KR100197700B1 - Proportional controlled valve control circuit for a gas oven range - Google Patents

Abstract

The present invention relates to a proportional control valve control circuit of a gas oven, and to control the current sensing unit 20 and the proportional control valve 1 which output a voltage value proportional to the current value flowing in the proportional control valve 1. The microcomputer outputs a first pulse width modulated signal for outputting the second pulse width modulated signal for controlling the maximum value and the minimum value of the current flowing in the proportional control valve 1 according to the output of the current sensing unit 20. 22, a first smoothing circuit 24 for smoothing the first pulse width modulated signal output from the microcomputer and outputting a direct current signal, and without attenuating the voltage level of the DC signal smoothed in the first smoothing circuit 24; A buffer 26 to be transmitted, a second smoothing circuit 28 for smoothing the second pulse width modulation signal and outputting a DC signal, and the buffer according to a voltage value of the DC signal input from the second smoothing circuit 28. Transfer of DC signal input via 26 The current adjusting unit 40 for adjusting the value, the amplifying unit 42 for increasing and outputting the DC signal whose voltage value is adjusted by the current adjusting unit 40 compared with the voltage value of the signal output from the current sensing unit 20 And a proportional control valve driver 44 for supplying current to the proportional control valve 1 according to the signal amplified by the amplifier 42 and output. The maximum and minimum values of can be adjusted automatically.

Description

Acircuit for controlling ratio control valve of gas oven range

The present invention relates to a proportional control valve control circuit of a gas oven, and more particularly, to automatically set the minimum and maximum values of the current flowing in the proportional control valve, and to allow the current to flow in the proportional control valve within the set range. It relates to a proportional control valve control circuit of an oven range.

In general, in a gas oven, a burner is controlled by adjusting an amount of gas supplied to the burner using a proportional control valve.

The conventional proportional control valve control circuit for controlling the proportional control valve as described above is a microcomputer 3 that outputs a pulse width modulation signal (PWM signal) for controlling the proportional control valve 1, as shown in FIG. ), A smoothing circuit 5 for smoothing the pulse width modulated signal and outputting a DC signal, a buffer 7 for smoothly transmitting the voltage level of the DC signal input smoothed by the smoothing circuit 5, and proportional control. First variable resistor VR1 for setting the maximum value of the current flowing in the valve 1, Second variable resistor VR2 for setting the minimum value of the current flowing in the proportional control valve 1, Proportional control valve 1 The current detector 9 outputs a DC signal whose voltage is adjusted by the current detector 9 and the first variable resistor VR1 and the second variable resistor VR2 that detect and output a current value flowing through the current detector 9. A non-inverting amplifier 11 for comparing and amplifying the output signal and outputting Amplified by the non-inverting amplifier unit 11 it is configured by a proportional control valve driving unit 13 for supplying a current to the proportional control valve (1) according to the output signal.

In the conventional proportional control valve control circuit configured as described above, when the pulse width modulation signal is output from the microcomputer 3, the signal is smoothed by the smoothing circuit 5 and output as a DC signal having a constant voltage. That is, as the duty of the pulse width modulated signal output from the microcomputer 3 increases, a DC signal having a large voltage value is output from the smoothing circuit 5.

The DC signal obtained as described above has a sufficient current value while passing through the buffer 7, and the DC signal output through the buffer 7 is formed by the first variable resistor VR1 and the second variable resistor VR2. The voltage value is adjusted. At this time, the variable resistors VR1 and VR2 are manually adjusted in advance so that the minimum and maximum values of the current flowing through the proportional control valve 1 can be defined using a measuring instrument.

As described above, the DC signal whose voltage value is adjusted by each of the variable resistors VR1 and VR2 is input to the non-inverting terminal of the OP-amp2 of the amplifier 11 and detected by the detector 9. The signal is input to the inverting terminal of the OP-amp2.

The amplifier 11 compares and amplifies the signals input through the non-inverting terminal and the inverting terminal as described above and inputs them to the bare end of the NPN transistor TR1 of the proportional control valve driving unit 13 so that the transistor ( Turn TR1) on / off. When the NPN transistor TR1 is 'on', the NPN transistor TR2 is also 'on' so that a current flows in the proportional control valve 1, and when the NPN transistor TR1 is 'off', TR2 is also 'off' so that no current flows through the proportional control valve 1.

That is, the amount of current flowing in the proportional control valve 1 is adjusted by supplying or interrupting the current in the proportional control valve 1 as described above. However, the conventional proportional control valve control circuit as described above is inconvenient for the user to directly adjust the resistance values of the variable resistors VR1 and VR2 to set the maximum and minimum values of the current flowing in the proportional control valve 1. There was this.

