KR930009753B1 - Controller for electric hot water boiler - Google Patents

Abstract

The controller for controlling the heater, water supply valve, and water level display includes a magnetic switch (MC), bimetal switches (BM1-2), and a temperature setting relay (RY2). A solenoid valve (23) controls the water supply feeding to a water tank (11) with a water level detection relay (RY1) of a water level detection circuit (24). The magnetic switch is controlled by the relay (RY1) and a timer relay (RY3) of a timer circuit (25). The circuit (24) comprises a water level displays (31-33) displaying the water level, an alarm indicating the low level, a controller (35) controlling the water level with output of the alarm.

Description

Control circuit of electric water heater

1 is a control circuit diagram of a conventional electric water heater.

2 is a structural diagram of a conventional electric water heater.

3 is a control circuit diagram of an electric water heater according to the present invention.

4 is a detailed circuit diagram of the water level detection circuit portion of FIG. 3 according to the present invention.

5 is a detailed circuit diagram of the timer circuit portion of FIG. 3 according to the present invention.

6 is a flowchart of operation according to the present invention.

* Explanation of symbols for main parts of the drawings

11: water tank 13: hot water outlet

14: water supply side cover 21: earth leakage breaker

22: heater, S / V 23: solenoid valve

24: water level detection circuit portion 25: timer circuit portion

RY1: Water level detection relay RY2: Temperature detection relay

RY3: Timer relay S / W2: Temperature selector switch

BM1, BM2: Bimetal Switch S1-S3: Water Level Sensor

MC: Magnet Switch

The present invention relates to a control circuit of an electric water heater, and more particularly to a control circuit of an electric water heater having a sensor to control the water level display, automatic water supply and operation of the heater and the like.

FIG. 1 is a control circuit diagram of a conventional electric water heater. As shown therein, a power voltage AC is applied through an earth leakage breaker (ELB) 1 to be connected to a power display lamp LP1 and a magnet switch contact MCa. Is connected to the heater (2) and heater operation indicator lamp (LP2), and the temperature detection relay (RY) through the bimetal switches (BM1) and (BM2) connected in parallel through the temperature selection switch (S / W). ), And connected to the magnet switch (MC) through the temperature detection relay switch (RYa).

Referring to the operation and problems of the conventional electric water heater control circuit configured as described above are as follows.

When the power supply voltage AC is applied while the earth leakage breaker 1 is turned on, the power display lamp LP1 is turned on and the bimetal switch BM1 or the bimetal switch is switched according to the switching of the temperature selection switch S / W. The temperature detection relay RY is turned on through the BM2, the temperature detection relay switch RYa is turned on, and the magnet switch MC is turned on.

Accordingly, the magnet switch contact MCa is turned on to start the heater 2 and to turn on the heater operation display lamp LP2.

Here, the bimetal switch (BM1), (BM2) selected by the temperature selection switch (S / W) is turned off at any temperature (90 ℃), (60 ℃), the current is cut off the heater (2) Operation is stopped, and when the water temperature is lower than the arbitrary temperature (90 ° C) and (60 ° C) and the bimetal switches BM1 and BM2 are turned on, the heater 2 is operated again to maintain a constant water temperature. .

2 is a structural diagram of a conventional electric hot water, a transparent glass 12 is attached to one side of the water tank 11 so as to check the water level from the top to the bottom, and the heater 15 controlled according to the control circuit of FIG. ) To heat the water in the tank 11, to manually supply water through the water supply side cover 14 installed on the water tank 11, and through the hot water supply outlet 13 installed at the bottom It was configured to hot water to maintain the temperature. Therefore, the water level in the water tank 11 is checked through the transparent glass 12 and the water supply side lid 14 must be opened manually and filled with water.

