JP2020150636A - Switching power supply device and combustion device - Google Patents

Abstract

To provide a switching power supply device that can stably drive a load on the high voltage side even in a case where a current consumed by a load on the low voltage side is small.SOLUTION: A switching element SW1 is turned on/off to control a current amount in an input coil 102, and a first output voltage is generated in a first output coil 103a. A second output coil 103b generates a second output voltage higher than the first output voltage. When a current consumption amount of the first output voltage becomes small, the duty ratio of the switching element is reduced, and a voltage value at a current-detecting resistor R1 connected in series to the input coil is detected to control the duty ratio. Further, when the current consumption amount is less than or equal to the threshold value, the switching element is switched to an intermittent operation state. However, in a case where the current at the second output voltage is consumed, the voltage value at the current-detecting resistor is increased to prevent the switching element from being switched to the intermittent operation state. A current can thereby be supplied stably to the load on the high voltage side.SELECTED DRAWING: Figure 2

Description

According to the present invention, by switching the DC input voltage applied to the input coil on the primary side of the transformer, the output coil provided on the secondary side of the transformer has the first output voltage and is higher than the first output voltage. The present invention relates to a switching power supply device that generates a second output voltage of a voltage and a combustion device equipped with the switching power supply device.

Today's electrical equipment is controlled by computers, etc., and along with this, in addition to the high voltage for driving actuators such as motors, low voltage for driving computers, etc. is also used within one electrical equipment. It is common to be done. For example, in a combustion device that burns fuel gas, a fan motor that rotates a combustion fan that supplies combustion air for burning the fuel gas, a blower fan for blowing warm air, etc. is driven by a high voltage. However, various solenoid valves that control the amount of fuel gas supplied and control units that control the operation of these solenoid valves are driven by a low voltage. Therefore, today's electrical equipment is equipped with a switching power supply device capable of efficiently generating a voltage having a different voltage value from a single power supply (for example, a commercial power supply).

The switching power supply device inputs by applying a DC input voltage to the coil on the primary side of the transformer (hereinafter referred to as the input coil) and performing a switching operation to turn on / off the switch element connected in series with the input coil. It efficiently converts the voltage into an output voltage with a ratio corresponding to the winding ratio of the transformer. In a switching power supply device, a plurality of coils on the secondary side of a transformer (hereinafter referred to as output coils) are provided, and by making the number of turns of these output coils different, it is possible to easily generate a plurality of output voltages having different voltage values. It will be possible.

Further, if the duty ratio in which the switch element is turned on is increased or decreased, the current flowing through the input coil is increased or decreased, and as a result, the current supplied from the output coil on the secondary side can be increased or decreased. Therefore, if the duty ratio of the switch element is controlled according to the increase or decrease of the current consumed by the electric load connected to the output coil on the secondary side, the current supplied from the output coil on the secondary side can be increased or decreased. it can. However, when multiple output voltages with different voltage values are generated, the currents at the multiple output voltages increase or decrease all at once, so the current consumed by any one output voltage is actually used. The duty ratio will be controlled according to the increase or decrease. Further, as described above, in the switching power supply installed in an electric device, an output voltage having a low voltage value is used to drive a computer or the like, and the operation is not possible unless the necessary current can be supplied to the computer or the like. There is a risk of becoming stable. Therefore, it is usual to control the duty ratio of the switch element according to the required current at an output voltage having a low voltage value.

Further, since a computer or the like consumes almost no current while it is not operating, it is not possible to reduce the amount of current generated by the output coil to the required amount of current simply by reducing the duty ratio. Therefore, the amount of current supplied to a computer or the like is further reduced by switching between a state in which the switch element is driven with a predetermined small duty ratio and a state in which the switch element is suspended in a predetermined cycle to an intermittent operation. A technique that makes this possible has also been proposed (Patent Document 1).

JP-A-2002-252973

However, in the proposed conventional switching power supply device, there is a problem that the operation of an actuator or the like driven by an output voltage having a high voltage value may become unstable. That is, even if the computer mounted on the electric device is not operating, the actuator of the electric device may be operating. In such a case, when the switching power supply is switched to the intermittent operation, the voltage value is changed. This is because it becomes impossible to stably supply the current with a high output voltage to the actuator. In particular, in a combustion device that burns fuel gas, a purge operation that rotates a combustion fan or a blower fan may be performed while the supply of fuel gas is stopped, and in the purge operation, the switching power supply device is likely to switch to an intermittent operation. It has become. For this reason, it becomes difficult to stably rotate the combustion fan or the blower fan, and a situation may occur in which sufficient purging operation cannot be performed.

The present invention has been made to solve the above-mentioned problems of conventional switching power supply devices and combustion devices, and the voltage value can be increased even when the current consumed by the output voltage having a low voltage value is reduced. It is an object of the present invention to provide a switching power supply device and a combustion device capable of stably driving an actuator driven by a high output voltage.

