KR930004533B1 - Safety device for liquid heating device - Google Patents

Abstract

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Description

Safety device of liquid heater

1 is a block diagram of a control device for a gas water heater showing an embodiment of the present invention.

2 is a schematic configuration diagram of a gas water heater of this embodiment.

3 is a circuit diagram showing a safety circuit and a microcomputer power supply of this embodiment.

4 is a circuit diagram showing a power supply for the current flow circuit and the relay circuit of this embodiment.

* Explanation of symbols for main parts of the drawings

10: combustor 35: water flow sensor

42: microcomputer 41: interface

44: solenoid valve energizing relay circuit 45b: relay circuit power supply

The present invention relates to a safety device for a liquid heating device for heating a liquid through a heat exchanger.

In a liquid heating device that heats a liquid such as water through a heat exchanger, such as a gas water heater or an electric instant hot water dispenser, water flowing into a heat exchanger to determine a heating amount such as a combustion amount according to the quantity or water temperature flowing into the heat exchanger. A water flow sensor for detecting the temperature and the water temperature temperature dummyster are provided, and a heating amount such as the required combustion amount is calculated and heated by a control circuit such as a microcomputer. As a driving signal for starting the operation of the hot water heater, etc., a signal from the water flow sensor provided to determine the heating amount is used instead of the water flow switch that has been used in the past.

However, in such a liquid heating device, if there is an error in the control circuit, the signal from the water flow sensor cannot be read correctly. Therefore, even if there is no water flow detection signal, the liquid heating device can start heating and cause the water in the heat exchanger to overheat and boil or empty the pot. There was a burning problem.

According to the present invention, in a liquid heating apparatus which starts operation based on a signal from a detection means such as a water flow sensor that detects the movement of liquid, the fluid does not flow into the heat exchanger even if a control circuit for controlling the operation is abnormally operated. It is an object of the present invention to provide a safety device for a liquid heating device that stops heating if not.

The present invention operates on the basis of heating means for heating a liquid passing through a heat exchanger, liquid detecting means for detecting a liquid flowing into the heat exchanger and transmitting a liquid detecting signal, and a liquid detecting signal from the liquid detecting means. And control means for transmitting a control signal for controlling the heating state of the heating means, and when the operation is supplied with electric power, the heating means is operated in accordance with the control signal transmitted from the control means, and operation power is not supplied. Technical means having a driving means for stopping the operation of the heating means when not in operation and a switching means for supplying the operating power to the driving means only when a liquid detection signal is sent from the liquid detection means.

In the present invention, when the liquid flows into the heat exchanger, the liquid detecting means detects the movement of the liquid, sends a liquid detecting signal, and supplies the operating power to the driving means by the switching means. The control means also operates on the basis of the liquid detection signal, and sends a control signal for controlling the operation of the heating means to the drive means. At this time, since the driving power is supplied to the driving means, the heating means is driven according to the control signal. When the liquid flowing into the heat exchanger is not detected, the power supply to the drive means is stopped by the switching means. The driving means is then unable to operate the heating means and thus stops the heating means irrespective of the control signal from the control means. The heating means therefore stops heating.

In the present invention, the liquid detection signal from the liquid detection means is sent to the control means and the switching means, and the switching means supplies electric power to the drive means based on the signal. The manual means can operate the heating means only when the electric power for operation is supplied, and when there is no supply, the heating means is in the stopped state, so that the control means is abnormally operated and irrespective of the liquid detection signal from the liquid detection means. Even if the heating means is operated, the heating means does not operate when the liquid does not flow into the heat exchanger, and the heat exchanger does not heat up or the heating means does not operate abnormally.

Next, the present invention will be described based on the embodiments of the drawings. 2 is a schematic configuration diagram of the gas water heater of the present embodiment, and includes a combustor 10, a fuel pipe 20, a water pipe 30, and a controller 40. The combustor 10 is comprised of the burner group 11 installed in the water heater case 1, and the combustion fan 12 which supplies combustion air, and the fuel gas supplied from the nozzle 13 is carried out by the combustion fan 12. The whole primary air combustion which burns only with primary air supplied is performed, and combustion gas is discharged | emitted from the discharge port 2. As shown in FIG. The burner group 11 is a double burner in which a plurality of ribbon burners are arranged in two rows, and the sparker 14 of the ignition device and the frame rod 15 for flame detection above the burner group 11. And the decoupler 16 are installed, respectively. The fuel pipe 20 is a gas pipe for supplying fuel gas to the nozzle 13, and from the upstream side thereof, the solenoid valve 21 and the kettle valve 22, and a proportional valve 23 for adjusting the fuel supply amount, respectively, are provided. Downstream of the proportional valve 23, the fuel pipe 20 is branched to supply fuel gas to each edge of the double burner, and one of the burner groups 11 is connected to one branched fuel pipe 20. A conversion valve 24 is provided to burn only one combustion. The water pipe 30 is composed of a supply pipe 31 and a hot water pipe 31 a connected to a water supply source and a hot water supply port which are not shown, respectively, and a heat exchanger 32 and a bypass pipe 32a installed in communication with each other. A part of the water supplied from) is led to the hot water supply pipe (31a) through the heat exchanger (32) and the other part through the bypass pipe (32a), the downstream side of the heat exchanger (32) and the bypass pipe (32a) A bypass valve 33 is installed at the confluence of the mixture, and adjusts and mixes the ratio of the water heated by the heat exchanger 32 and the water directly induced by the bypass pipe 32a as it is.

