KR200384426Y1 - Automatic water supply system using voltage up circurt - Google Patents

Abstract

The present invention improves the fact that the conventional battery voltage can only be used up to the solenoid driving limit voltage (4.5V), and uses up to the microcomputer driving limit voltage (2.5V) and the solenoid driving power supply and the sensing sensor transmission driving power supply are boosted. The present invention relates to an automatic cleaning device that maximizes the use time of a battery by supplying the same.

The automatic cleaning device includes a battery 70, a sensing sensor transmitter 40 for generating a signal to detect a user, and a sensing sensor transmitter driving power boosting circuit 50 for supplying power to the sensing sensor transmitter 40. And, the sensor sensor receiving unit 30 for detecting that the signal generated from the sensor sensor transmitting unit 40 is reflected by the user, and the solenoid valve 10 to open and close to discharge the water during cleaning, and the solenoid To detect the limit voltage of the solenoid valve driving circuit 90 for driving the valve 10, the solenoid valve driving power boosting circuit 80 for supplying power to the solenoid valve driving circuit 90, and the battery 70. Comparing the reference voltage comparison unit 60, the low voltage signal generator 100 for generating a signal so that the battery can be replaced when the voltage of the battery 70 is less than the micom operation limit voltage, and the mi Com control unit 20 is made.

Description

Automatic water supply system using voltage up circurt} with booster circuit to maximize battery life

The present invention is to maximize the battery life of the automatic cleaning device, and more specifically, to operate the solenoid valve smoothly and to directly drive up to 4.5V, a sufficient voltage to the sensor transmitter to detect the user at a suitable distance Supply the microcomputer up to the limit voltage of the microcomputer directly and supply the solenoid valve to the solenoid valve driving circuit by boosting the low voltage above the solenoid valve operating voltage above the solenoid valve driving circuit. If the voltage is low, the user can not detect the user because the signal is too weak to detect the user, so boost the low voltage to 4.5V and supply it to the automatic cleaning device that can be used for a long time until the battery voltage is lowered to the micom operation limit voltage. One will.

In order to prevent the solenoid from operating due to battery voltage drop, the conventional self-cleaning device detects the solenoid operating limit voltage of 4.5V compared to the reference voltage, displays a low voltage alarm, and prompts the user to replace the battery. Had to be exchanged.

      The present invention was devised to solve such a conventional problem, and the solenoid valve is driven directly by the battery voltage up to the solenoid operating limit voltage, and the solenoid valve can not be directly driven because the voltage is low until the micom operation limit voltage. By operating up to the limit voltage, the battery life can be used for as long as possible.

Here, the battery is replaced after using the microcomputer operating limit voltage.

Conventional battery type automatic cleaning device is used by inserting a new battery at an initial stage and can only use the solenoid limit voltage. However, since the present invention can be used additionally to the microcomputer operating limit voltage, the battery life can be extended by that time. It is an object of the present invention to provide an automatic cleaning device that maximizes the pressure.

Automatic cleaning device maximizing the battery life of the present invention for achieving the above object, the detection sensor transmission unit for transmitting a signal to detect the user, and a detection sensor receiver for receiving a signal reflected when the user is detected; The solenoid valve that opens and closes the water pipe for cleaning when the user senses it at the detection sensor receiver, the solenoid valve driving circuit that controls the power to open and close the solenoid valve, and the battery voltage is lowered to the solenoid valve operation limit voltage, Reference voltage comparison unit that can drive booster circuits by comparing them when the voltage is lowered to the operating limit voltage, and solenoid valve driving power booster circuit which boosts up to the operation limit voltage of solenoid valve when it is recognized as below the solenoid valve operating limit voltage. Transmitting the sensing sensor transmitter The sensor power transmitter booster circuit boosts the voltage to the same voltage as the solenoid valve operation limit voltage so that the call strength can be detected at a certain distance. The microcomputer control unit controls all the above functions. It is characterized in that it comprises a battery for supplying power to perform all operations.

        Hereinafter, with reference to the accompanying drawings will be described in detail the automatic cleaning device that maximizes the use time of the battery of the present invention.

      1 is a block diagram of an automatic cleaning device according to an embodiment of the present invention.

