CN110761621A - Full-automatic sliding cover wake-up circuit and device of intelligent lock and operation method of full-automatic sliding cover wake-up circuit - Google Patents

Abstract

The invention discloses a full-automatic sliding cover awakening circuit of an intelligent lock, which comprises a main control module, a driving module, a touch sensor and a motor, wherein the touch sensor is used for sensing an awakening trigger signal; the main control module is electrically connected with the touch sensor; the driving module is respectively electrically connected with the main control module and the motor. The invention provides a full-automatic sliding cover awakening circuit, a full-automatic sliding cover awakening device and an operation method of the full-automatic sliding cover awakening circuit, which are simple in structure and practical and can effectively drive a sliding cover of an intelligent lock.

Description

Full-automatic sliding cover wake-up circuit and device of intelligent lock and operation method of full-automatic sliding cover wake-up circuit

Technical Field

The invention relates to the technical field of intelligent locks, in particular to a full-automatic sliding cover wake-up circuit and device of an intelligent lock and an operation method thereof.

Background

With the progress of human society, the increase of social wealth and the improvement of technological level, the living standard of people is also improved, so that people pay more and more attention to personal property safety. The door lock is used as the guarantee of property safety and is of great importance in daily life of people. The sliding cover for protecting the intelligent lock is usually installed on the existing intelligent lock, but the sliding cover circuit of the existing intelligent lock is complex, and the wake-up circuit of the sliding cover is usually integrated in the intelligent lock system, so that the function is easy to make mistakes and the maintenance is difficult.

Disclosure of Invention

Aiming at the technical problems, the invention provides a full-automatic sliding cover awakening circuit, a full-automatic sliding cover awakening device and an operation method of the full-automatic sliding cover awakening circuit, which are simple and practical in structure and can effectively drive a sliding cover of an intelligent lock. The technical scheme is as follows:

the embodiment of the invention provides a full-automatic sliding cover awakening circuit of an intelligent lock, which comprises a main control module, a driving module, a touch sensor and a motor, wherein the touch sensor is used for sensing an awakening trigger signal, and the motor is used for executing the sliding cover to slide upwards or downwards;

the main control module is electrically connected with the touch sensor;

the driving module is respectively electrically connected with the main control module and the motor.

As a preferred scheme, the driving module comprises a driving chip and an overvoltage protector;

the control signal input end of the driving chip is correspondingly connected to the control signal output port of the main control module, and the overvoltage protector is connected to the control signal input end of the driving chip in parallel;

the power supply input port of the driving chip is connected with a power supply, and the grounding end of the driving chip is grounded;

and the control signal output end of the driving chip is connected with the motor.

As a preferred scheme, the control signal input end of the driving chip is divided into a forward signal input end and a reverse signal input end; the forward rotation signal input end and the reverse rotation signal input end are respectively and correspondingly connected to a first control signal output port and a second control signal output port of the main control module;

the control signal output end of the driving chip is divided into a forward rotation signal output end and a reverse rotation signal output end; the positive rotation signal output end and the reverse rotation signal output end are respectively and correspondingly connected to a first control signal input port and a second control signal input port of the motor.

As a preferred scheme, the power supply input port of the driving chip is connected to a power supply, and specifically includes:

the driving chip comprises a first power supply input port and a second power supply input port;

the first power supply input port is connected with the cathode of the diode so as to be connected with the diode in series and is connected with the power supply in parallel with the first capacitor;

the second power input port and the second capacitor are connected to a power supply in parallel.

As a preferred scheme, the ground terminal of the driving chip is grounded, specifically:

the driving chip comprises a first grounding end and a second grounding end;

the first grounding end is grounded after being connected with the resistor in series; the second ground terminal is grounded.

As a preferred scheme, the first ground terminal is grounded after being connected in series with the resistor, specifically:

and the first grounding end is connected with the ground wire after being connected with three parallel resistor groups with the resistance value of 0.33 ohm in series.

Preferably, the overvoltage protector is formed by connecting an ESD electrostatic suppressor and a resistor with the resistance value of 4.7 kilo ohms in parallel.

Preferably, the first capacitor is a capacitor of 100 uF; the second capacitance is a capacitance of 0.1 uF.

In order to solve the same technical problem, an embodiment of the present invention provides a full-automatic sliding closure device for an intelligent lock, including the full-automatic sliding closure wake-up circuit for an intelligent lock according to any one of claims 1 to 8, and a sliding closure; the touch sensor is arranged at the trademark position of the sliding cover, and the motor is connected with the sliding cover to drive the sliding cover to slide up or down.

In addition, the embodiment of the invention provides an operation method of a full-automatic sliding cover device of an intelligent lock, which comprises the following steps:

inducing a wake-up trigger signal through a touch sensor and transmitting the wake-up trigger signal to a main control module;

awakening the intelligent lock complete machine through the main control module and simultaneously controlling the driving module to drive the motor so as to enable the sliding cover to slide upwards; and

and after the preset time is exceeded, the driving module is controlled to drive the motor so as to enable the sliding cover to slide downwards.

