KR20170003161U - Intelligent vacuum preservation boxes and control method thereof - Google Patents

Abstract

The present invention relates to a smart vacuum freshly maintained lunchbox and a control method thereof, which includes a lunch box body, a lunch box cover, an air suction and discharge structure, and a control module, and an air suction and discharge structure and a control module are installed in the lunch box cover , The lunch box cover and the lunch box body are detachably connected and the control module controls the air intake and exhaust structure. The control method of the smart vacuum freshly maintained lunchbox includes detecting the amount of power of the battery BT1, detecting whether the lunch box is in a horizontal state, detecting whether the lunch box cover is rotating, and detecting whether the lunch box cover is covered in the lunch box body. The present invention has the advantage that the freshness retention time is long and the freshness retention effect is excellent because the air is pumped out through the air suction pump and the air is discharged from the lunch box and the air leakage speed is greatly reduced to increase the degree of vacuum. This design further extends the useful life due to the implementation of smartization.

Description

{INTELLIGENT VACUUM PRESERVATION BOXES AND CONTROL METHOD THEREOF}

The present invention relates to a smart vacuum freshly maintained lunch box and its control method.

There are two types of conventionally available vacuum fresh-preserved lunch boxes. One is to manually discharge air to maintain freshness, and the other is to discharge air from a lunch box using a small cylinder. Both of these types extract 1 to 2% of the air volume to form a pressure difference inside and outside the lunch boxes, but since the method is relatively mechanical, it is difficult to reach a complete vacuum state, not. To make it return from a vacuum to normal atmospheric pressure, an air injection device is used, which is typically a mechanical plastic valve.

The object of the present invention is to propose a smart vacuum freshly maintained lunchbox and a control method thereof that overcome the disadvantages of the conventional product, have a long holding time and are excellent in freshness retention effect.

In order to achieve the above object, the present invention is implemented through the following technical solution.

The present invention relates to a smart vacuum freshly maintained lunchbox, which comprises a lunch box body, a lunch box cover, an air suction and discharge structure, and a control module, wherein the air suction and discharge structure and the control module are installed in the lunch box cover, The electromagnetic valve A includes the electromagnetic valve A, the electromagnetic valve B, the air suction pump, the T tube C, and the T tube D, and the electromagnetic valve A is connected to the electromagnetic valve A T tube C, the electromagnetic valve A is connected to the air suction pump, the air suction pump is connected to one branch of the T tube D, and the other part of the T tube C is connected to one branch of the T tube C, And the electromagnetic valve B is connected to the other branch of the T tube D. The main tube of the T tube D is fixed to the outside of the lunch box cover A control module, a pressure and temperature sensor module, a gyroscope and an acceleration sensor module, a charging module, a temperature sensor module, and a temperature sensor module. A battery voltage monitoring module, and a constant voltage module, and the pressure and temperature sensor module, the gyroscope and acceleration sensor module, the charging module, the solenoid valve A, the solenoid valve B, the battery voltage monitoring module, and the constant voltage module are all connected to the controller And the constant voltage module, the battery voltage monitoring module, and the battery BT1 are connected to the charging module.

The pressure and temperature sensor module includes a pressure and temperature sensor S1, and the CSB port, the SDA port, the SCL port, and the INTI port of the pressure and temperature sensor S1 are connected to the controller.

The gyroscope and the acceleration sensor module include a gyroscope and an acceleration sensor U2, an electric resistance R23, an electric resistance R24, an electric resistance R25, an electric resistance R26, an electric resistance R27, a capacitance C26, a capacitance C28, a capacitance C29 and an NPN triode Q5 And the CPOUT port of the gyroscope and acceleration sensor U2 is connected to the ground signal GND via a capacitance C26. The SCL port and the SDA port of the gyroscope and the acceleration sensor U2 are connected to the controller, and the gyroscope and the acceleration sensor U2 And the SDA port of the gyroscope and acceleration sensor U2 are connected to the power supply VMCU via an electrical resistance R27 and the INT port of the gyroscope and acceleration sensor U2 is connected to the power supply VMCU through an electrical resistance R26, R24, and the base electrode of the NPN triode Q5 is connected to the base electrode of the NPN triode Q5 through the resistor R25 The collector of the NPN triode Q5 is connected to the ground signal GND, the emitter of the NPN triode Q5 is connected to the ground signal GND, the collector of the NPN triode Q5 is connected to the controller, It is also connected to the power VMCU.