      1, the solenoid valve 10 is installed in the water pipe and the solenoid valve 10 is connected to the solenoid valve driving circuit 90 is driven, the solenoid valve driving circuit is a microcomputer 20 and a solenoid valve driving It is connected to the power boost circuit (80). In addition, the sensor sensor receiver 30 is connected to the microcomputer 20, the sensor sensor transmitter 40 for generating a signal to receive a signal that the sensor sensor receiver 30 is a user is a sensor sensor transmitter drive power The booster circuit 50 is connected, and the sensing sensor transmitter driving power booster circuit 50 is connected to the microcomputer control unit 20.

In addition, the reference voltage comparator 60 is connected to the microcomputer control unit 20 and the battery 70, and the sensor sensor transmitter driving power booster circuit 50 and the solenoid valve driving power booster circuit 80 are also connected to the microcomputer control unit 20. It is connected to the battery 70.

The solenoid valve 10 is opened and closed by the solenoid valve driving circuit 90 and the solenoid valve driving circuit 90 is driven by the battery 70 voltage when the voltage of the battery 70 is greater than or equal to the solenoid valve operating limit voltage. If the voltage is lower than the operating limit voltage, the solenoid valve driving power booster circuit 80 is boosted to the solenoid valve operating limit voltage or higher and then supplied to the solenoid valve driving circuit 90 to be driven.

The sensing sensor transmitter 40 is driven by the battery 70 voltage when the battery 70 voltage is greater than or equal to the solenoid valve operating limit voltage, and is operated by the sensing sensor transmitter driving power booster circuit 50 when the battery 70 voltage is less than the solenoid valve operating limit voltage. After the voltage is increased above the operating threshold voltage, the sensor is supplied to the transmitter 40 and driven.

The sensor sensor receiving unit 30 receives a signal transmitted from the sensor sensor transmitting unit 40 reflected by the user and sends it to the microcomputer control unit 20 again.

The microcomputer control unit 20 compares the reference voltage comparing unit 60 with the voltage of the battery 70 and controls the solenoid valve driving power boosting circuit 80 and the sensing sensor transmitter driving power boosting circuit 50 when the solenoid operating limit voltage is lower. If the microcomputer operation limit voltage is less than the low voltage signal generation unit 100 to control the battery to generate a signal.

In addition, the microcomputer control unit 20 receives the signal from the sensor sensor receiver 30 to control the solenoid valve driving circuit (90).

As described above, the automatic cleaning device that maximizes the use time of the battery of the present invention uses the solenoid valve operating limit voltage which can directly drive the solenoid valve in a general driving method and then keeps operating the battery until the micom operating limit voltage. It boosts the voltage for use and supplies it to the solenoid valve and the sensing sensor transmitter, so it can operate smoothly even at low voltage, which can significantly extend the battery life.

1 is a block diagram of an automatic washing apparatus according to an embodiment of the present invention,

2 is a block diagram of an embodiment of a conventional automatic cleaning device.

-Explanation of the symbols for the main parts of the drawings-

10: solenoid valve 20: microcomputer control unit

30: detection sensor receiver 40: detection sensor transmitter

50: Drive power boost circuit for detection sensor transmitter

60: reference voltage comparison 70: battery

80: solenoid valve driving power boost circuit

90: solenoid valve drive circuit 100: low voltage signal generating unit

Claims (2)

In the automatic cleaning device to maximize the battery life, The solenoid valve driving power booster circuit 80 and the sensor sensor transmitter driving power booster circuit 50 are operated when the reference voltage comparing unit 60 and the battery 70 voltage are lower than the solenoid valve operating limit voltage. By increasing the voltage even at a low voltage that cannot be achieved, the solenoid valve 10 and the sensor sensor transmitter 40 can operate smoothly, extending the battery usage time from the existing solenoid valve operating limit voltage to the micom operating limit voltage. Automatic cleaning device that maximizes battery life. The method of claim 1, The solenoid valve driving power boosting circuit 80 and the sensor sensor transmission unit driving power boosting circuit 50 is integrated to simplify the circuit, the automatic cleaning device to maximize the battery use time, characterized in that consisting of one boost circuit,