KR102182227B1 - Emergency Power Supply Apparatus of Digital Doorlock Using Smart Phone and Method Thereof - Google Patents

Abstract

An object of the present invention is to provide an emergency power supply device of a digital door lock using a smart phone and a method thereof, which can supply emergency power when the battery life of the digital door lock is exhausted using a smartphone, supply power to the digital door lock without purchasing or carrying a separate component, and automatically open a door, so that the convenience is greatly improved. To this end, the present invention has a magnetic induction coil, a rectifier circuit, and a constant voltage circuit at a digital door lock side, and a smart phone includes an oscillator and a magnetic induction coil connected to the oscillator, which are controlled by each MCU. Therefore, according to the present invention, it is possible to supply emergency power to the digital door lock with only a smartphone without separately purchasing and carrying a booster, so that an emergency door can be conveniently opened. In addition, without having a separate Bluetooth module that continuously consumes power, it is possible to open a door simply by touching a smart phone to the digital door lock, so that the convenience of use can be greatly improved.

Description

Emergency Power Supply Apparatus of Digital Doorlock Using Smart Phone and Method Thereof}

The present invention relates to an emergency power supply device and a method for a digital door lock using a smart phone. In particular, the user can supply emergency power to a digital door lock that cannot be started using a smart phone without carrying a separate auxiliary device. It relates to a digital door lock emergency power supply device and method using a smart phone.

As is well known, most digital door locks installed at the entrance use batteries as power, and the batteries are used outside the door if there is no one to open the door inside the door when the battery's lifespan is reached when the door is locked. There is no way to replace it.

Therefore, as shown in FIG. 3, a general digital door lock is provided with an emergency power supply terminal on one side of the outdoor device of the digital door lock to obtain an emergency battery in an emergency situation in which the door cannot be opened due to the end of the battery life and supply the emergency power. Opening is attempted by entering a password or touching a fingerprint while maintaining the power supply by contacting the terminal.

On the other hand, the emergency battery has a voltage of 9V, and it is not generally used, so it is difficult to use it for other purposes. As it is left unattended after one use, it is self-discharged and becomes unusable, and it is impossible to carry it in case of emergency. The cost is large due to the fact that it is discarded after one use.

In order to solve this problem, research on a method of using the power of the mobile communication terminal as an emergency power by connecting a mobile communication terminal such as a mobile phone to a conventional digital door lock has been conducted.

A representative example of this can be found in the Republic of Korea Utility Model Registration No. 20-0402152 (name: a device that supplies emergency power to a digital door lock using the power of a mobile communication terminal; hereinafter referred to as'cited invention').

This cited invention is a booster 220 that receives power from the power terminal 212 of the mobile communication terminal 210 as input power, boosts the voltage to generate an output voltage, and supplies the output voltage to the digital door lock 100. ), and further includes an authentication key 540 for authenticating an accessor, and the authentication key 540 is a device for supplying emergency power to a digital door lock that is attached to one side of the main body case. .

This cited invention is to supply emergency power to the digital door lock 100 by using the power of the mobile communication terminal 210, and to provide the convenience of enabling the door to open using the authentication key 540,

It is possible to use it conveniently because it does not require a one-time emergency battery, but above all, it is necessary to always carry the booster 220 purchased separately with the economic burden of purchasing the booster 220 separately. If it is not done, it will be useless and it is not being spread.

In addition, if the authentication key 540 is embedded in the booster 220, the manufacturing cost of the booster 220 increases as well as the volume increases, so portability further deteriorates, leaving room for improvement. .

Republic of Korea Utility Model Registration No. 20-0402152 (Name: a device that supplies emergency power to a digital door lock using the power of a mobile communication terminal)

In order to solve this problem, the present invention makes it possible to supply emergency power when the battery life of the digital door lock, which has been popularized in recent years, has expired, and in particular, it is possible to supply power to the digital door lock without purchasing a separate item and carrying it. The purpose is to propose an emergency power supply device for a digital door lock using a smart phone and a method thereof, which is economical and highly convenient by enabling automatic door opening without additional burden if necessary.

