KR101203115B1 - Steam cleaner with flow control function - Google Patents

Abstract

The present invention relates to a steam cleaner, a water tank in which water is stored, a solenoid pump for discharging water stored in the water tank, a heater unit for heating and discharging water discharged from the solenoid pump, and the solenoid pump By providing a pump driving unit for driving a control period generating unit for outputting a control period signal to the pump driving unit so that the control period of the solenoid pump is changed in accordance with the voltage level of the commercial AC power supply, the solenoid according to the voltage level of commercial AC power supply The control cycle of the pump can be changed automatically.

Description

Steam cleaner with flow control function

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a steam cleaner having a flow control function, and more particularly, to a steam cleaner having a flow control function in which a control cycle of a solenoid pump is automatically changed according to a voltage level of a commercial AC power supply.

A steam cleaner is an electric device that heats water to inject hot steam to contaminants, and generally includes a solenoid pump for supplying a predetermined amount of water stored in a water tank to a heater. In addition, the driving element for controlling the solenoid pump is generally SCR or TRAC, and the flow rate control method of the solenoid pump controls the discharge flow rate of the solenoid pump in accordance with the phase of the power source.

However, the power applied to the solenoid pump always has the same waveform for each cycle if the controlled phase is the same, but it is difficult to control the discharge flow rate at the correct ratio since the solenoid pump used in the steam cleaner is a very small metering pump. There was.

The invention that improves the problems caused by the phase control of the solenoid pump is disclosed in Korea Patent Publication No. 2010-0052047. According to the present invention, it is possible to obtain a good discharge amount by driving a solenoid pump for half a cycle at predetermined intervals.

However, when the commercial AC power is supplied to the heater unit, there is still a problem that the flow rate supplied from the water tank remains constant even though a difference occurs in the heating temperature of the heater according to the voltage variation of the commercial AC power.

Korean Patent Publication No. 2010-0052047

In order to improve the above-mentioned problem, an object of the present invention is to provide a steam cleaner having a flow control function in which a control cycle of a solenoid pump is automatically changed according to the voltage level of a commercial AC power supply.

In order to achieve the above object, a steam cleaner according to the present invention is a water tank in which water is stored, a solenoid pump for discharging the water stored in the water tank, and a heater for heating the water discharged from the solenoid pump to convert to steam And a pump driver for driving the solenoid pump, and a control cycle generator for outputting a control cycle signal to the pump driver so that the control cycle of the solenoid pump is changed according to the voltage level of a commercial AC power supply.

The pump driving unit preferably includes a pump voltage conversion circuit for converting the commercial AC power into a pump DC voltage and a power transistor for controlling the solenoid pump to operate by the pump DC voltage.

The control period generation unit includes a power level detection circuit connected to the commercial AC power source, and a period connected to the power level detection circuit to generate a control period signal according to the voltage level of the commercial AC power supply and supply the control period signal to a gate of the power transistor. It is preferable to include a generation comparison circuit.

The control period generation unit may further include an on time setting circuit configured to set an on time time supplied to the gate of the power transistor.

The power level detection circuit includes a first diode connected to a first anode to the commercial AC power source, a first resistor connected to one side of the first cathode of the first diode, and a first plus terminal connected to the other side of the first resistor. It may include a first capacitor connected to the first negative terminal to the ground.

The period generation comparison circuit may include a first comparator connected to a first plus terminal of the first capacitor and a first minus input terminal to a first reference voltage.

The period generation comparison circuit includes a transistor having a base connected to a first output terminal of the first comparator and an emitter connected to the ground, a second resistor and a first connected between the collector of the transistor and the plus input terminal of the comparator The device may further include a diode and a second diode connected between the collector of the transistor and the negative input terminal of the comparator.

The on time setting circuit includes a second comparator having a second plus input terminal connected to a plus terminal of the first capacitor, a second negative input terminal connected to a second reference voltage, and a second output terminal connected to a base of the transistor. It may include.

The steam cleaner may further include a reference voltage providing unit for providing the first reference voltage and the second reference voltage.

The reference voltage providing unit includes a third resistor having one side connected to the commercial AC power source, a third diode having a third anode connected to the other side of the third resistor, and a fourth cathode connected to the third cathode of the third diode. A zener diode connected to a fourth anode to ground and a second capacitor connected in parallel to the zener diode may be included.