The charging module includes a charging chip U3, a capacitance C32, a capacitance C34, an electric resistance R36, and a charger G1. The VCC port of the charging chip U3 is connected to the charger G1, and the VCC port of the charging chip U3 is connected through a capacitance C32 The GND port of the charging chip U3 is connected to the ground signal GND and both the CHRG port and the PROG port of the charging chip U3 are connected to the controller and the BAT port of the charging chip U3 is connected to the ground signal GND through the capacitance C34 The PROG port of the charging chip U3 is connected to the ground signal GND via an electrical resistance R36 and the BAT port of the charging chip U3 is connected to the ground signal GND via the battery BT1.

The battery voltage monitoring module includes an electric resistance R42 and an electric resistance R44. One end of the electric resistance R42 is connected to the BAT port of the charging chip U3. The other end of the electric resistance R42 is connected to the ground signal GND And the other end of the electric resistance R42 is connected to the controller.

The constant voltage module includes a constant voltage chip U5, an electric resistance C35, an electric resistance C36, and an electric resistance C39. The IN port of the constant voltage chip U5 is connected to the BAT port of the charging chip U3, C39 to the ground signal GND, the GND port of the constant voltage chip U5 is connected to the ground signal GND, the power supply VMCU is connected to the OUT port of the constant voltage chip U5, and the OUT port of the constant voltage chip U5 is connected to the capacitance C35 To the ground signal GND, and the capacitance C35 is in parallel with the capacitance C36.

The control method of the smart vacuum freshly maintained lunchbox may be,

(1) initializing the controller;

If the amount of power of the battery BT1 is sufficient, the controller proceeds to step (3). If not, the controller proceeds to charge the battery BT1 Step (2);

The controller determines whether the lid of the lunch box body is closed through the voltage and temperature sensor module. If the lunch box body is closed by the lid, the controller enters the step (4), otherwise returning to the step (2) 3);

The controller detects whether the lunch box is in a horizontal state through the gyroscope and the acceleration sensor module. If the lunch box is in a horizontal state, the controller enters the step (5). If not, the controller adjusts the state of the lunch box, Entering a horizontal state and then entering step (5) (4);

(5) controlling the air intake and exhaust structure to proceed with an air discharge operation;

The controller detects the amount of power of the battery BT1 through the battery voltage monitoring module and determines whether the amount of power of the battery BT1 is sufficient. If the amount of power of the battery BT1 is sufficient, the controller goes to step 7, otherwise controls the air intake / (6) for the charging module to proceed with charging for the battery BT1;

The controller detects whether the lunch box cover is rotated through the gyroscope and the acceleration sensor module. When the lunch box cover is rotated, the controller controls the air suction and discharge structure to advance the air discharge operation, and then enters the step (2) (7) if not, returning to step (6).

The beneficial effects of this design are as follows. That is, the present invention promotes the air discharge operation to the freshly-kept lunch box through the air suction pump, thereby greatly reducing the air leakage speed, thereby improving the degree of vacuum and thus maintaining the freshness retention time and the freshness retention effect; When the lunchbox cover is closed, the controller, pressure and temperature sensor modules are smarter because they analyze the change in gas pressure in the lunch box and initiate air discharge operations. By using the controller, gyroscope and acceleration sensor module to analyze the angle of rotation of the lunch box cover, air is discharged, which prevents the troublesome button operation and damage to the product, thus extending the service life.

1 is a structural view of the present invention;
2 is a system chart of a control module in the present invention;
3 is an electric circuit principle diagram of the pressure and temperature sensor module;
4 is an electric circuit principle diagram of the gyroscope and acceleration sensor module;
5 is an electric circuit principle diagram of the charging module and the battery voltage detection module;
6 is an electric circuit principle diagram of the constant voltage module; And
7 is a program flow chart of the present invention.

Hereinafter, the technical solution of the present invention will be described in more detail in connection with the drawings of the specification.