Compared with the prior art, the embodiment of the invention has the following beneficial effects:

the invention provides a full-automatic sliding cover awakening circuit, a device and an operation method of an intelligent lock, wherein the full-automatic sliding cover awakening circuit comprises a main control module, a touch sensor, a driving module and a motor, the number of elements is small, the manufacturing cost is low, the circuit design can be greatly simplified, and the cost is saved; the touch sensor, the main control module, the driving module and the motor are sequentially connected, when the touch sensor senses a wake-up trigger signal, the wake-up trigger signal is converted into a control signal through the main control module, and the motor is controlled by the driving module to complete corresponding actions of the sliding cover, so that the sliding cover of the intelligent lock is effectively driven, actions of manually pushing and pulling the sliding cover by a user are saved, and mechanical damage possibly caused by manually pushing and pulling the sliding cover by the user is avoided.

Drawings

Fig. 1 is a schematic diagram of a full-automatic sliding cover wake-up circuit of an intelligent lock according to an embodiment of the present invention;

FIG. 2 is a circuit diagram of a fully automatic slider wake-up circuit of an intelligent lock according to an embodiment of the present invention;

fig. 3 is a flowchart of an operation method of a fully automatic sliding cover device of an intelligent lock according to an embodiment of the present invention.

Detailed Description

The technical solutions in the embodiments of the present invention will be clearly and completely described below with reference to the drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only a part of the embodiments of the present invention, and not all of the embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present invention.

Referring to fig. 1, an exemplary embodiment of an awakening circuit of a full-automatic sliding cover of an intelligent lock according to the present invention includes a main control module, a driving module, a touch sensor for sensing an awakening trigger signal, and a motor for executing an upward or downward sliding motion of the sliding cover;

the main control module is electrically connected with the touch sensor;

the driving module is respectively electrically connected with the main control module and the motor.

Referring to fig. 2, in a specific embodiment, the main control module refers to an MCU control unit with an intelligent lock having a touch function; the driving module refers to a unit for driving the motor to work; the motor refers to an action unit for controlling the sliding cover to ascend or descend through the intelligent lock.

The driving module comprises a driving chip and an overvoltage protector;

the control signal input end of the driving chip is correspondingly connected to the control signal output port of the main control module, and the overvoltage protector is connected to the control signal input end of the driving chip in parallel;

the power supply input port of the driving chip is connected with a power supply, and the grounding end of the driving chip is grounded;

and the control signal output end of the driving chip is connected with the motor.

The control signal input end of the driving chip is divided into a forward rotation signal input end and a reverse rotation signal input end; the forward rotation signal input end and the reverse rotation signal input end are respectively and correspondingly connected to a first control signal output port and a second control signal output port of the main control module;

the control signal output end of the driving chip is divided into a forward rotation signal output end and a reverse rotation signal output end; the positive rotation signal output end and the reverse rotation signal output end are respectively and correspondingly connected to a first control signal input port and a second control signal input port of the motor.

The overvoltage protector is formed by connecting an ESD electrostatic suppressor and a resistor with the resistance value of 4.7 kilo ohms in parallel.

The power supply input port of the driving chip is connected with a power supply, and the method specifically comprises the following steps:

the driving chip comprises a first power supply input port and a second power supply input port;

the first power supply input port is connected with the cathode of the diode so as to be connected with the diode in series and is connected with the power supply in parallel with the first capacitor;

the second power input port and the second capacitor are connected to a power supply in parallel.

The first capacitor is a 100uF capacitor; the second capacitance is a capacitance of 0.1 uF.

The diode is a rectifier diode.

The ground terminal of the driving chip is grounded, specifically:

the driving chip comprises a first grounding end and a second grounding end;

the first grounding end is grounded after being connected with the resistor in series; the second ground terminal is grounded.

The first grounding end is grounded after being connected with the resistor in series, and specifically comprises the following steps:

and the first grounding end is connected with the ground wire after being connected with three parallel resistor groups with the resistance value of 0.33 ohm in series.

The invention provides an exemplary embodiment, a full-automatic sliding closure device of an intelligent lock, which comprises a wake-up circuit of the full-automatic sliding closure of the intelligent lock and a sliding closure; the touch sensor is arranged at the trademark position of the sliding cover, and the motor is connected with the sliding cover to drive the sliding cover to slide up or down.

The touch sensor can also be arranged at the trademark position of the handle of the intelligent lock.

In this embodiment, the control principle of the fully-automatic sliding cover device of the intelligent lock is that a touch signal line is separated from the main control module to serve as a wake-up trigger signal of the entire lock, and also serve as a signal trigger line for the sliding cover to automatically slide upwards. When the hand touches the handle trademark or the sliding cover trademark, the touch sensor senses the awakening trigger signal, the signal enables the intelligent lock complete machine to awaken, the sliding cover slides upwards, and at the moment, the password or the fingerprint or the card can be input for unlocking verification. After the verification is successful, the sliding cover automatically slides down after short time delay.