With the above configuration, the present invention automatically changes the control cycle of the solenoid pump in accordance with the voltage level of the commercial AC power supply, so that water can be discharged more frequently when the heat generation of the heater is larger than the case where the heater is small.

1 is a block diagram of a steam cleaner having a flow control function according to an embodiment of the present invention.
FIG. 2 is a circuit diagram illustrating the steam cleaner shown in FIG. 1 in detail.

Hereinafter, a steam cleaner having a flow control function according to an embodiment of the present invention will be described in detail with reference to the drawings.

1 is a block diagram of a steam cleaner having a flow control function according to an embodiment of the present invention.

As shown in FIG. 1, the steam cleaner includes a commercial AC power source 110, a water tank 120, a solenoid pump 130, a heater 140, a pump driver 150, a heater driver 160, and a reference voltage. The providing unit 170 and the control period generating unit 180 are included.

The commercial AC power source 110 is a power source that is generally supplied to a home or an office, and varies from country to country, and in the domestic case, is 220V.

The water tank 120 stores water to be supplied to the heater unit according to the operation of the solenoid pump, and the solenoid pump 130 discharges the water stored in the water tank 120 toward the heater unit 140, and the heater unit 140. ) Converts the water discharged from the solenoid pump 130 into steam by heating.

The pump driver 150 supplies a driving voltage to the induction coil (see FIG. 2) of the solenoid pump 130 to control the operation of the solenoid pump 130.

The heater driving unit 160 may include a power switching element such as SCR, TRIAC, etc., but may be simply made of a bi-metal for supplying a commercial AC power source 110 to the heater unit 140.

The reference voltage providing unit 170 generates a predetermined DC voltage from the commercial AC power supply 110 and supplies it to the control period generation unit 180.

The control period generator 180 generates an on-cycle signal of the pump driver 150 according to the input voltage value of the commercial AC power source 110 and outputs the ON cycle signal to the pump driver 150.

FIG. 2 is a circuit diagram illustrating the steam cleaner shown in FIG. 1 in detail.

As shown in FIG. 2, the solenoid pump 130 includes an induction coil 232, the heater 140 includes a heater 242, and the heater driver 160 supplies a commercial AC power source 110. It may include a bimetal 262 for supplying the heater 242.

As shown in FIG. 2, when the commercial AC power source 110 is supplied to the heater 242 through the bimetal 262, the heater 242 generates heat in proportion to the square of the voltage of the commercial AC power source 110. . Therefore, it is necessary to keep the heat generation temperature of the heater 242 constant regardless of the difference in the voltage of the commercial AC power supply 110.

The pump driver 150 includes a pump voltage conversion circuit 250, a switching element Q1 254, and a diode D2 255 to supply a driving voltage to the induction coil 232 of the solenoid pump 130.

The pump voltage conversion circuit 250 includes a resistor R1 251, a diode D1 252, and a capacitor C1 253, and converts a commercial AC power source into a DC voltage. This DC voltage is used as a driving voltage for the induction coil 232 of the solenoid pump 130.

The switching element Q1 254 is turned on / off according to the control period signal of the control period generation unit 180 supplied to the gate. When the switching element Q1 254 of FIG. 2 is turned on, a driving voltage is supplied to the induction coil 232 of the solenoid pump 130. Therefore, the solenoid pump 130 heats the water stored in the water tank 120. It is discharged toward 140.

In addition, the switching element Q1 254 shown in FIG. 2 may be formed of a power transistor or the like. Diode D2 255 prevents back EMF generated from induction coil 232 of solenoid pump 130.

On the other hand, the pump driving unit 150 shown in FIG. 2 applies a DC voltage to the induction coil 232 of the solenoid pump 130 as a driving voltage, but uses SCR or TRIAC as the switching element Q1 254. It is apparent to those skilled in the art that commercial AC power can be applied as a driving voltage as it is, or AC power that is half-wave or full-wave rectified can be applied as a driving voltage.

The reference voltage providing unit 170 generates a predetermined DC voltage from the commercial AC power supply 110 to supply the control period generating unit 180 to the resistor R2 271, the capacitor C2 272, and the diode D3 273. ), Diode D4 274, capacitor C3 275 and zener diode ZD1 276.

Since the capacitor C3 275 and the zener diode ZD1 276 are connected in parallel, the capacitor C3 275 is charged with the rated voltage of the zener diode ZD1 276, for example, a voltage of 12 V, and the resistor R2 271. Is a voltage difference between the charging voltage of the commercial AC power supply 110 and the capacitor C3 (275) is generated heat.