As described above, in the conventional electric water heater, there is a risk of disconnection and explosion of the heater when heated in the absence of water because there is no automatic water supply function. Although it can be known, it is difficult to check when steam is generated due to heating, and there is no continuous heating function for a certain period of time when a certain heating (barley tea, etc.) is necessary, that is, when boiling over a certain temperature (90 ℃) for several tens of minutes. When the temperature (90 ℃) of the heating is stopped because there is a problem that can not boil as desired.

In order to solve this problem, the present invention is to provide a water level sensor to display the water level and automatic water supply, and to create a control circuit that can be heated for a certain time above a certain temperature by attaching a timer, attached to this Referring to the drawings in detail as follows.

3 is a control circuit diagram of the electric water heater according to the present invention, and as shown therein, the power supply voltage AC is passed through the earth leakage breaker ELB 21 and then the heater 22 through the magnet switch contact MCal MCa2. Bimetal switch (BM1), (BM2) selected by the temperature selection switch (S / W2) to be supplied to the control circuit of the present invention through the fuse (F1) and the operation switch (S / W1) and then applied to the control circuit of the present invention. Connect to the temperature detection relay (RY2) through, and through the water level detection relay contact (RY1a) of the water level detection circuit unit 24 to the water supply control solenoid valve 23, the water level detection circuit of the water level detection circuit unit 24 It was configured by connecting to the magnet switch MC through the temperature detection relay contact RY2al and the timer relay contact RY3b of the timer circuit 25 connected in parallel after the relay contact RY1b.

5 is a detailed circuit diagram of the water level detection circuit unit according to the present invention, as shown in the water level sensor (S1), (S2), so as to detect the low water level, medium water level and full water level in the water tank 11 of the electric water heater, After installing (S3) and installing a solenoid valve (S / V) to supply water up to the full water level, the state of the low water level sensor (S1) is sensed through the PNP transistor (Q1) and the ENP transistor (Q2) A low water level display unit 31 for driving the low water level display light emitting diode LED1 through the low water level display unit 31, and a low water level alarm unit 34 for driving the buzzer BZ through the diode D7 according to the state of the low water level display unit 31; A mid-level display 32 for sensing the state of the mid-level sensor S2 through the PN transistor Q3 and driving the mid-level display light emitting diode LED2 through the transistor Q4; The state of (S3) through the PNP transistor Q5 The low water level display unit 33 for driving the high water level display light emitting diode LED3 through the transistor Q6, and the diode D2 and the transistor according to the state of the low water level sensor S1 through the low water level alarm 34 After the Q8, the PNP transistor Q7 drives the water level detection relay RY1 and maintains it through the diode D3, and the water level through the water level display 33 through the diode D4. The water level detection control unit 35 controls the water level detection relay RY1 according to the state of the detection sensor S3.

5 is a detailed circuit diagram of a timer circuit unit according to the present invention. As shown in FIG. 5, operation of the timer 41 through the capacitor C15 and the resistor R21 connected in parallel according to the state of the temperature detection relay contact RY2b is shown in FIG. After the control, the diode D16 of the timer relay controller 43 is controlled in accordance with the time constants of the capacitor C14, the resistor R19, and the variable resistor V _{R of the} variable time constant part 42 of the timer 41. And the timer relay RY3 through Q7, and reset the timer 41 through the magnet switch contact MCb.

Using the operation and effects of the present invention configured as described above are as follows.

The water level detection circuit unit shown in FIG. 4 operates according to the state of the water level sensor S1-S3, and the water level sensor S1-S3 is a low level, a medium level and a full level of the electric water heater water tank 11, respectively. It is installed so as to detect water, and when the water comes into contact, it is electrically short (short) and vice versa electrically open (open). If the water tank 11 is in full water level and the water level detection sensor S1-S3 is in a short state, the P & P transistor Q1 of the low water level, the medium water level, and the high water level display parts 31, 32, and 33 Since Q3) and Q5 are turned on to turn on transistors Q2, Q4, and Q6, respectively, the light emitting diodes LED1, LED2, and LED3 are turned on to display the full water level state.