Referring to fig. 3, an exemplary embodiment of the present invention provides an operation method of a fully automatic sliding cover device of an intelligent lock, including:

s101, inducing a wake-up trigger signal through a touch sensor and transmitting the wake-up trigger signal to a main control module;

s102, awakening the intelligent lock complete machine through the main control module and simultaneously controlling a driving module driving motor to enable the sliding cover to slide upwards; and

and S103, controlling a driving module to drive a motor to enable the sliding cover to slide downwards after the preset time is exceeded.

The invention provides a full-automatic sliding cover awakening circuit, a device and an operation method of an intelligent lock, wherein the full-automatic sliding cover awakening circuit comprises a main control module, a touch sensor, a driving module and a motor, the number of elements is small, the manufacturing cost is low, the circuit design can be greatly simplified, and the cost is saved; the touch sensor, the main control module, the driving module and the motor are sequentially connected, when the touch sensor senses a wake-up trigger signal, the wake-up trigger signal is converted into a control signal through the main control module, and the motor is controlled by the driving module to complete corresponding actions of the sliding cover, so that the sliding cover of the intelligent lock is effectively driven, actions of manually pushing and pulling the sliding cover by a user are saved, and mechanical damage possibly caused by manually pushing and pulling the sliding cover by the user is avoided.

While the foregoing is directed to the preferred embodiment of the present invention, it will be understood by those skilled in the art that various changes and modifications may be made without departing from the spirit and scope of the invention.

Claims (10)

1. A full-automatic sliding cover awakening circuit of an intelligent lock is characterized by comprising a main control module, a driving module, a touch sensor for sensing an awakening trigger signal and a motor for executing the sliding cover to slide upwards or downwards;

the main control module is electrically connected with the touch sensor;

the driving module is respectively electrically connected with the main control module and the motor.

2. The full-automatic sliding cover wake-up circuit of an intelligent lock as claimed in claim 1, wherein the driving module comprises a driving chip and an overvoltage protector;

the control signal input end of the driving chip is correspondingly connected to the control signal output port of the main control module, and the overvoltage protector is connected to the control signal input end of the driving chip in parallel;

the power supply input port of the driving chip is connected with a power supply, and the grounding end of the driving chip is grounded;

and the control signal output end of the driving chip is connected with the motor.

3. The full-automatic sliding cover wake-up circuit of an intelligent lock as claimed in claim 2, wherein the control signal input terminal of the driving chip is divided into a forward signal input terminal and a reverse signal input terminal; the forward rotation signal input end and the reverse rotation signal input end are respectively and correspondingly connected to a first control signal output port and a second control signal output port of the main control module;

the control signal output end of the driving chip is divided into a forward rotation signal output end and a reverse rotation signal output end; the positive rotation signal output end and the reverse rotation signal output end are respectively and correspondingly connected to a first control signal input port and a second control signal input port of the motor.

4. The full-automatic sliding cover wake-up circuit of an intelligent lock as claimed in claim 2, wherein the power input port of the driving chip is connected to a power supply, specifically:

the driving chip comprises a first power supply input port and a second power supply input port;

the first power supply input port is connected with the cathode of the diode so as to be connected with the diode in series and is connected with the power supply in parallel with the first capacitor;

the second power input port and the second capacitor are connected to a power supply in parallel.

5. The full-automatic sliding cover wake-up circuit of an intelligent lock as claimed in claim 2, wherein the ground terminal of the driving chip is grounded, specifically:

the driving chip comprises a first grounding end and a second grounding end;

the first grounding end is grounded after being connected with the resistor in series; the second ground terminal is grounded.

6. The full-automatic sliding cover wake-up circuit of an intelligent lock as claimed in claim 5, wherein the first ground terminal is connected in series with a resistor and then grounded, specifically:

and the first grounding end is connected with the ground wire after being connected with three parallel resistor groups with the resistance value of 0.33 ohm in series.

7. The fully automatic sliding closure wake-up circuit of an intelligent lock as claimed in claim 2, wherein the overvoltage protector is formed by connecting an ESD electrostatic suppressor in parallel with a resistor having a resistance of 4.7 kohms.

8. The full-automatic sliding cover wake-up circuit of an intelligent lock as claimed in claim 4, wherein the first capacitance is a capacitance of 100 uF; the second capacitance is a capacitance of 0.1 uF.

9. An intelligent lock full-automatic sliding closure device, characterized in that, it comprises the intelligent lock full-automatic sliding closure wake-up circuit according to any claim 1 to 8, and a sliding closure; the touch sensor is arranged at the trademark position of the sliding cover, and the motor is connected with the sliding cover to drive the sliding cover to slide up or down.

10. An operation method of a full-automatic sliding closure device of an intelligent lock is characterized by comprising the following steps:

inducing a wake-up trigger signal through a touch sensor and transmitting the wake-up trigger signal to a main control module;

awakening the intelligent lock complete machine through the main control module and simultaneously controlling the driving module to drive the motor so as to enable the sliding cover to slide upwards; and

and after the preset time is exceeded, the driving module is controlled to drive the motor so as to enable the sliding cover to slide downwards.

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