The control period generation unit 180 generates a power supply level detection circuit 310, a period generation comparison circuit 320, and a control cycle signal of the pump driver 150 according to an input voltage value of the commercial AC power supply 110. An on time setting circuit 330.

The power supply level detection circuit 310 is a circuit for detecting the voltage level of the commercial AC power supply 110 and includes a diode D5 311, a resistor R3 312, a zener diode ZD2 313, and a capacitor C4 314. do. Here, the diode D5 311 is a device for half-wave rectifying the commercial AC power supply 110, and the voltage half-wave rectified in the diode D5 311 is charged in the capacitor C4 314 through the resistor R3 312. The charging voltage of the capacitor C4 314 is determined by the time constant of the resistance value of the resistor R3 312 and the capacitance value of the capacitor C4 314. On the other hand, the charging voltage of the capacitor C4 314 is shorter the charging time as the voltage level of the commercial AC power is larger when the resistance value of the resistor R3 312 and the capacitance value of the capacitor C4 314 are constant. The smaller the voltage level, the longer the charging time.

The period generation comparison circuit 320 generates a control period signal to be supplied to the gate of the switching element Q1 254 of the pump driver 150. The comparator CP1 321, the transistor TR1 322, and the resistor R4 323 ), Diode D6 324, resistor R5 325, resistor R6 326, diode D7 327, and resistor R7 328.

The positive input terminal of the comparator CP1 321 is supplied with the charging voltage of the capacitor C4 314 of the power level detection circuit 310 and connected to the transistor TR1 322 through the resistor R4 323 and the diode D6 324. do. In addition, the negative input terminal of the comparator CP1 321 is supplied with a reference voltage in which the DC voltage of the capacitor C3 275 of the reference voltage providing unit 170 is divided through the resistors R5 325 and R6 326, Also connected to transistor TR1 322 via diode D7 327. The output terminal of the comparator CP1 321 is connected to the base of the transistor TR1 322, and the DC terminal of the capacitor C3 275 of the reference voltage providing unit 170 and the output terminal of the comparator CP1 321 are connected to the resistor R7 (328). Is connected through

As a result, the comparator CP1 321 of the period generation comparison circuit 320 has a charge voltage of the capacitor C4 314 of the power supply level detection circuit 310 supplied to the positive input terminal than the reference voltage supplied to the negative input terminal. If large, output a high level voltage to the output terminal. Since the high level voltage output to the output terminal of the comparator CP1 321 is supplied to the gate of the transistor TR1 322, the transistor TR1 322 is turned on.

When transistor TR1 322 is turned on, since the charging voltage of capacitor C4 314 is discharged through resistor R4 323, the voltage supplied to comparator CP1 321 to the positive input terminal is lowered. On the other hand, the turn-on of the transistor TR1 322 also lowers the reference voltage supplied to the negative input terminal of the comparator CP1 321. When the charging voltage of the capacitor C4 314 is discharged through the resistor R4 323 and lower than the reference voltage supplied to the negative input terminal of the comparator CP1 321, the low level voltage is output to the output terminal of the comparator CP1 321. Thus, transistor TR1 322 is turned off.

When the transistor TR1 322 is turned off, the DC voltage of the capacitor C3 275 of the reference voltage providing unit 170 is distributed through the resistor R5 325 and the resistor R6 326 so that the reference voltage comparator CP1 321 It is supplied to the negative input terminal, and the charging voltage of the capacitor C4 314 is supplied to the plus input terminal of the comparator CP1 321. However, since the charge voltage of the capacitor C4 314 of the power supply level detection circuit 310 is discharged at the turn-on of the transistor TR1 322, the charge voltage becomes a low voltage, and the resistor R3 312 is turned on for a predetermined frequency period of the commercial AC power supply. Is charged through.

When the resistance values of the resistors R4 323, R5 325 and R6 326 of the period generation comparison circuit 320 are appropriately selected, the output time of the high level voltage of the comparator CP1 321, that is, the switching element Q1. The on time time of 254 can be adjusted. However, due to the resistance values of the resistors R4 323, the resistors R5 325, and the resistors R6 326 of the period generation comparison circuit 320 and the errors of the connected devices, it may be difficult to set an accurate on time time.

The on time setting circuit 330 is for setting an accurate on time time at the gate of the switching element Q1 254, and includes a comparator CP2 331, a resistor R8 332, and a resistor R9 333.