In order to achieve this object, the present invention provides a first magnetic induction coil installed inside the front side of the outer unit of a digital door lock, a position marking unit provided on the outer surface where the magnetic induction coil is installed, and rectification connected to both ends of the magnetic induction coil. The circuit, the constant voltage circuit connected to the output of the rectifier circuit, and the output of the constant voltage circuit are connected to a power supply that supplies power to the digital door lock, and connected to the first MCU of the digital door lock to transmit data through the first magnetic induction coil. In addition to being provided with a first data transmission and reception unit for transmitting and receiving,

Controlling the oscillation unit connected to the second magnetic induction coil of the smartphone, a second data transmission and reception unit for transmitting and receiving data to and from the first data transmission and reception unit of the digital door lock through the second magnetic induction coil, and the oscillation unit and the second data transmission and reception unit A second MCU is provided for the digital door lock, and the first MCU of the digital door lock wakes up by the power transmitted by the second magnetic induction coil of the smartphone, and transmits ping data and configuration data to power by the first magnetic induction coil. When the reception is maintained and the reception power, voltage, and current are within the normal range, the password transmission request data is transmitted to the 2nd MCU via the 1st and 2nd magnetic induction coils, and when there is the password data transmitted from the 2nd MCU, the stored password data Digital door lock using a smart phone to terminate power transmission by driving the deadbolt and supplying the PT termination packet data to the second MCU of the smartphone via the 1st and 2nd magnetic induction coils if they match compared to Provides an emergency power supply method.

Accordingly, the present invention has a useful effect in that emergency power can be supplied to the digital door lock with only a smartphone without separately purchasing and carrying items, as in the cited invention, thereby enabling an emergency door lock.

In addition, the present invention uses a magnetic induction coil to transmit and receive data, thereby minimizing cost and compactness by allowing the password stored in the smartphone to be entered directly into the digital door lock even without a separate Bluetooth module that always consumes power. According to the designed design, it is possible to provide high convenience by simply accessing the smartphone, supplying emergency power and completing the authentication procedure, allowing the door to be opened easily.

1 is a perspective view showing a device for supplying emergency power to a digital door lock using power of a conventional mobile communication terminal.
Figure 2 is a perspective view showing a device for supplying emergency power according to Figure 1;
Figure 3 is a photograph showing an emergency power supply terminal provided on the outside of a general digital door lock.
Figure 4 is a photograph illustrating the exterior appearance to which the present invention is applied.
Figure 5 is a circuit diagram showing the electrical configuration of the emergency power supply of the digital door lock using a smart phone according to the present invention.
6 is a flow chart showing the operation performed by the MCU of the smart phone in the present invention.
7 is a flowchart showing an operation performed by the MCU of the digital door lock in the present invention.
8 is a flow chart showing an operation according to another embodiment showing an operation performed by the MCU of the smart phone in the present invention.
9 is a flowchart showing an operation according to another embodiment performed by the MCU of the digital door lock in the present invention.

Hereinafter, embodiments of the present invention will be described in detail so that those of ordinary skill in the art may easily implement the present invention with reference to the accompanying drawings.

The present invention includes a first magnetic induction coil 101 installed inside the front of the outer unit of a digital door lock, and a position marking part 103 provided on the outer surface where the first magnetic induction coil 101 is installed,

As shown in Fig. 5, a rectifier circuit 104 connected to both ends of the first magnetic induction coil 101, a constant voltage circuit 105 connected to the output of the rectifier circuit 104, and the constant voltage circuit 105 The output of the digital door lock is connected to one of the input side and the output side of the power supply unit 106 that supplies power to the digital door lock, the first data transmission and reception unit 102 controlled by the first MCU 100 (Micro Control Unit) of the digital door lock. ), and the first data transmission/reception unit 102 and the first magnetic induction coil 101 are connected by a capacitor,

The oscillation unit 203 connected to the second magnetic induction coil 201 of the smartphone, a second data transmission/reception unit 202 connected to the second magnetic induction coil 201, the oscillation unit 203 and second data transmission/reception A second MCU 200 (Micro Control Unit) for controlling the unit 202 is provided.

In the present invention as described above, first, the first MCU 100 of the digital door lock can store a program in the internal or external memory so that the first MCU 100 of the digital door lock can perform the same as the flowchart shown in FIG. 7.