On the other hand, the water supply control valve 34, the water flow sensor 35 and the water-receiving on-demand 36 from the upstream side, and the heat exchange dummyster 37 downstream from the heat exchanger 32 are supplied to the supply pipe 31 again. ) Is provided with tapping on the demister (38), respectively. In addition, the bypass valve 33 and the water quantity control valve 34 are driven by geared motors provided, respectively, and potentiometers are installed to detect the position of each valve. The water flow sensor 35 outputs a pulse of the number corresponding to the rotational speed of the vane, which is not shown, which is rotated by the water flow passing through the supply pipe 31. As shown in FIG. 1, the control device 40 includes a microcomputer 42 serving as the center of the control device 40 and each circuit serving as an interface 41 for exchanging signals with the respective parts provided in the gas water heater. It consists of a safety circuit 43 for securing and a solenoid valve energization relay circuit 44, and a power supply part 45 for supplying electric power to all of them, and a controller 46 and a microcomputer for manipulating the operation of the gas water heater. A mode setting circuit 47 for setting the operation mode of 42 in advance is provided.

First, each circuit as the interface 41 will be described.

The sparker circuit 51 is comprised from the high voltage generation part which generate | occur | produces the high voltage which makes a spark discharge discharge to the sparker 14, and the discharge detection part which detects the spark discharge in the sparker 14. As shown in FIG.

The flame temperature detecting circuit 52 is an amplifying circuit for using the output voltage of the decoupler 16 according to the detected flame temperature as a control signal, and the amplified signal is used for controlling the air-fuel ratio during combustion. The water temperature detection circuit 53 is a circuit for obtaining respective temperature signals from the resistance values of the respective dummysters arranged in the water pipe 30, and the temperature signals are obtained by dividing the power supply voltage by a resistor connected in series with each dummyster. Lose. The geared motor driving circuit 54 is an energization circuit of a geared motor for driving the water quantity control valve 34 and the bypass valve 33 disposed in the water pipe 30, respectively, and each geared motor controls the opening degree of each valve. It is controlled based on the resistance value of an unshown potential meter which is installed for detection. The fan circuit 55 is a circuit for driving the combustion fan 12 based on the pulse signal transmitted from the microcomputer 42, and output voltage according to the pulse width of the transmitted pulse signal as the control voltage of the fan driving circuit. Is authorized. And a rotation speed detection circuit for outputting a pulse signal corresponding to the rotation speed of the combustion fan 12, and sends the rotation speed signal to the microcomputer 42. FIG. The proportional valve circuit 56 is a circuit for energizing the proportional valve 23 for controlling fuel gas. The flame detection circuit 58 is flame detection means for detecting a flame by the frame rod 15 to obtain a flame detection signal, and flame detection signals of H level are sent to the microcomputer 42 and the safety circuit 43, respectively. do.

The water flow circuit 59 transmits the pulse signal to the microcomputer 42 based on the pulse signal from the water flow sensor 35 generated in accordance with the quantity of water passing through the water pipe 30, and at the same time, When the quantity passing through becomes a certain amount or more, the switching signal is transmitted to the relay circuit power supply 45b of the power supply unit 45. The microcomputer 42 performs predetermined sequence control, combustion amount control, and quantity control.

In this embodiment, the control signal of H lever is used as an operation signal as an energization signal of each solenoid valve or a drive signal of a geared motor. In the normal operation from the microcomputer 42, a pulse signal indicating the operation of the microcomputer 42 is sent to the safety circuit 43. The safety circuit 43 is a microcomputer when an abnormality is detected in any one of a flame detection signal from the flame detection circuit 58, a flow signal from the current flow circuit 59, and a pulse signal which is constantly transmitted during the operation of the microcomputer 42. A circuit for sending a switching signal for stopping the power supply to the computer 42 and the solenoid valve energizing relay circuit 44.