At this time, since the transistor Q2 of the low water level display unit 31 is turned on, the low level alarm unit 34 opens the ground loop through the diode D7 so that the buzzer BZ does not drive the water level detection control unit 35. Q8) is off, and the water level detection relay RY1 is off. On the contrary, when all of the water level detection sensors S1-S3 are in an open state without contact with water, the PNP transistors Q1, Q3, Q5 of the water level display sections 31, 32, and 33 Since transistors Q2, Q4, and Q5 are turned off in the off state, the light emitting diodes LED1-LED3 are turned off, respectively.

At this time, the low water level alarm unit 34 blocks the loop through the diode D7 so that the transistor Q2 of the low water level display unit 31 is turned off according to the low water level sensor S1, and the buzzer BZ is driven. In addition, the water level detection control unit 35 turns on the transistor Q8 through the diode D2 and the PN transistor Q7 is turned on so that the water level detection relay RY1 is turned on and the transistor Q8 through the diode D3. The gate bias of is fed back to maintain self. The solenoid valve S / V 23 is opened by the contact RY1a of the water level detection relay RY1 to start water supply to the water tank 11. Thereafter, the water level detection sensors S1-S3 are sequentially shorted, and the light emitting diodes LED1-LED3 of the water level display units 31-33 are sequentially turned on.

Here, the water level detection control unit 35 is in a self-hold state through the diode D3 until the high water level detection sensor S3 is shorted, and when the high water level detection sensor S3 is shorted, the transistor of the high water level display unit 33 is shorted. When Q6 is turned on and the light emitting diode LED3 is turned on, a loop is opened to the transistor Q6 turned on through the diode D4 of the water level detection control unit 35, so that the diode D3 is turned off from the PNP transistor Q7. The loop used to maintain the passage is blocked so that the water level detection relay RY1 is turned off. Accordingly, the solenoid valve S / V 23 is turned off to stop the water supply.

In addition, the timer circuit unit shown in FIG. 5 is driven according to the temperature detection relay contact RY2b of FIG. 3, and the user can adjust the time constant by adjusting the variable resistor V _R. . When the heater 22 is operated and the bimetal switch BM1 or BM2 is turned off in accordance with the temperature detection and the temperature detection relay RY2b is turned off, its contact RY2b is turned on and the timer 41 starts driving. If a predetermined time constant is set by adjusting the variable resistor (V _R ), during this time constant time, the timer 41 turns on the transistor Q7 through the diode D16 through the high potential output, and thus the timer relay ( RY3) is turned off.

After that, if the timer relay RY3 turns off and the magnet switch MC turns off, the timer 41 is reset because its contact MCb is turned on.

6 is a flowchart illustrating an operation according to the present invention. As shown in FIG. 6, the power supply voltage AC is supplied to the control circuit according to the present invention while the operation switch S / W1 is turned on while the earth leakage breaker 21 is turned on. Is supplied and the temperature detection relay RY2 is turned on through the bimetal switch BM1 or the bimetal switch BM2 having a different selection temperature by selection of the temperature selection switch S / W2.

At this time, it operates under the control of the water level detection circuit unit 24 shown in FIG. 4. When the low water level sensor S1 is open and is open, the light emitting diode LED1 of the low water level display unit 31 is opened. In addition to being turned off, the buzzer BZ of the low water level alarm part 34 drives an alarm sound, and the level detection relay RY1 of the water level detection control part 35 is turned on to open the solenoid valve 23 through its contact point RY1a. The water is supplied to the water tank 11 by turning it on. Then, when the low water level sensor S1 is shorted, the light emitting diode LED1 of the low water level display unit 31 is turned on and the buzzer BZ of the low water level alarm unit 34 is turned off.