The second MCU 200 of the smartphone may also store a program in the internal and external memory of the smartphone so that the operation of the flowchart shown in FIG. 6 can be performed, and specific embodiments based on FIGS. 6 and 7 below. Explain.

In an emergency situation where the battery of the digital door lock is exhausted and the door cannot be opened, the present invention initiates operation by simply touching the designated location of the digital door lock with the smartphone, and using authentication means such as a touch pad or fingerprint. Since the door can be opened, it can be normalized by replacing the battery of the inside of the digital door lock installed indoors after opening.

That is, in the present invention, the door lock emergency power transmission app is downloaded and installed on the smartphone through the server, and the door lock emergency is operated as in the flowchart shown in FIG. 6 by operating the smartphone in an emergency situation where the door cannot be opened due to the end of the battery life. Execute the power transfer app to display the door lock emergency power transfer menu, and press the door lock emergency power transfer button with the second magnetic induction coil 201 in contact with the position marking unit 103 or after pressing the button. When the second magnetic induction coil 201 is brought into contact with the position marking unit 103, the second MCU 200 controls the oscillation unit 203 to operate the switching unit 204 to operate the second magnetic induction coil 201. It supplies switching power for 40 ms to 64 ms.

Accordingly, the AC output induced through the first magnetic induction coil 101 inside the position marking part 103 of the digital door lock in close contact with the second magnetic induction coil 201 of the smartphone is rectified in the rectifier circuit 104. Power is directly supplied to the entire digital door lock including the first MCU 100, and as shown in Fig. 7, the first MCU 100 of the digital door lock wakes up and various connection elements such as fingerprint recognition module, motor drive unit, touch pad, etc. After performing an initialization operation to check the data, Ping and configuration data are transmitted through the first data transmission/reception unit 102 and the first magnetic induction coil 101. This ping data indicates that power reception is required, and then data such as an identifier as a power reception element and a maximum amount of power to be supplied to the output of its rectifier are transmitted.

This ping and configuration data is transmitted to the second magnetic induction coil 201, which is in close contact with the first magnetic induction coil 101 and the position marking unit 103, and is transmitted through the second data transmission/reception unit 202. 2 Since it is applied to the MCU 200, the second MCU 200 receives it and stores the identifier, receives the maximum power amount data, adjusts the transmission power, and then the oscillator so that the transmission power is transmitted to the second magnetic induction coil 201 ( By controlling 203, the switching unit 204 is driven.

As a result, full-fledged power is induced in the first magnetic induction coil 101 that is in close contact with the second magnetic induction coil 201, which becomes direct current while passing through the rectifier circuit 104 and the constant voltage circuit 105 to become a digital door lock. After being adjusted to a voltage suitable for the operation of the digital door lock, it is supplied to a power supply unit 106 that can supply operating power.

In addition, if the power, voltage, and current received at this time are within the normal range, the digital door lock is in a normal operating state, and at this time, the user manipulates the touch pad to enter a number or authenticate with a card or fingerprint. If the data is the same as the data, the door is opened by driving the dead bolt, and the first MCU 100 transmits the PT (Power Transmission) end packet data to the smartphone side to the first data transmission/reception unit 102, and accordingly, the first self-induction Data is induced in the second magnetic induction coil 201 in close contact with the coil 101 and the second data transmission/reception unit 202 transmits the data to the second MCU 200. As a result, the second MCU 200 cuts off the transmission power by stopping the operation of the oscillation unit 203, and ends a series of operations.

In this way, the user operates the smart phone in a state in which the digital door lock is inoperative and touches the position marking part 103 of the digital door lock, and then operates only by operating the touch pad or performing fingerprint authentication. It is possible to obtain the convenience of being able to open the impossible digital door lock.

In addition, the present invention allows the second MCU 200 of the smartphone and the first MCU 100 of the digital door lock to perform the operation according to the flowchart shown in FIGS. 8 and 9, thereby indicating the location of the digital door lock for the smartphone being carried. It is possible to obtain the convenience of supplying emergency power to a digital door lock that cannot be operated by simply contacting the unit 103 and allowing it to be automatically opened.

