KR930007080B1 - Water flow sensing type starting device - Google Patents

Abstract

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Description

Water Flow Detection Starter

1 is a circuit diagram showing a water flow circuit of a gas water heater using the present invention.

2 is a configuration diagram schematically showing a gas water heater of the present embodiment,

3 is a block diagram showing a control device of the gas water heater of this embodiment.

4 is a circuit diagram showing a conventional water flow circuit.

* Explanation of symbols for main parts of the drawings

35: water flow sensor (pulse generation means) 70: F / V conversion circuit (F / V conversion means)

74: comparator (water leveling means)

The present invention relates to a water flow detection start device for starting the operation of the device by detecting the water flow through the water flow path.

In a hot water supply facility such as a hot water heater, a heating device for heating water controls the amount of heating according to the amount of water passing through the water pipe. For this reason, the pulse generating type water flow sensor which generate | occur | produces the number of pulses according to the quantity which passes through a water pipe is installed in a water pipe. In addition, the hot water heater detects the water passing through the water pipe and starts the operation when the user uses the water.

At this time, the start of the operation of the heating device is a starting device 100 using a pulse generated from the water flow sensor installed for controlling the heating amount. In the starter 100, as shown in FIG. 4, the pulse signals from the water flow sensor input from the terminal 101 are waveform-formed by the transistors 102 and 103, and the output voltages are converted into the resistors 104 and capacitor 105. ), Switching is performed by the comparator 106 based on the voltage after smoothing. Here, the reference voltage of the comparator 106 is set by adjusting the semi-fixed resistor 109 provided in series between the resistor 107 and the resistor 108.

However, in a hot water heater etc., the amount of hot water required is not necessarily limited to a large quantity. Therefore, when the hot water supply amount is small, the heating apparatus needs to operate reliably. However, in the case of a small amount of hot water supply, in the conventional starter 100 shown in FIG. 4, since the pulses input to the terminal 101 are simply waveform-shaped, the hot water supply amount is particularly small, and the number of input pulses is small. The charging potential of the capacitor 105 was lowered, and a sufficient output voltage according to the flow rate could not be obtained. Therefore, even if the semi-fixed resistor 109 is adjusted, there is a problem in that the heating device cannot be operated because a reliable switching signal is not obtained from the comparator 106.

An object of the present invention is to provide a water flow detection type starter that can reliably operate the device even when the amount of hot water is small.

The present invention provides a pulse generating means for generating a number of pulses in accordance with the amount of water passing through the water tank, F / V conversion means for generating an output voltage according to the number of pulses generated by this pulse generating means, and this F / V conversion Technical means consisting of switching means for generating an operation signal when the output voltage of the means is above a predetermined voltage is employed.

According to the present invention, a number of pulses are generated from the pulse generating means according to the quantity, and converted into voltage according to the number of pulses by the F / V converting means. In the switching means, when the output voltage of the F / V conversion means becomes higher than a predetermined voltage, an operation signal is generated to operate the device.

In the present invention, since the pulse generated by the pulse generating means is F / V converted into a voltage corresponding to the number of pulses, the switching means can input a voltage corresponding to the quantity even when the quantity of water passing through the flow path is small. Therefore, the device can be reliably operated when a predetermined quantity of water passes through the water flow passage.

Next, the Example which used the water flow detection type starter of this invention for a gas water heater is demonstrated based on drawing.

The gas water heater of this embodiment shown schematically in FIG. 2 is composed of a combustor 10, a fuel pipe 20, a water pipe 30, and a control device 40.

The combustor 10 is provided in the hot water heater case 1, and consists of the burner group 11 which arrange | positioned several ribbon burners in two rows, and the combustion fan 12 which supplies combustion air. Fuel gas is supplied to the burner group 11 from the nozzle 13, and combustion is performed by the combustion air supplied by the combustion fan 12, and the combustion gas generated by the combustion is discharged from the exhaust port 2. .

Above the burner group 11, the sparker 14 of the ignition apparatus and the flame rod 15 for flame detection are provided, respectively.

The fuel pipe 20 supplies fuel gas to the nozzle 13, and the primary solenoid valve 21, the kettle valve 22, and the bire valve 23 are provided in order from the upstream side, respectively, and the proportional valve 23 is provided. Downstream of), the fuel pipe 20 is branched so as to supply fuel gas to each row of the burner group 11, and one of the burner groups 11 arranged in two rows is arranged in one branched fuel pipe 20. A switching valve 24 for stopping combustion is provided.

The proportional valve 23 controls the supply amount of fuel gas by adjusting the supply pressure of the fuel gas supplied from the nozzle 13 to the burner group 11 in proportion to the energizing current.