1 to 6, the smart vacuum fresh-keeping lunch box includes a lunch box body 1, a lunch box cover 8, an air suction and discharge structure, and a control module. The air suction and discharge structure, And the lunch box cover 8 is detachably connected to the lunch box body 1 and the electromagnetic valve A 2 and the electromagnetic valve B 6 , The air suction pump 3, the T tube C (7) and the T tube D (4), the electromagnetic valve A (2) is connected to one branch of the T tube C (7) The electromagnetic valve A 2 is connected to the air suction pump 3 and the air suction pump 3 is connected to one branch of the T tube D 4 and the other part of the T tube C 7 The main body of the T-tube D (4) is connected to the solenoid valve B (6), the solenoid valve B (6) is connected to another branch of the T- And the main tube of the T-tube C (7) communicates with the box body (1), and the control module controls the air intake / exhaust structure, and the control module (23) The pressure and temperature sensor module 21, the gyroscope and acceleration sensor module 22, the charging module 24, the battery BT1 27, the battery voltage monitoring module 26 and the constant voltage module 25, And the temperature sensor module 21, the gyroscope and acceleration sensor module 22, the charging module 24, the solenoid valve A 2, the solenoid valve B 6, the battery voltage monitoring module 26, the constant voltage module 25 Are connected to the controller 23. The constant voltage module 25, the battery voltage monitoring module 26 and the battery BT1 27 are connected to the charging module 24.

The pressure and temperature sensor module 21 includes a pressure and temperature sensor S1, and the CSB port, the SDA port, the SCL port, and the INTI port of the pressure and temperature sensor S1 are connected to the controller. The model of pressure and temperature sensor S1 is HP203B or HP206C.

The gyroscope and acceleration sensor module 22 are connected to the gyroscope and acceleration sensor U2, the electric resistance R23, the electric resistance R24, the electric resistance R25, the electric resistance R26, the electric resistance R27, the capacitance C26, the capacitance C28, the capacitance C29, And the CPOUT port of the gyroscope and the acceleration sensor U2 are connected to the ground signal GND via a capacitance C26 and the SCL port and the SDA port of the gyroscope and the acceleration sensor U2 are connected to the controller and the gyroscope The SCL port of the acceleration sensor U2 is connected to the power supply VMCU through an electric resistance R26, and the SDA port of the gyroscope and the acceleration sensor U2 is connected to the power supply VMCU through an electric resistance R27, and the INT port of the gyroscope and the acceleration sensor U2 Is connected to the base electrode of the NPN triode pipe (Q5) through an electric resistance R24, and the base electrode of the NPN triode pipe (Q5) is connected to the electric resistance R25 The collector of the NPN triode Q5 is connected to the controller, and the collector of the NPN triode Q5 is connected to the ground signal GND. The emitter of the NPN triode Q5 is connected to the ground signal GND. Is also connected to the power VMCU. The model of the gyroscope and acceleration sensor U2 is the MPU6050.

The charging module 24 includes a charging chip U3, a capacitance C32, a capacitance C34, an electric resistance R36, and a charger G1. The VCC port of the charging chip U3 is connected to the charger G1. The VCC port of the charging chip U3 is connected to a capacitance The GND port of the charging chip U3 is connected to the ground signal GND and both the CHRG port and the PROG port of the charging chip U3 are connected to the controller and the BAT port of the charging chip U3 is connected to the ground signal GND via the capacitance C34 to the ground signal GND and the PROG port of the charging chip U3 is connected to the ground signal GND via the electrical resistance R36 and the BAT port of the charging chip U3 is connected to the ground signal GND via the battery BT1. The model of the charging chip U3 is STC4054.

The battery voltage monitoring module 26 includes an electric resistance R42 and an electric resistance R44. One end of the electric resistance R42 is connected to the BAT port of the charging chip U3, and the other end of the electric resistance R42 is connected Is connected to the ground signal GND, and the other end of the electric resistance R42 is connected to the controller.

The constant voltage module 25 includes a constant voltage chip U5, an electric resistance C35, an electric resistance C36, and an electric resistance C39. The IN port of the constant voltage chip U5 is connected to the BAT port of the charging chip U3, The port is connected to the ground signal GND through a capacitance C39, the GND port of the constant voltage chip U5 is connected to the ground signal GND, the power VMCU is connected to the OUT port of the constant voltage chip U5, and the OUT port of the constant voltage chip U5 Is connected to the ground signal GND via a capacitance C35, and the capacitance C35 is parallel to the capacitance C36.