The solenoid valve energization relay circuit 44 is a relay for energizing the original solenoid valve 21, the kettle valve 22, and the conversion valve 24 by the H level control signals from the microcomputer 42, respectively. Circuit, and the solenoid valve driving means of the present invention. The power supply unit 45 converts the electric power for driving the respective circuits of the control device 40 into the voltages required for the respective circuits when the plug (not shown) is inserted into the outlet. The power supply for the microcomputer power supply 45a for supplying power to the power supply 42 and the relay circuit power supply 45b for supplying power to the solenoid valve energization relay circuit 44 is supplied with a power supply rectification signal from the safety circuit 43. There is a switching function for stopping, stopping the operation of the microcomputer 42 and stopping the energization to each solenoid valve and stopping the fuel supply. The relay circuit power supply 45b for supplying power to the solenoid valve energization relay circuit 44 is capable of energizing each solenoid valve only when a switching signal is transmitted from the water flow circuit 59, and the flow of water is not detected. In this case, since no fuel gas is supplied to the burner group 11, there is no fear of empty pot heating. In addition, the power supply unit 45 is further equipped with a temperature fuse, an overheat switch, and an anti-boiling switch, which are not shown, in a converter connected to a commercial power source to further ensure safety. The controller 46 is for setting and operating the humidifying water heater, and has a small capacity microcomputer and communication circuit operated by electric power from the communication circuit 57 to exchange signals with the microcomputer 42, The set signal is modulated and sent to the microcomputer 42. The controller 46 has a display function, and displays the set tapping temperature by a digital number such as a liquid crystal, and at the same time by a lamp indicating that the combustor 10 is burning.

The mode setting circuit 47 is a circuit which is preset at the time of shipment from the factory or at the time of installation of the gas water heater according to the type of gas, the presence of the remote control, the hot water supply capability, the exhaust facility, etc. using the operation mode of the microcomputer 42. It is set by a dip switch connected to each terminal of the custom IC constituting the computer 42, and the microcomputer 42 operates in a mode different from that potential depending on whether the potential of each terminal is H level or L level. .

Next, the circuit of the safety circuit 43 and the microcomputer power supply 45a is demonstrated based on FIG. In the safety circuit 43, 61 and 62 each represent an inverting circuit not shown for the control signals of the solenoid valve 21 and the kettle valve 22, which are sent from the microcomputer 42 to the solenoid valve energizing relay circuit 44, respectively. Is a coupler to input the flame detection signal from the flame detection circuit 58, 64 is a combiner to input the water flow detection signal from the current flow circuit 59, and 65 is a microcomputer. And a combiner for inputting the outgoing pulse signal to indicate the operating state from (42). TR ₁ , TR ₂ and TR ₃ are all transistors, TR ₁ and TR ₂ are NPN transistors of emitter ground, and TR ₃ is PNP transistors. And INV ₁ to INV ₅ are inverters for reversing the phase of the input signal, R ₁ to R ₉ are resistors, C ₁ to C ₄ are capacitors, OR ₁ , OR ₂ , OR ₃ are oa circuits, and D ₁ to D ₅ Is a diode. On the other hand, in the microcomputer power supply 45a, TR ₁₁ , TR ₁₂ and TR ₁₃ are transistors, R ₁₀ to R ₁₅ are resistors C ₁₁ and C ₁₂ are capacitors, and B and D are bridge diodes, and the combiners 66 and 67 are used. ) Is connected to the secondary coil of a power supply transistor (not shown), and power is supplied to the microcomputer 42 via the constant voltage circuit (not shown) which causes the couplers 68 and 69 to have a positive potential and a negative potential, respectively.

Next, the current flow circuit 59 and the relay circuit power supply 45b will be described with reference to FIG. Any one of the couplers 71, 72, 73 of the water flow circuit 59 is connected to the water flow sensor 35. The coupler 71 has a ground potential, and the coupler 72 has operating power + V. _DD is supplied to the water flow sensor 35, and a pulse generated from the water flow sensor 35 is input to the combiner 73. TR ₁₄ and TR ₁₅ are emitter grounded transistors that invert and output the voltage phase of the input signal, 74 is a comparator R ₁₆ to R ₂₄ is a resistor, ZD is a zener diode, D ₆ is a diode, and C ₁₃ , C ₁₄ Is the capacitor.