In this embodiment, the member authentication of the door lock emergency power transmission app installed on the smartphone or the password of the digital door lock set in advance is stored in the smartphone so that the second MCU 200 can read it, or the smartphone is contacted with the digital door lock. In the event of an emergency situation where the operation of the digital door lock is not possible due to the end of the battery life when the one-time authentication for the opening of the digital door lock has been completed on the smartphone, the smartphone is connected to the location marking unit 103 of the digital door lock. Power communication and power supply are enabled and the operation starts, and the door can be opened without authentication means such as a touch pad or fingerprint, so that normalization can be performed very simply.

That is, by operating the smartphone in an emergency situation in which the digital door lock is inoperable, the door lock emergency power transmission menu appears as in the flow chart shown in Fig. 8, and by pressing the door lock emergency power transmission button, the second MCU 200 first starts the oscillation unit. The switching unit 204 is operated by controlling 203 to supply switching power to the second magnetic induction coil 201 for 40 ms to 64 ms.

Accordingly, the AC output induced through the first magnetic induction coil 101 that is in close contact with the position marking unit 103 is rectified by the rectifier circuit 104 and is directly transferred to the entire digital door lock including the first MCU 100. Power is supplied, and as shown in Fig. 9, the first MCU 100 of the digital door lock wakes up and performs an initialization operation to check various connection elements such as the fingerprint recognition module, motor drive unit, and touch pad, and then ping. (Ping) and configuration data is transmitted to the second magnetic induction coil 201 through the first data transmission/reception unit 102 and the first magnetic induction coil 101. This ping data indicates that power reception is required, and then data such as an identifier as a power reception element and a maximum amount of power to be supplied to the output of its rectifier are transmitted.

These ping and configuration data are applied to the second MCU 200 through the second magnetic induction coil 201 and the second data transmission and reception unit 202, which are in close contact with the first magnetic induction coil 101, so that the second MCU ( 200) receives this, stores the identifier, receives the maximum amount of power data, adjusts the transmission power, and controls the oscillator 203 so that the transmission power is transmitted to the second magnetic induction coil 201 to control the switching unit 204. It will be driven.

As a result, full-fledged power is induced in the first magnetic induction coil 101 that is in close contact with the second magnetic induction coil 201, which is converted to direct current through the rectifier circuit 104 and the constant voltage circuit 105 to form a digital door lock. After being adjusted to a voltage suitable for the operation of the digital door lock, it may be supplied directly to the digital door lock or may be supplied to the power supply unit 106 of the digital door lock.

At this time, if the received power, voltage, and current are within the normal range, the digital door lock is in a normal operating state. At this time, the first MCU 100 transmits a password request signal to the first magnetic induction coil through the first data transmission and reception unit 102. The data is transmitted to 101, and accordingly, the data is induced by the second magnetic induction coil and applied to the second MCU 200 through the second data transmission/reception unit 202. Therefore, the second MCU 200 recognizes the reception of the password request signal, and transmits the stored password or authentication data to the second magnetic induction coil 201 through the second data transmission/reception unit 202. Since such data is transferred to the first magnetic induction coil 101 and applied to the first MCU 100 through the first data transmission/reception unit 102, the first MCU 100 checks the authentication data or stores the received password with the stored password. It is checked to determine whether they match. As a result, if authentication is confirmed or the stored password and the entered password data are the same, the door is immediately opened by driving the dead bolt, and after the opening is completed, the PT end packet data is transmitted via the first data transmission/reception unit 102. And, this is also supplied to the second data transmission/reception unit 202 via the first magnetic induction coil 101 and the second magnetic induction coil 201, and the second data transmission/reception unit 202 transmits the PT end packet data. Upon receiving, the second magnetic induction coil 201 transmits power to be cut off, and a series of operations are terminated.

In this way, the user can supply power to the inoperable digital door lock by simply touching the smart phone to the position marking part 103 of the digital door lock while the digital door lock is inoperable, so that it is not only normalized, but can also be opened. As a result, it is possible to further enhance the convenience of use.

In addition, in the present invention, the first magnetic induction coil 101 and the capacitor are combined, and the first data transmitting and receiving unit 102 is configured by using an active element for signal amplification. Of course, the signal data can be detected by using.