The control method of the smart vacuum freshly maintained lunch box is concretely described,

(1) initializing the controller;

The controller detects the amount of power of the battery BT1 through the battery voltage monitoring module and determines whether the amount of power of the battery BT1 is sufficient. If the amount of power of the battery BT1 is sufficient, the controller proceeds to step (3). Otherwise, the charging module proceeds to charge the battery BT1 (2);

The controller determines via the voltage and temperature sensor module whether the lid is closed on the lunch box body, if the lunch box body is closed with the lid, go to step (4), otherwise return to step (2) );

The controller detects whether the lunch box is in a horizontal state via the gyroscope and the acceleration sensor module. If the lunch box is in a horizontal state, the controller enters the step (5). Otherwise, the state of the lunch box is adjusted (4) to enter the next step (5) after placing it in the state;

The controller (5) controlling the air intake and exhaust structure to proceed with the air discharge operation;

The controller detects the amount of power of the battery BT1 through the battery voltage monitoring module. If the amount of power of the battery BT1 is sufficient, the controller goes to step 7, otherwise controls the air intake / , The charging module proceeds to charge (6) the battery BT1;

The controller detects whether the lunch box cover is rotated through the gyroscope and the acceleration sensor module. When the lunch box cover is rotated, the controller controls the air suction and discharge structure to advance the air discharge operation, and then enters the step (2) (7) if not, returning to step (6).

The present invention proposes an air suction pump which performs air discharging operation for a freshly-kept lunch box, thereby greatly reducing the air leakage speed, thereby increasing the degree of vacuum. When the lunch box cover is closed, the controller, pressure and temperature sensor module is smarter because it analyzes the gas pressure changes in the lunch box and initiates the air discharge operation; By using the controller, gyroscope and acceleration sensor module to analyze the angle of rotation of the lunch box cover, air is discharged, which prevents the troublesome button operation and damage to the product, thus extending the service life.

It should be noted that the above description is only a concrete example of the present invention. Obviously, the present invention is not limited to the above embodiment, and various modifications are possible.

Accordingly, those skilled in the art will be able to deduce or associate various modifications directly with the teachings of the present disclosure, all of which fall within the scope of the present invention.

Claims (7)