When the water level is continuously filled and the water level detection sensor S2 is shorted, the light emitting diode LED2 of the water level display unit 32 is turned on, and then the water level display unit (3) is filled until the water level detection sensor S3 is filled with the water level in the short state. 33) With the light emitting diode LED3 off, the water level detection relay RY1 continues to be turned on so that the solenoid valve S / V continues to supply water and is filled with the full water level so as to fill the full water level sensor S3. When it is turned on, the light emitting diode LED3 of the half water level display part 33 is turned on, the water level detection relay RY1 of the water level detection control part 35 is turned off, and its contact point RY1a is turned off, so that the solenoid valve S / V; 23) turns off to stop the water supply. At this time, if the set temperature of the other bimetal switch BM1 or BM2 is different from the temperature selection switch S / W2, the water temperature in the water tank 11 is lower than the set temperature. Since the temperature detection relay RY2 is turned on because the BM1 or BM2 is on, the magnetic switch MC is turned on through the water level detection relay contact RY1b and the temperature detection relay contact RY2a, and accordingly its contact (BM1 or BM2) is turned on. The heater 22 is operated and heated through MCa1 and MCa2.

Thereafter, when the water temperature in the water tank 11 rises to the set temperature of the bimetal switch BM1 or BM2, the temperature detection relay RY2 is turned off while the bimetal switch BM1 or BM2 is turned off, whereby the magnet switch MC is turned off. When the heater 22 is turned off and the user wants to keep heating for a predetermined time or more at a certain temperature, the timer 41 adjusts the time constant of the timer 41, and the timer 41 detects the temperature detection relay RY2. The magnet switch MC is turned on through the set contact RY3b because the timer relay RY3 is turned off during the time constant time set by the user at an arbitrary time by operating together with the contact RY2b of. Accordingly, the heater 22 keeps on heating. When the set time constant time of the timer 41 has elapsed, the timer relay RY3 is turned on and its contact RY3b is turned off, so that the magnet switch MC is turned off, and by the contacts MCa1 and MCa2. The heater 22 is stopped and the timer 41 is reset by its contact MCb.

As described above, the present invention controls the heater to be driven only at the midnight power, and the power supply voltage supplied to the other control circuit part can be driven at the general power, thereby saving the user's economy and using the water level sensor accordingly. The water level indicator and automatic water supply in the water tank can be controlled at any time, which is convenient for use. When there is no water in the water tank, the heating of the heater is stopped and the automatic water supply can be performed while generating an alarm sound. By setting the time, there is an effect that the heating can be continued for a desired time above a certain temperature.

Claims (3)

The heater 22 is controlled through the contacts MCa1 and MCa2 of the magnet switch MC, and the temperature selection relays B2 and BM2 are selected by the temperature selection switch S / W2. In the control circuit of the electric water heater configured to control RY2, the water tank 11 through the water level detection relay RY1 contact RY1a of the water level detection circuit section 24 for controlling according to the water level detection in the water tank 11. Contacts RY2a and timer circuit section of the temperature detection relay RY2 which are connected in parallel after controlling the solenoid valve 23 installed to control the water supply in the < Desc / Clms Page number 6 > A control circuit for an electric water heater, characterized in that the magnet switch (MC) is configured to be controlled through a contact point (RY3b) of a timer relay (RY3) of (25). The water level display unit (31-) according to claim 1, wherein the water level display unit (31-) displays each level state according to the detection state of the water level sensor (S1-S3) installed to detect the low level, the medium level, and the full level level of the water level in the water tank (11), respectively. 33), the low water level alarm unit 34 for controlling the alarm sound generation in accordance with the drive control of the water level display unit 31, and the water level detection relay RY1 in accordance with the driving of the low water level alarm unit 34 to maintain the magnetic level. And a water level detection circuit section (24) consisting of a water level detection control section (35) for controlling the water level detection relay (RY1) according to the drive control of the water level display section (33). The method according to claim 1, which is driven by the contact point RY2b of the temperature detection relay RY2, reset by the contact point MCb of the magnet switch MC, and the time constant of the timer 41 is variable. And a timer circuit 25 configured to control the timer relay RY3 according to the output thereof.

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