before the test load is disconnected, are arranged to be performed
    30 measurement intervals T1P, T2P, T3P, such that several voltage measurements are performed during each measurement interval, of which the control unit (9) is arranged to calculate
    20175461 prh 23 -05- 2017 average of the voltage used as the measurement value for each measurement interval T1P, T2P, T3P.
    [13]
    An electric lock arrangement according to any one of claims 2 to 12, characterized in that said second measurement after the application of the test load (8) is arranged.
    5 to be carried out within 5 to 400 ms of disconnecting the test load, and said third measurement before disconnecting the test load (8) is arranged to be performed within 5 300 ms prior to disconnecting the test load.
    [14]
    An electric lock arrangement according to any one of claims 2 to 13, characterized in that the capacitor unit (6) comprises at least one capacitor.
    15. An electric lock arrangement according to claim 14, characterized in that the electric actuator (3) is a solenoid or an electric motor.
    An electric lock arrangement according to any one of claims 2 to 15, characterized in that the electrical lock arrangement is arranged to comprise a button space in which the lock mode is operable by a button and an electric actuator (3) or another electric actuator.
    [15]
    15 (15) is arranged to direct the electrical lock arrangement into or out of the button space.
    [16]
    An electric lock arrangement according to any one of claims 1 to 16, characterized in that the electrical lock arrangement comprises a lock body (16) on which said parts of the electrical lock arrangement are located.
    [17]
    An electric lock arrangement according to any one of claims 1 to 16, characterized in that the electric lock arrangement comprises a lock body (16) and a separate control module (17), in which the control unit (9) and the capacitor unit (6) are located; inside the control unit and capacitor unit operating parts.
    [18]
    An electrical lock arrangement according to any one of claims 1 to 16, characterized by
    The electric lock arrangement comprises a lock body (16) and a separate control module (17), in which the control module (9) is located, and which control unit can be electrically connected to the lock body by the control unit parts therein.
    类似技术:
    公开号 | 公开日 | 专利标题
    FI128211B|2019-12-31|Electric lock arrangement
    US10174527B2|2019-01-08|Backup energy source for automotive systems and related control method
    CA2634309C|2016-02-02|Battery system and management method
    CN101625399B|2014-03-05|Temperature monitoring in uninterruptible power supply systems using synthetic loading
    CN102064597B|2015-03-25|Energy storage device
    US10012696B2|2018-07-03|Battery-assisted safety circuit monitoring system
    BR112014002825B1|2021-04-20|test method of an elevator installation and monitoring set configured to perform the test method
    BRPI0921866B1|2019-04-24|TEST SET, LIFT DEVICE AND HARDWARE CONTROL PROCESS.
    CN102798782B|2015-05-20|High-voltage insulation resistance monitoring alarm
    US9979180B2|2018-05-22|Electronic fuse
    BR102013005184A2|2016-06-28|electrical installation method and maintenance device
    DE102013220684A1|2015-04-16|A battery management system for monitoring and controlling the operation of a rechargeable battery and battery system having such a battery management system
    JP2015529332A|2015-10-05|Circuit for guiding current
    CN201150008Y|2008-11-12|Accumulator on-line monitoring type UPS uninterrupted power supply system
    CN103048945B|2017-07-18|Circuit arrangement and method for operating housed device
    BR102014007710A2|2015-11-03|method for detecting and predicting a power failure in a node of a power grid
    CN201291774Y|2009-08-19|Electrokinetic cell package flooding detecting device
    EP3471186A1|2019-04-17|Battery system with battery cell internal cell supervision circuits
    ES2643471T3|2017-11-23|Bistable safety relay
    CN104459524A|2015-03-25|Auxiliary unit, electric system comprising a circuit breaker and one such auxiliary unit, and method for determining a cause of opening of the circuit breaker
    KR101244342B1|2013-04-19|Method and System for Real Time Remote Battery Inspection
    CN103292926A|2013-09-11|Device and method for acquiring excitation data of superconducting magnets
    JP2016051404A|2016-04-11|Lock management apparatus and lock management system using the same
    US10670685B2|2020-06-02|Method for detecting a fault in an electricity meter including a breaking unit
    US10073149B2|2018-09-11|Method and system for performing diagnostics and monitoring a DC subsystem
    同族专利:
    公开号 | 公开日
    US20180340351A1|2018-11-29|
    EP3407308B1|2021-06-30|
    US11220843B2|2022-01-11|
    FI128211B|2019-12-31|
    EP3407308A1|2018-11-28|
    CN108930453A|2018-12-04|
    FI20175461A|2018-11-24|
    引用文献:
    公开号 | 申请日 | 公开日 | 申请人 | 专利标题
    US4967305A|1989-01-06|1990-10-30|Datatrak, Inc.|Electronic door lock apparatus, system and method|
    US6005487A|1990-05-11|1999-12-21|Medeco Security Locks, Inc.|Electronic security system with novel electronic T-handle lock|
    JP3850311B2|2002-02-21|2006-11-29|オムロン株式会社|Remaining life prediction notification method and electronic device|
    US7487391B2|2005-08-04|2009-02-03|Dot Hill Systems Corporation|Storage controller super capacitor adaptive life monitor|
    FI120109B|2006-05-02|2009-06-30|Abloy Oy|lock Body|
    US8154259B2|2007-07-25|2012-04-10|Agiga Tech Inc.|Capacitor save energy verification|
    US8607076B2|2009-06-26|2013-12-10|Seagate Technology Llc|Circuit apparatus with memory and power control responsive to circuit-based deterioration characteristics|
    US8065562B2|2009-06-26|2011-11-22|Seagate Technology Llc|Systems, methods and devices for backup power control in data storage devices|
    IN2014KN01565A|2012-01-16|2015-10-23|Schneider Electric Buildings|
    CN110259293A|2012-12-24|2019-09-20|麦格纳覆盖件有限公司|Method for controlling the electronics latch assembly of the closing device of motor vehicles|
    US9673868B2|2013-05-16|2017-06-06|Microchip Technology Incorporated|Wireless door lock power transfer system having communications capabilities|
    CN104716814B|2013-12-13|2018-10-26|光宝电子有限公司|Power system and its control method|
    CN203662263U|2014-01-14|2014-06-25|厦门汉凌达智能科技有限公司|Express dispatching cabinet|
    US9567773B2|2014-02-25|2017-02-14|Schlage Lock Company Llc|Electronic lock with selectable power off function|
    US9740258B2|2014-03-24|2017-08-22|Intel Corporation|Hold-up energy storage and management|
    WO2015183250A1|2014-05-28|2015-12-03|Schneider Electric Buildings Llc|Estimation of the remaining lifetime of a supercapacitor|US11180929B2|2017-09-19|2021-11-23|Sargent Manufacturing Company|Low temperature control of lock actuator|
    US10693310B2|2017-10-31|2020-06-23|Sargent Manufacturing Company|Hiccup charger|
    法律状态:
    2019-12-31| FG| Patent granted|Ref document number: 128211 Country of ref document: FI Kind code of ref document: B |
    优先权:
    申请号 | 申请日 | 专利标题
    FI20175461A|FI128211B|2017-05-23|2017-05-23|Electric lock arrangement|FI20175461A| FI128211B|2017-05-23|2017-05-23|Electric lock arrangement|
    EP18169283.1A| EP3407308B1|2017-05-23|2018-04-25|Electronic lock assembly|
    US15/987,592| US11220843B2|2017-05-23|2018-05-23|Electronic lock assembly|
    CN201810500569.2A| CN108930453A|2017-05-23|2018-05-23|Electronics lock set|
    [返回顶部]