In a smart vacuum fresh-keeping lunchbox,
The air intake / exhaust structure and the control module are installed in the lunch box cover (8), and the lunch box cover body (1), the lunch box cover (8) 8 is connected to the box body 1 in a detachable manner and the electromagnetic valve A 2, the solenoid valve B 6, the air suction pump 3, the T tube C 7, The electromagnetic valve A (2) is connected to one branch of the T-tube C (7), and the electromagnetic valve A (2) is connected to the air suction pump 3 The air suction pump 3 is connected to one branch of the T-tube D (4), the other branch of the T-tube C (7) is connected to the solenoid valve B (6) The solenoid valve B 6 is connected to another branch of the T tube D 4 and the main tube of the T tube D 4 is fixed to the outside 5 of the lunch box case cover 5, ) Communicates with the lunch box body (1), and the control module controls the air intake and exhaust structure, and the control module includes a controller (23), a pressure and temperature sensor module (21), a gyroscope and an acceleration sensor And a constant voltage module 25. The pressure and temperature sensor module 21, the gyroscope and the acceleration sensor module 22, the charging module 24, the battery BT1 27, the battery voltage monitoring module 26, The battery voltage monitoring module 26 and the constant voltage module 25 are both connected to the controller 23 and the constant voltage module 22, the charging module 24, the electromagnetic valve A 2, the solenoid valve B 6, (25), a battery voltage monitoring module (26), and a battery (BT1) (27) are connected to the charging module (24). The method according to claim 1,
The pressure and temperature sensor module 21 includes a pressure and temperature sensor S1, and the CSB port, the SDA port, the SCL port, and the INTI port of the pressure and temperature sensor S1 are connected to the controller. Maintained lunch boxes. The method according to claim 1,
The gyroscope and acceleration sensor module 22 are connected to the gyroscope and acceleration sensor U2, the electric resistance R23, the electric resistance R24, the electric resistance R25, the electric resistance R26, the electric resistance R27, the capacitance C26, the capacitance C28, the capacitance C29, And the CPOUT port of the gyroscope and the acceleration sensor U2 are connected to the ground signal GND via a capacitance C26 and the SCL port and the SDA port of the gyroscope and the acceleration sensor U2 are connected to the controller and the gyroscope The SCL port of the acceleration sensor U2 is connected to the power supply VMCU through an electric resistance R26, and the SDA port of the gyroscope and the acceleration sensor U2 is connected to the power supply VMCU through an electric resistance R27, and the INT port of the gyroscope and the acceleration sensor U2 Is connected to the base electrode of the NPN triode pipe (Q5) through an electric resistance R24, and the base electrode of the NPN triode pipe (Q5) is connected to the electric resistance R25 The collector of the NPN triode Q5 is connected to the controller, and the collector of the NPN triode Q5 is connected to the ground signal GND. The emitter of the NPN triode Q5 is connected to the ground signal GND. Is connected to a power VMCU. The method according to claim 1,
The charging module 24 includes a charging chip U3, a capacitance C32, a capacitance C34, an electric resistance R36, and a charger G1. The VCC port of the charging chip U3 is connected to the charger G1. The VCC port of the charging chip U3 is connected to a capacitance The GND port of the charging chip U3 is connected to the ground signal GND and both the CHRG port and the PROG port of the charging chip U3 are connected to the controller and the BAT port of the charging chip U3 is connected to the ground signal GND via the capacitance C34 to the ground signal GND and the PROG port of the charging chip U3 is connected to the ground signal GND through the electrical resistance R36 and the BAT port of the charging chip U3 is connected to the ground signal GND via the battery BT1 Smart box vacuum cleaner lunch boxes. 5. The method of claim 4,
The battery voltage monitoring module 26 includes an electric resistance R42 and an electric resistance R44. One end of the electric resistance R42 is connected to the BAT port of the charging chip U3, and the other end of the electric resistance R42 is connected Is connected to the ground signal GND and the other end of the electrical resistor R42 is connected to the controller. 5. The method of claim 4,
The constant voltage module 25 includes a constant voltage chip U5, an electric resistance C35, an electric resistance C36, and an electric resistance C39. The IN port of the constant voltage chip U5 is connected to the BAT port of the charging chip U3, The port is connected to the ground signal GND through a capacitance C39, the GND port of the constant voltage chip U5 is connected to the ground signal GND, the power VMCU is connected to the OUT port of the constant voltage chip U5, and the OUT port of the constant voltage chip U5 Is connected to the ground signal GND via a capacitance C35, and the capacitance C35 is in parallel with the capacitance C36. A method of controlling a smart vacuum freshly maintained lunchbox,
Specifically,
(1) initializing the controller;
If the amount of power of the battery BT1 is sufficient, the controller proceeds to step (3). If not, the controller proceeds to charge the battery BT1 Step (2);
The controller determines whether the lid of the lunch box body is closed through the voltage and temperature sensor module. If the lunch box body is closed by the lid, the controller enters the step (4), otherwise returning to the step (2) 3);
The controller detects whether the lunch box is in a horizontal state through the gyroscope and the acceleration sensor module. If the lunch box is in a horizontal state, the controller enters the step (5). If not, the controller adjusts the state of the lunch box, Entering a horizontal state and then entering step (5) (4);
(5) controlling the air intake and exhaust structure to proceed with an air discharge operation;
The controller detects the amount of power of the battery BT1 through the battery voltage monitoring module and determines whether the amount of power of the battery BT1 is sufficient. If the amount of power of the battery BT1 is sufficient, the controller goes to step 7, otherwise controls the air intake / (6) for the charging module to proceed with charging for the battery BT1;
The controller detects whether the lunch box cover is rotated through the gyroscope and the acceleration sensor module. When the lunch box cover is rotated, the controller controls the air suction and discharge structure to advance the air discharge operation, and then enters the step (2) And if not, returning to step (6). ≪ Desc / Clms Page number 13 >

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