The present invention has been made to solve the above-mentioned conventional problems, and an object thereof is to provide a proportional control valve control circuit of a gas oven which can automatically set the minimum and maximum values of the current flowing in the proportional control valve. .

The proportional control valve control circuit of the gas oven according to the present invention for achieving this object, the first pulse for controlling the proportional control valve and the current sensing unit for outputting a voltage value proportional to the current value flowing in the proportional control valve. The microcomputer outputs a width modulated signal and outputs a second pulse width modulation signal for controlling the maximum and minimum values of current flowing through the proportional control valve according to the output of the current sensing unit, and the first pulse width modulation output from the microcomputer. A first smoothing circuit for smoothing a signal and outputting a DC signal, a buffer for transmitting the voltage level of the DC signal smoothed in the first smoothing circuit without attenuation, and a second pulse width modulating signal output from the micom to smoothing the direct current signal A second smoothing circuit for outputting a direct current input through the buffer 26 according to a voltage value of a direct current signal input from the second smoothing circuit; A current adjusting unit for adjusting a voltage value of a signal, an amplifier unit for comparing and outputting a DC signal whose voltage value is adjusted by the voltage adjusting unit with a voltage value of a signal output from the current sensing unit, and amplified by the amplifying unit And a proportional control valve driver for supplying current to the proportional control valve according to the output signal.

1 is a circuit diagram of a proportional control valve control circuit of a conventional gas oven,

2 is a circuit diagram of a proportional control valve control circuit of the gas oven according to the first embodiment of the present invention;

3 is a circuit diagram of a proportional control valve control circuit of a gas oven according to an embodiment of the present invention;

4 is an operation flowchart of the proportional control valve control circuit of the gas oven according to the present invention;

5a to 5d are views for explaining the process of setting the maximum value and the minimum value of the current flowing in the proportional control valve in the present invention.

2 is a circuit diagram of a proportional control valve control circuit of a gas oven according to a first embodiment of the present invention. The first embodiment of the present invention includes a current sensing unit 20, a microcomputer 22, and a first smoothing. The circuit 24, the buffer 26, the 2nd smoothing circuit 28, the voltage control part 40, the amplifier 42, and the proportional control valve drive part 44 are comprised.

The current sensing unit 20 includes the resistance resistors R1 and R2, and outputs a voltage value proportional to the current value flowing in the proportional control valve 1.

The microcomputer 20 outputs a first pulse width modulation signal for controlling the proportional control valve 1 and at the output of the current sensing unit 20, the maximum value of the current flowing through the proportional control valve 1. A second pulse width modulated signal for controlling the minimum value is output.

The first smoothing circuit 24 includes a resistor R3 and a capacitor C1 to smooth a first pulse width modulated signal output from the microcomputer 22 to output a DC signal. Denoted at 26 is to transmit the voltage level of the DC signal smoothed in the first smoothing circuit 24 without attenuation. The second smoothing circuit 28 is composed of a resistor R4 and a capacitor C2 to smooth a second pulse width modulated signal output from the microcomputer 22 to output a DC signal.

In addition, the voltage adjusting unit 40 includes a plurality of resistors R7, R8, and R9, and the direct current input through the buffer 26 according to the voltage value of the direct current signal input from the second smoothing circuit 28. The voltage value of the signal is adjusted.

The amplifier 42 includes an input resistor R10, an op amp (OP-amp2), a feedback resistor R11, an output resistor R12, and a capacitor C3. The DC signal whose voltage value is adjusted is compared and amplified with the voltage value of the signal output from the electrical detection unit 9 so as to be output.

The proportional control valve driver 44 includes an NPN transistor TR1, a PNP transistor TR2, resistors R13 and R14, and diodes D2 and D3 and amplifies the amplifier 42. Then, the current is supplied to the proportional control valve 1 in accordance with the output signal.

3 is a circuit diagram of a proportional control valve control circuit of a gas oven range according to a second embodiment of the present invention. The second embodiment of the present invention includes a current sensing unit 20, a microcomputer 22, and a first smoothing. In the first embodiment of the present invention, which includes a circuit 24, a buffer 26, a second smoothing circuit 28, a voltage adjusting unit 40, an amplifier 42, and a proportional control valve driving unit 44. The variable voltage regulator 30 and the voltage stabilizer 32 are further provided.

The current sensing unit 20 includes voltage divider resistors R1 and R2, and outputs a voltage value proportional to the current value flowing in the proportional control valve 1. The microcomputer 20 outputs a first pulse width modulation signal for controlling the proportional control valve 1, and the maximum value of the current flowing in the proportional control valve 1 according to the output of the current sensing unit 20, and A second pulse width modulated signal for controlling the minimum value is output.