The water pipe 30 is composed of a water supply source and a hot water supply port (not shown) and a supply pipe 31 and a hot water supply pipe 31a connected to each other, and a heat exchanger 32 and a bypass pipe 32a provided in communication therewith. The bypass valve 33 is provided in the confluence part of the heat exchanger 32 and the downstream of the bypass pipe 32a. A part of the water supplied from the supply pipe 31 flows through the heat exchanger 32, and the remaining part is led to the hot water supply pipe 31a through the bypass pipe 32a, and the water heated by the heat exchanger 32 The ratio of the water directly led by the bypass pipe 32a is controlled by the bypass valve 33. On the other hand, the supply pipe 31 is provided with the water supply control valve 34, the water flow sensor 35, and the water-injection temperature dummyster 36 from the upstream side, and the hot water supply pipe 32a is provided with the tapping-temperature dummyster 38.

As shown in FIG. 3, the control device 400 includes a microcomputer 42 having an interface with the input / output circuit 50, the safety circuit 43 for securing safety, and the solenoid valve energization. It consists of the relay circuit 44, the power supply part 45 which supplies electric power, and each circuit of the input / output circuit 50, the controller 46 for operating the operation of a gas water heater, and the microcomputer 42 The mode thrust circuit 47 is set in advance at the time of shipment from the factory or at the time of gas hot water supply, depending on the type of gas used in the operation mode, the presence or absence of the remote control, the hot water supply capacity, the exhaust facility, and the like.

The stabilization circuit 43 micomes a power stop signal for stopping power supply to the microcomputer 42 when a combustion stop signal is input from the microcomputer 42, the flame detection circuit 58, and the water flow circuit 59, respectively. Output to the power supply 45a.

The solenoid valve energization relay circuit 44 is a relay circuit for energizing the basic solenoid valve 21, the kettle valve 22, and the switching valve 24 in accordance with control signals from the microcomputer 42.

When the power supply unit 45 inserts a plug (not shown) into an outlet, the power supply 45 converts power for operating each circuit of the control device 40 into a voltage required for each circuit and always supplies the power. In the present embodiment, the microcomputer power supply 45a for supplying power to the microcomputer 42 has a water leveling function for stopping power supply to the microcomputer 42 in response to the combustion stop signal of the burner to the safety circuit 43. The operation of the microcomputer 42 is stopped by stopping the power supply. In addition, the relay circuit power supply 45b for supplying power to the solenoid valve energization relay circuit 44 has a switching function for starting supply of power to the solenoid valve energization relay circuit 44 in response to a flow signal from the water flow circuit 59. In addition, when water in the supply pipe 31 flows in, power is supplied to each solenoid valve, and when supply is stopped, power is supplied to each solenoid valve to stop supply of fuel.

The input / output circuit 50 is a circuit for signal exchange with each of the above-described parts provided in the gas water heater. In the input / output circuit 50, each header disposed in the sparker circuit 51 and the water pipe 30, which generates a high voltage in order to perform spark discharge on the sparker 14, and detects the spark discharge in the sparker 14. Geared motor drive circuit 54 which drives the water temperature detection circuit 53, the bypass valve 33, and the quantity control valve 34 to obtain respective temperature signals from the resistance of the MR based on signals of a potentiometer (not shown). A fan circuit 55 and a controller 46 for driving the combustion fan 12 based on a control signal from the microcomputer 42 and outputting a pulse signal for detecting the rotation speed of the combustion fan 12. Transmits a pulse signal from the water flow sensor 35 generated according to the quantity of water passing through the communication circuit 57 and the water pipe 30 to exchange signals with the microcomputer 42 and passes through the water pipe 35 at the same time. Switching signal to supply power when the quantity Is supplied to the relay circuit power supply 45b and the safety circuit 43 of the power supply unit 45, and the proportional valve circuit 60 for energizing the proportional valve 60 for controlling fuel gas is provided. have.

Next, the water flow circuit 59 will be described based on FIG.

The terminals 61, 62 and 63 are all connected to the water flow sensor 35, the terminal 61 supplies the voltage V _DD supplied from the power supply unit 45 and the terminal 62 is connected to the ground circuit and the terminal In (63), a pulse generated from the water flow sensor 35 is input.

The cathode of the zener diode 64 is connected to the terminal 63, and pulses of a predetermined voltage or more passing through the zener diode 64 are waveform-shaped by the NPN transistors 65 and 66. The waveform shaped by the transistor 566 is sent out from the terminal 68 to the microcomputer 42. The output of the transistor 66 is input to the F / V conversion circuit 70 through the capacitor 69.

The F / V conversion circuit 70 converts the input pulse into a DC voltage by the F / V conversion element 71, and the DC voltage corresponding to the input pulse number is output. A capacitor 73 is connected to the output portion 70a of the F / V conversion circuit 70 between the ground electrode 72 and the output voltage of the F / V conversion circuit 70 is stabilized by the capacitor 73. do. The non-inverting input terminal 74a of the comparator 74 is connected to the output portion 7a of the F / V conversion circuit 70. On the other hand, the inverting pressure terminal 74b of the comparator 74 is inputted with a reference voltage obtained by dividing the power supply voltage V _DD by the resistors 75 and 76.