When the pulse amplitude of the input pulse signal is greater than or equal to a predetermined voltage, the signal input to the transistor TR ₁₄ through the zener diode ZD and output again through the transistor TR ₁₅ is a diode D ₆ and a resistor R. ₁₉ ) When the capacitor C ₁₃ is charged and its charge potential is higher than or equal to the predetermined voltage determined by the resistors R ₂₁ and R ₂₂ , the output of the comparator 74, which has been H level, is inverted to H level. It is sent to the relay circuit power supply 45b as a switching signal. The pulse signal output from the transistor TR ₁₅ of this water flow circuit 59 is sent from the combiner 75 to the microcomputer 42, and the output signal of the comparator 74 is the water flow signal through the combiner 76. It is also sent out to the safety circuit 43 as a. The power supply 45b for the relay circuit is composed of a diode D ₇ , a transistor TR ₁₆ , a TR ₁₇ , a resistor R ₂₅ , and a R ₂₆ . The electric power supplied from the coupler 77 connected to 68 is supplied to the solenoid valve energization relay circuit 44 via the coupler 78 by switching of the transistor TR ₁₇ . The signal for stopping the power supply from the safety circuit 43 to the microcomputer power supply 45a is connected through the combiner 70, and the power supply when the H level signal is transmitted is stopped.

The gas water heater of this embodiment with the above structure operates as follows.

When the user inserts the operation switch of the controller 46 and sets the tapping temperature and operates the tap water not shown, the water supplied by the supply pipe 31 passes through the water quantity control valve 34 and the water flow sensor 35. Flows into the heat exchanger 32 and the bypass pipe 32a, and flows out from the heat exchanger 32 and the bypass pipe 32a by the bypass valve 33 to control the hot water supply pipe 31a. Out of the hot water supply port without a city. At this time, a pulse signal according to the water flow is generated by the water flow sensor 35, and is transmitted as a switching signal and a pulse signal to the solenoid valve energization relay circuit 44 and the microcomputer 42 via the water flow circuit 59, respectively. In the solenoid valve energization relay circuit 44, each solenoid valve becomes energizable in accordance with the control signal of the microcomputer 42, while the microcomputer 42 detects a predetermined number or more of the transmitted pulse signals and the combustor 10 The spark discharge is performed on the sparker 14 by the ignition operation. At this time, since the flame detection signal 58 is not yet transmitted from the flame detection circuit 58, the L-level signal is transmitted to the combiner 63, and the transistor TR ₁ is turned off to the capacitor C ₁ . In addition, since the control signals of the solenoid valve 21 and the kettle valve 22 by the microcomputer 42 are still at the L level as closed signals, the inverter 61 and 62 have an inverting circuit not shown. The control signal of the H level is transmitted through, and the signals input to the OR circuit ₁ through the INV ₁ (INV ₂ ) are all at the L level, so the output of the OR circuit ₁ is at the L level. do.

Therefore, the capacitor C ₁ is kept at the L level, and the voltage output from the diode D ₂ through the inverter INV ₃ (INV ₄ ) is at the L level. The high voltage signal is transmitted from the water flow circuit 59 to the combiner 64 so that the transistor TR ₂ is turned on, and the output of the L level of the OR circuit OR ₁ is the OR circuit OR ₂ . Since the capacitor C ₂ is applied to the capacitor C ₂ through the resistor R ₄ , the capacitor C ₂ remains at the L level, and the voltage output from the diode D ₄ through the OR circuit OR ₃ becomes L level. . The charging charge of the capacitor C ₃ , which is charged through the resistor R ₇ , is discharged from time to time when the pulse amplitude is 0 because the operating pulse from the microcomputer 42 is input to the combiner 65, and the transistor TR _3. ) Output becomes H level. Therefore, the capacitor C ₄ is maintained at the H level through the resistor R ₈ , and the voltage output from the diode D ₅ via the inverter INV ₅ is at the L level.

As a result, the signal transmitted to the transistor TR ₁₃ via the coupler 70 and the resistor R ₁₀ is at the L level, and the transistor TR ₁₃ is turned off, so the transistor TR ₁₂ is turned on and again. The transistor TR ₁₃ is also turned on. Therefore, the safety circuit 43 does not operate, and power is supplied from the combiner 68 to the microcomputer 42 in the microcomputer power supply 45a. Then, when the spark discharge in the sparker 14 is detected by the operation detection unit of the sparker circuit 51, the microcomputer 42 returns the control signals of the original solenoid valve 21 and the kettle valve 22, which were the L level signals. The valve is switched to the H level signal for opening each solenoid valve and sent out. Here, in the safety circuit 43, the resistance of the resistors R ₁ and R ₄ is set sufficiently large, and the potential of the capacitors C ₁ and C ₂ is maintained even when the output of the OR circuit OR ₁ is at the H level. Since it does not rise immediately, the safety circuit 43 does not operate and power is continuously supplied to the microcomputer 42 for a predetermined time even after the control signal of each solenoid valve becomes an H level signal.