The first smoothing circuit 24 includes a resistor R3 and a capacitor C1 to smooth a first pulse width modulated signal output from the microcomputer 22 to output a DC signal. Denoted at 26 is to transmit the voltage level of the DC signal smoothed in the first smoothing circuit 24 without attenuation.

The second smoothing circuit 28 includes a resistor R4 and a capacitor C2 to smooth a second pulse width modulated signal output from the microcomputer 22 to output a DC signal. The variable voltage regulator 30 is configured to output a variable voltage of the DC signal input from the second smoothing circuit 28, and the voltage stabilizing unit 30 is made of a capacitor C4. The voltage of the DC signal input at 30 is stabilized and input to the voltage adjusting unit 40.

The voltage adjusting unit 40 includes a plurality of resistors R7, R8, and R9, and the DC signal input through the buffer 26 according to the voltage value of the DC signal input from the voltage stabilizing unit 32. To adjust the voltage value. The amplifier 42 includes an input resistor R10, an op amp (OP-amp2), a feedback resistor (R11), an output resistor (R12), and a capacitor (C3), and the voltage adjuster (40). The amplified DC signal whose voltage value is adjusted is compared with the voltage value of the signal output from the current sensing unit 9 so as to be output.

The proportional control valve driver 44 includes an NPN transistor TR1, a PNP transistor TR2, resistors R13 and R14, and diodes D2 and D3 and amplifies the amplifier 42. Then, the current is supplied to the proportional control valve 1 in accordance with the output signal.

The operation of the proportional control valve control circuit of the gas oven according to the present invention configured as described above will be described in detail with reference to FIGS. 4 and 5a to 5d.

When power is applied to the microcomputer 22, the microcomputer 22 first performs an operation for setting the maximum value and the minimum value of the current flowing in the proportional control valve 1 as follows.

(1) Minimum current value setting

As shown in FIG. 4, the microcomputer 22 has a first pulse width modulated signal and a second pulse width having a duty of 0% through the first output port P1 and the second output port P2. Each of the modulated signals is output, and the voltage value output from the current sensing unit 20 is received through the input port P3 to start sensing the amount of current flowing in the proportional control valve 1 (S1). Subsequently, the duty of the second pulse width modulated signal output through the second output port P2 is gradually increased. (S2)

At this time, when the voltage value input through the input port P3 reaches the preset voltage detected when the minimum current flows in the proportional control valve 1, the duty of the second pulse width modulated signal at this time is stored as the minimum duty. (S3, S4).

The preset voltage is preset by multiplying the minimum current value flowing through the proportional control valve 1 by the resistance value of the resistor R1.

(2) Maximum current value determination

The microcomputer 22 outputs the second pulse width modulated signal output through the second output port P2 with the minimum duty set by the above process, and the first output through the first output port P1. The pulse width modulated signal is output at a duty of 100% (S5). Then, the duty of the second pulse width modulated signal output through the second output port 2 is gradually increased (S6). At this time, when the voltage value input through the input port P3 reaches the preset voltage detected when the maximum current flows in the proportional control valve 1, the duty of the second pulse width modulation signal at this time is stored as the maximum duty. (S7, S8).

(2) Duty setting of the second pulse width modulated signal

The average value of the minimum duty and the maximum duty obtained as described above is calculated, and the average value is set as the reference duty of the second pulse width modulated signal output through the second output port 2 of the microcomputer 22 (S9). When the duty of the first pulse width modulated signal is increased based on 50%, the reference duty of the second pulse width modulated signal is changed to the maximum duty direction and to the minimum duty direction when the duty cycle is reduced (S10, S11, S12, S13).

That is, as the duty of the second pulse width modulation signal increases, the maximum value and the minimum value of the current flowing in the proportional control valve 1 increase, and as the duty of the second pulse width modulation signal decreases, the proportional control valve 1 increases. The maximum and minimum values of the flowing current fall. Therefore, it is possible to control within the target maximum current value and minimum current value which flow through the proportional control valve 1.

At this time, the change amount (maximum value-minimum value) of the current flowing in the proportional control valve 1 is made constant by the voltage adjusting section 40. For example, as shown in FIG. 5A, when the maximum target current flowing in the proportional control valve 1 is 150 mA and the minimum target current is 30 mA, the duty of the second pulse width modulated signal is 50%. When fixed, as shown in FIG. 5B, the maximum current flowing in the proportional control valve 1 due to the duty change of the first pulse width modulated signal is 140 mA, and the minimum current is 40 mA.

In addition, when the duty of the second pulse width modulated signal is fixed to 0%, as shown in FIG. 5C, the maximum current flowing through the proportional control valve 1 due to the change in duty of the first pulse width modulated signal is 130 mA. The minimum current value is 30 mA. When the duty of the second pulse width modulated signal is fixed to 100%, as shown in FIG. 5D, the maximum current flowing through the proportional control valve 1 due to the duty change of the first pulse width modulated signal is 150 mA. The minimum current value is 50 mA.