In this embodiment, the first data transmitting and receiving unit 102 is connected between the first magnetic induction coil 101 and the first MCU 100, and the second data transmitting and receiving unit 202 is connected to the second MCU 200 and the second magnetic field. The digital door lock is connected between the induction coils 201 so that the first and second MCUs 100 and 200 exchange authentication data or password data after exchanging ping data and configuration data via the first and second magnetic induction coils. There is no need to install a separate short-range wireless communication device that continuously consumes power in the digital door lock, so it is easy to manage the battery of the digital door lock, and the compact design of the digital door lock is possible and there is no burden of manufacturing cost, so it is economical.

In the above, the technical idea of the present invention has been described with the accompanying drawings, but this is an illustrative description of the best embodiment of the present invention, not limiting the present invention, and those of ordinary skill in the art It is obvious that anyone can modify and imitate the dimensions, shapes, and structures within a range not departing from the scope of the technical idea of the present invention, and such modifications and imitations are included in the scope of the technical idea of the present invention.

100: first MCU 101: first magnetic induction coil 102: first data transmitting and receiving unit
103: position marking unit 104: rectifier circuit 105: constant voltage circuit
106: power supply unit 200: second MCU 201: second magnetic induction coil
202: second data transmission/reception unit 203: oscillation unit 204: switching unit

Claims (8)

The first magnetic induction coil installed inside the front of the outer unit of the digital door lock,
A position marking unit provided on an outer surface on which the first magnetic induction coil is installed,
A rectifier circuit connected to both ends of the first magnetic induction coil,
A constant voltage circuit connected to the output of the rectifier circuit,
The output of the constant voltage circuit is connected to a power supply for supplying power to the digital door lock, and connected to the first MCU of the digital door lock to transmit and receive data through the first magnetic induction coil.
An oscillator connected to the second magnetic induction coil of the smartphone,
A second data transceiving unit for transmitting and receiving data with a first data transmitting and receiving unit of the digital door lock through the second magnetic induction coil,
A second MCU for controlling the oscillation unit and the second data transmission/reception unit is provided,
The first MCU of the digital door lock wakes up by the power transmitted by the second magnetic induction coil of the smartphone, transmits ping data and configuration data to maintain power reception by the first magnetic induction coil, and receives power, When the voltage and current are within the normal range, the password transmission request data is transmitted to the 2nd MCU via the 1st and 2nd magnetic induction coils, and when there is the password data transmitted from the 2nd MCU, it is compared with the stored password data, and if they match, dead bolt Emergency power supply of a digital door lock using a smartphone, characterized in that power transmission is terminated by supplying PT termination packet data to the second MCU of the smartphone via the first and second magnetic induction coils after opening the door by driving Way. The method of claim 1,
An emergency power supply method for a digital door lock using a smartphone, characterized in that an active element for amplifying a signal provided in the first data transmission/reception unit amplifies a condenser connected to the first magnetic induction coil and a signal of the condenser. delete The method of claim 1,
The first data transmission/reception unit is connected between the first magnetic induction coil and the first MCU, and the second data transmission and reception unit is connected between the second magnetic induction coil and the second magnetic induction coil, so that the first and second MCUs connect the first and second magnetic induction coils. Emergency power supply method of a digital door lock using a smartphone, characterized in that the password data is exchanged after ping data and configuration data are exchanged via the pass. The method of claim 1,
When the door lock emergency power transmission menu starts, the second MCU of the smartphone allows wireless power to be transmitted for 40 ms to 64 ms, and waits for reception of ping data and configuration data, and when the corresponding data is received, the second self-induction until the PT end packet reception time Emergency power supply method of a digital door lock using a smartphone, characterized in that transmitting power to the coil. The method of claim 1,
The first MCU of the digital door lock wakes up by the power transmitted by the second magnetic induction coil of the smartphone, transmits ping data and configuration data to maintain power reception by the first magnetic induction coil, and receives power, If the voltage and current are in the normal range and there is no password data transmitted from the 2nd MCU, the user waits for the authentication means signal input,
When the authentication means signal is input by the user, if the authentication signal matches the stored data, the dead bolt of the digital door lock is driven to open the door, and then the PT end packet data is supplied to the second MCU of the smartphone via the first and second magnetic induction coils. Emergency power supply method of a digital door lock using a smart phone, characterized in that it is so.
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