The comparator 74 outputs a signal of "H" level when the output voltage of the F / V conversion circuit 70 input to the non-inverting input terminal 74a is higher than the reference voltage input to the inverting input terminal 74b. In addition, the comparator 74 has a hysteresis characteristic in order to ensure the stability of the operation as a starter, and inverting the output to the "L" level is a case where the inverting voltage is set lower than the reference voltage.

The output terminal 74c of the comparator 74 is connected to the terminal 77. The terminal 77 is connected to the safety circuit 43 and the relay circuit power supply 45b to send a start signal, respectively.

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

When the user enters the operation switch by the controller 46 and sets the tapping temperature and opens the water cock (not shown), the water supplied by the supply pipe 31 is connected to the water flow control valve 34 and the water flow sensor 35. Passed through the heat exchanger 32 and the bypass pipe (32a), and each of the outflow amount is adjusted in the bypass valve 33 and flows out from the hot water supply port (not shown) through the hot water supply pipe (31a). When the water passes through the supply pipe 31, the water flow sensor 35 generates a number of pulses according to the amount of water passing therethrough, and is input to the water flow circuit 59 through the terminal 63 as shown in FIG. The input pulse passes through the zener diode 64 and is waveform-shaped by the transistors 65 and 66. The waveform-shaped pulses are sent out from the terminal 68 to the microcomputer 42 and are differentiated by the capacitor 69 and input to the F / V conversion circuit 70. In the F / V conversion circuit 70, pulses are converted into voltages corresponding to the number of pulses to be input. Therefore, the F / V conversion circuit 70 outputs a voltage corresponding to the quantity detected by the water flow sensor 35.

When the output voltage of the F / V conversion circuit 70 is inputted to the non-inverting input terminal 74a, the comparator 74 indicates that the quantity of water flowing into the supply section 31 is equal to or greater than the predetermined quantity. The signal of " level is outputted and sent to the relay circuit power supply 45b and the safety circuit 43 through the terminal 77. Thereby, the relay circuit power supply 45b supplies electric power to the solenoid valve energizing relay arc 44, and the solenoid valve energizing relay circuit 44 can drive each solenoid valve according to the control signal from the microphone computer 42. It is in a state.

On the other hand, the safety circuit 43 operates the microcomputer power supply 45a at a predetermined time from when the power supply is started from the power supply unit 45 regardless of the input signal. Therefore, since electric power is supplied to the microcomputer 42, the microcomputer 42 starts the ignition operation of the combustor 10 by a predetermined sequence.

When spark discharge is performed on the sparker 14 by the ignition operation and the spark discharge is detected by the sparker 14, the solenoid valve 21 and the kettle valve 22 are energized, and fuel gas is discharged from the nozzle 13. It is ejected, mixed with combustion air, and then supplied to the burner group 11 and ignited by the sparker 14. At this time, the combustion fan 12 and the proportional valve 23 is gently controlled ignition.

When the ignition occurs within a predetermined time and is detected by the flame rod 15, the microcomputer 42 needs the signal based on the detection signals from the water temperature detection circuit 53 and the water flow circuit 59 and the setting signals of the controller 46. The combustion amount is calculated and the combustion fan 12, the proportional valve 23, the switching valve 24, the bypass valve 33 and the water quantity control valve 34 are controlled based on the calculation result.

When the water cock is closed by the user, the pulse generated from the water flow sensor 35 stops, so that the output voltage of the F / V conversion circuit 70 also decreases. Therefore, since the electric charge of the capacitor | condenser 73 discharges and its potential falls, the output of the comparator 74 is inverted to the "L" level. Then, since the relay circuit power supply 45b stops supplying power to the solenoid valve energization relay circuit 44, energization to each solenoid valve is stopped and closed, regardless of the control signal from the microcomputer 42. Therefore, fuel supply is stopped and combustion stops reliably.

As described above, in the water flow detection type starter of the present invention, since the F / V conversion circuit is provided, start and stop can be controlled by a small amount of water passing through the water pipe.

In the present embodiment, the solenoid valve energization relay circuit is started by the current flow detection, but may be used for starting the whole control device or starting the microcomputer.

Claims (1)

Pulse generating means 35 for generating a number of pulses corresponding to the quantity of water passing through the water flow path, F / V converting means 70 for generating an output voltage according to the number of pulses generated by the pulse generating means, and the F A water flow detecting starter comprising a leveling means (74) for generating an operation signal when the output voltage of the / V converting means is equal to or higher than a predetermined voltage.

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