As described above, when the second pulse width modulated signal output from the second output port P2 is fixed to an arbitrary value, the current adjustable by the first pulse width modulated signal output through the first output port P1 is determined. Since the change amount is fixed by the resistors R7, R8 and R9 of the voltage adjusting unit 40, the change amount of the actually adjustable current is determined to be slightly smaller than the target current change amount (maximum value-minimum value). The duty of the first pulse width modulated signal and the second pulse width modulated signal is adjusted to meet the desired target value.

As described above, the first pulse width modulated signal output from the microcomputer 22 is smoothed by the first smoothing circuit 24 and then input to the voltage adjuster 40 without attenuation through the buffer 26. At this time, the duty of the second pulse width modulated signal output from the microcomputer 22 changes according to the duty of the first pulse width modulated signal, and the second pulse width modulated signal output as described above is a second smoothing circuit ( 28 is smoothed and input to the voltage adjuster 40.

The voltage adjusting unit is input to the amplifier 42 for adjusting the voltage of the signal input through the buffer according to the signal input through the second smoothing circuit 28, the amplifier 42 is the voltage adjusting unit Compared with the voltage value of the DC signal input through the 40 and the voltage value input from the current sensing unit 20 when the voltage of the non-inverting stage is larger than the inverting stage, and outputs a 'high' signal (24V), small Outputs a low signal (0V).

The NPN transistor TR1 and the PNP transistor TR2 of the proportional control valve driver 44 are both turned on when the high signal is output from the amplifier 42 and is applied to the proportional control valve 1. The current is applied, and as the time for which each of the transistors TR1 and TR2 is 'on' increases, a large current flows in the proportional control valve 1.

Meanwhile, in the second embodiment of the present invention, the variable voltage regulator 30 varies the voltage of the DC signal input from the second smoothing circuit 28 and outputs the voltage, and the voltage stabilizing unit 30 outputs the variable voltage. As the voltage of the DC signal input from the regulator 30 is stabilized and input to the voltage adjusting unit 40, a more stable DC signal can be input to the voltage adjusting unit 40 in comparison with the first embodiment of the present invention. will be.

As described above, the present invention can automatically adjust the maximum and minimum values of the amount of current flowing in the proportional control valve. The present invention as described above has been described taking an example of controlling the proportional control valve used in the gas oven, it is obvious that it is applicable to all fields using the proportional control valve is not limited to the gas oven.

Claims (5)

A current sensing unit for outputting a voltage value proportional to a current flowing in the proportional control valve, a first pulse width modulation signal for controlling the proportional control valve, and a current flowing in the proportional control valve according to the output of the current sensing unit A microcomputer for outputting a second pulse width modulation signal for controlling the maximum value and the minimum value of the first signal; a first smoothing circuit for outputting a direct current signal by smoothing the first pulse width modulation signal output from the microcomputer; A buffer for transmitting the voltage level of the DC signal without attenuation, a second smoothing circuit for outputting a DC signal by smoothing the second pulse width modulated signal output from the microcomputer, and a voltage value of the DC signal input from the second smoothing circuit. A current adjusting unit for adjusting a voltage value of the DC signal input through the buffer according to the present invention, and a DC signal having a voltage value adjusted by the voltage adjusting unit A gas oven including an amplifier for comparing and amplifying and outputting the voltage value of the signal output from the current sensing unit, and a proportional control valve driver for supplying current to the proportional control valve according to the signal amplified and output from the amplifier The proportional control valve control circuit of the stove. The voltage stabilizer of claim 1, further comprising: a variable voltage regulator for varying and outputting a voltage of the DC signal input from the second smoothing circuit; The proportional control valve control circuit of the gas oven, characterized in that further provided. The method of claim 1, wherein when the duty of the first pulse width modulated signal is set to 0% and the duty of the second pulse width modulated signal is increased from 0%, the micro current flows through the proportional control valve. And the duty of the second pulse width modulated signal of the gas oven is set to the minimum duty. 4. The method of claim 3, wherein the duty of the first pulse width modulated signal is set at 100% and the duty of the second pulse width modulated signal is increased from the minimum duty to output the first pulse width. And the duty of the second pulse width modulated signal at the time of setting is set to the maximum duty. The second pulse width modulation method according to claim 4, wherein the microcomputer calculates an average value of minimum duty and maximum duty of the second pulse width modulated signal, and based on the average value of the second pulse width modulated signal. A proportional control valve control circuit for a gas oven, characterized in that the duty of the signal is varied to control the minimum and maximum values of the current flowing in the proportional control valve.