Therefore, the original solenoid valve 21 and the kettle valve 22 are energized by the solenoid valve energization relay circuit 44 and the fuel gas is ejected from the nozzle 13 and mixed with the combustion air, and is supplied to the burner group 11. It is ignited by the sparker 14 which is already working. It is ignited within a predetermined time until the potential of the condenser C ₁ rises and is detected by the frame rod 15, and the flame detection signal is transmitted from the flame detection circuit 58 to the combiner 63 with the H level signal. In this case, since the output of the transistor TR ₁ is at the L level, the charge of the capacitor C ₁ that is being raised is discharged, and the capacitor C ₁ is kept at the L level. Then, the microcomputer 42 obtains the on-demand demister 36, the heat-exchanging demister 37, the dummy signal of the tapping-heat dummy dummy 38 and the water flow sensor 35, and the setting signal from the controller 46. The required combustion amount is calculated based on the calculation result, and the air-fuel ratio correction control is also performed based on the calculation result. However, the air-fuel ratio control is not performed for a predetermined time until the temperature of the decoupler 16 is stabilized. Thereafter, the amount of tapping and the set temperature change, and according to the change, the ratio of the flow rate of the heat exchanger 32 and the bypass pipe 32a and the amount of combustion by the bypass valve 33 are changed. For example, if the microcomputer 42 malfunctions or congests during combustion, the microcomputer 42 cannot read the pulse signal from the water flow circuit 59 as an input signal correctly. Therefore, even if the water flow flowing into the heat exchanger 32 is lost and the pulse signal from the water flow circuit 59 stops, the determination is difficult in the microcomputer 42.

However, in the gas water heater of this embodiment, the relay circuit power supply 45b stops energizing the solenoid valve energization relay circuit 44 by the switching signal from the water flow circuit 59, so that each solenoid valve is closed and the burner group The fuel supply to (11) is stopped. When the control signal of each solenoid valve is misfired by repeating the H level and the L level, the microcomputer 42 stops the flame from being detected by the frame rod 15 and from the flame detection circuit 58. The flame detection signal of the H level is stopped to reach the L level. Then, the output of the transistor TR ₁ becomes H level and the potential of the capacitor C ₁ rises, so that the signal of the H level is input to the transistor TR ₁₃ through the diode D ₂ and the resistor R ₁₀ . Since the transistor TR ₁₃ is turned on and the transistors TR ₁₂ and TR ₁₁ are both turned off, the power supply from the microcomputer power supply 45a to the microcomputer 42 is stopped.

Therefore, the microcomputer 42 stops all the operations, and does not transmit the H level signal for opening each solenoid valve. Therefore, fuel gas is not leaked and safety can be ensured.

In this embodiment, the relay circuit power supply 45b for supplying power to the solenoid valve energization relay circuit 44 also has a power supply stop signal from the safety circuit 43, and the power supply to the solenoid valve energization relay circuit 44 is reduced. Since it stops and the electricity supply of each solenoid valve is not performed, safety can be ensured further. The safety circuit 43 can stop the power supply even when the H-level signal is stopped as the water flow signal from the current circuit 59, so that it is possible to prevent an air-bus and the like. In the safety circuit 43, the operation pulse from the microcomputer 42 is checked, and since the abnormality of the microcomputer 42 can be detected directly, safety can be ensured in double.

In the above description, description has been made for misfires involving the abnormality of the microcomputer 42, but of course, outflow of fuel gas can be prevented and safety can be ensured even in normal misfires.

In the present embodiment, the embodiment of the gas water heater is shown, but abnormal heating of the same gas station and the heating apparatus can be prevented even when using a different fuel such as petroleum. The liquid to be heated is not limited to only water such as a hot water heater and a water dispenser, but can be protected similarly in a liquid heating apparatus in an automatic processing facility that heats raw materials of industrial products, paints, foodstuffs and the like.

Claims (1)

Heating means for heating a liquid passing through the heat exchanger; Liquid detecting means for detecting a liquid flowing into the heat exchanger and transmitting a liquid detecting signal; Control means for operating on the basis of the liquid detection signal detected from said liquid detection means, and sending out a control signal for controlling the heating state of said heating means; Drive means for operating the heating means in accordance with a control signal sent from the control means when the electric power for operation is supplied, and for stopping the operation of the heating means when the electric power for operation is not supplied; And a switching means for supplying electric power for operation to the drive means only when a liquid detection signal is sent from the liquid detection means.

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