The positive input terminal of the comparator CP2 331 is supplied with the charging voltage of the capacitor C4 314 of the power level detection circuit 310, and the negative input terminal of the comparator CP2 331 is condenser C3 of the reference voltage providing unit 170. The reference voltage at which the DC voltage of 275 is distributed through the resistor R8 332 and the resistor R9 333 is supplied.

The reference voltage provided to the negative input terminal of the comparator CP2 331 detects a state in which the charging voltage of the capacitor C4 314 is discharged by the turn-on of the transistor TR1 322, and thus the resistance value of the resistor R8 332. It is preferable to determine about 10 times larger than the resistance value of this resistor R9 (333).

As a result, the comparator CP2 331 of the on-time setting circuit 330 discharges the charging voltage of the capacitor C4 314 of the power supply level detecting circuit 310 supplied to the positive input terminal by turning on the transistor TR1 322. When the output voltage is lower than the reference voltage supplied to the negative input terminal, the output terminal outputs a low level voltage. Since the low level voltage output from the output terminal of the comparator CP2 331 is supplied to the gate of the transistor TR1 322, the transistor TR1 322 is turned off.

The foregoing description is merely illustrative of the technical idea of the present invention, and various changes and modifications may be made by those skilled in the art without departing from the essential characteristics of the present invention. Therefore, the embodiments disclosed in the present invention are intended to illustrate rather than limit the scope of the present invention, and the scope of the technical idea of the present invention is not limited by these embodiments. The protection scope of the present invention should be interpreted by the following claims, and all technical ideas within the equivalent scope should be interpreted as being included in the scope of the present invention.

110: commercial AC power 120: water tank
130: solenoid pump 140: heater
150: pump driving unit 160: heater driving unit
170: reference voltage providing unit 180: control period generation unit
250: pump voltage conversion circuit 254: switching element
310: power supply level detection circuit 320: period generation comparison circuit
330: on time setting circuit

Claims (10)

A water tank where water is stored,
A solenoid pump for discharging water stored in the water tank;
A heater unit for heating the water discharged from the solenoid pump and converting the water into steam;
A pump driving unit for driving the solenoid pump;
And a control cycle generator for outputting a control cycle signal to the pump driver so that the control cycle of the solenoid pump changes according to a voltage level of a commercial AC power source. The method of claim 1,
The pump driving unit includes a pump voltage conversion circuit for converting the commercial AC power into a pump DC voltage and a power transistor for controlling the solenoid pump to operate by the pump DC voltage. The method of claim 2,
The control period generation unit includes a power level detection circuit connected to the commercial AC power source, and a period connected to the power level detection circuit to generate a control period signal according to the voltage level of the commercial AC power supply and supply the control period signal to a gate of the power transistor. A steam cleaner comprising a generation comparison circuit. The method of claim 3,
And the control period generating unit further comprises an on time setting circuit for setting an on time time supplied to the gate of the power transistor. 5. The method of claim 4,
The power level detection circuit includes a first diode connected to a first anode to the commercial AC power source, a first resistor connected to one side of the first cathode of the first diode, and a first plus terminal connected to the other side of the first resistor. Steam cleaner comprising a first condenser connected to the first negative terminal to the ground. The method of claim 5,
And the period generation comparison circuit includes a first comparator connected to a first plus terminal of the first capacitor and a first minus input terminal to a first reference voltage. The method according to claim 6,
The period generation comparison circuit includes a transistor having a base connected to a first output terminal of the first comparator and an emitter connected to the ground, a second resistor and a first connected between the collector of the transistor and the plus input terminal of the comparator And a second diode coupled between the diode and the collector of the transistor and the negative input terminal of the comparator. 5. The method of claim 4,
The on time setting circuit includes a second comparator having a second plus input terminal connected to a plus terminal of the first capacitor, a second negative input terminal connected to a second reference voltage, and a second output terminal connected to a base of the transistor. Steam cleaner comprising a. 9. The method according to claim 6 or 8,
And a reference voltage providing unit for providing the first reference voltage and the second reference voltage. 10. The method of claim 9,
The reference voltage providing unit includes a third resistor having one side connected to the commercial AC power source, a third diode having a third anode connected to the other side of the third resistor, and a fourth cathode connected to the third cathode of the third diode. And a second capacitor connected in parallel to the zener diode and a second capacitor connected in parallel to the zener diode.

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