In order to solve the above-mentioned problems, the switching power supply device of the present invention adopts the following configuration. That is,
By switching the DC input voltage applied to the input coil on the primary side of the transformer, a DC first output voltage and a DC second output voltage having a voltage value higher than the first output voltage are generated. In a switching power supply
An input voltage application unit that applies the input voltage to the input coil,
A switch element that is connected in series to the input coil and switches between an ON state in which the input voltage is applied to the input coil and an OFF state in which the input voltage is cut off.
A galvanometer resistor connected to the downstream side of the switch element,
A first output voltage generator that is connected to a first output coil provided on the secondary side of the transformer and generates the first output voltage,
A second output voltage generator that is connected to a second output coil provided on the secondary side of the transformer and generates the second output voltage.
A current consumption detection unit that detects the current consumption of the first load connected to the first output voltage generation unit, and a current consumption detection unit.
The switch element is driven so that the duty ratio in the ON state becomes smaller as the current consumption in the first load becomes smaller, and the switch element is obtained based on the voltage value detected at the upstream end of the galvanizing resistor. A switch element drive unit that controls the duty ratio so that the current value of the input coil becomes a current value corresponding to the current consumption of the first load.
When the current consumption in the first load becomes equal to or less than a predetermined threshold value, the operating state of the switch element driving unit is changed to the state of driving the switch element at the duty ratio and the driving of the switch element is suspended. An intermittent operation switching unit that switches to an intermittent operation state that repeats the state of
When the second load connected to the second output voltage generation unit consumes current, the operation of the switch element drive unit is performed even if the current consumption amount in the first load is equal to or less than a predetermined threshold value. A continuous operation holding unit for holding the state in a continuous operation state for driving the switch element at the duty ratio is provided.
By increasing the voltage value at the upstream end of the flow detection resistor, the continuous operation holding unit causes the intermittent operation switching unit to erroneously recognize that the current consumption amount in the first load is larger than the threshold value. , It is characterized in that it is held in the continuous operation state.

In the switching power supply device of the present invention, when the ON / OFF state of the switch element is switched, the state in which a current flows through the input coil on the primary side of the transformer and the state in which a current does not flow are switched, and accordingly, the first A DC first output voltage is generated from the first output voltage generation unit connected to the one output coil and supplied to the first load. Further, a second output voltage having a voltage value higher than that of the first output voltage is generated from the second output voltage generating unit connected to the second output coil and supplied to the second load. The amount of current flowing through the input coil is controlled as follows. First, the current consumption in the first load is detected, and the switch element is turned on at a duty ratio corresponding to the current consumption. Further, the voltage value at the upstream end of the galvanizing resistor connected to the downstream side of the switch element (in series with the input coil) is detected, and the current value of the input coil obtained based on the voltage value is determined. The duty ratio at which the switch element is turned on is controlled so that the current value corresponds to the current consumption of the first load. In addition, when the current consumption in the first load becomes equal to or less than a predetermined threshold value, the operating state of the switch element is switched to the intermittent operating state. However, when the current is consumed by the second load, the voltage value at the upstream end of the flow detection resistor is increased so as not to switch to the intermittent operation state.

When the state is switched to the intermittent operation state, the state in which the current can be supplied to the second load and the state in which the current cannot be supplied are repeated, so that the second load cannot be driven stably. However, in the switching power supply device of the present invention described above, even if the current consumption in the first load is reduced, it can be prevented from switching to the intermittent operation state, so that it is stable with respect to the second load. It becomes possible to supply an electric current.

Further, in the switching power supply device of the present invention described above, the voltage value at the upstream end of the flow detection resistor may be increased as follows. First, the switch element is switched to the ON state or the OFF state by supplying a control signal to the switch element. Then, even if the control signal and the upstream end of the flow detection resistor are connected by a connection resistor and the resistance value of this connection resistor is lowered, the voltage value at the upstream end of the flow detection resistor is increased. Good.

In this way, for example, using a switch element, another resistor is connected in parallel to the connection resistor, or another resistor connected in series to the connection resistor is connected using the switch element. By a method such as bypassing, the resistance value of the combined resistance including the connection resistance can be easily lowered, and the voltage value at the upstream end of the detection resistance can be easily increased.

Further, the present invention can also be grasped in the mode of a combustion device that blows out combustion products from an exhaust outlet by burning fuel gas with a burner while rotating a combustion fan inside the housing. That is, the combustion device of the present invention
A burner that burns fuel gas inside the housing, a combustion fan that sucks air into the housing and supplies it to the burner, and blows out combustion exhaust from the exhaust outlet of the housing, and a fan motor that rotates the combustion fan. In a combustion device equipped with a control unit that controls the operation of the burner and the fan motor, and the switching power supply device according to claim 1 or 2.
The first load includes at least the control unit.
The second load includes at least the fan motor.
When the continuous operation holding unit receives information from the control unit that the burner does not burn the fuel gas but rotates the combustion fan, the continuous operation holding unit holds the operating state of the switch element driving unit in the continuous operating state. It is characterized by that.

In the combustion device, although the burner does not burn the fuel gas, it may be in a purge state in which the fan motor is rotated. In the purge state, the current consumption is small in the first load such as the control unit. , A second load such as a fan motor consumes current. Therefore, if the switch element is switched to the intermittent operation state in the purge state, the current cannot be stably supplied to the fan motor, and there is a possibility that the inside of the housing cannot be sufficiently ventilated even in the purge state. However, in the combustion apparatus of the present invention described above, since it is possible to prevent the fan motor from switching to the intermittent operation state in the purge state, a stable current can be supplied to the fan motor, and the inside of the housing can be supplied during the purge state. Can be sufficiently ventilated.

It is a block diagram which showed the rough structure of the combustion apparatus 10 which mounted the switching power supply apparatus 100 of this Example. It is explanatory drawing which showed the internal structure of the switching power supply device 100 of this Example. As the control signal switches between the Hi state and the Low state, the ON / OFF state of the switch element SW1 and the voltage value (input value of the IS terminal) at the upstream end of the flow detection resistor R1 change. It is explanatory drawing shown. It is a block diagram which showed the internal structure of the controller 105 which generates the control signal based on the input value of the FB terminal and the IS terminal. It is explanatory drawing which showed how the controller 105 generates a control signal of a switch element SW1 by taking a logical product of a drive signal and a switching signal. It is explanatory drawing which showed how the duty ratio of a voltage IS and a control signal changes by turning on a switch element SW2. It is explanatory drawing which showed the operation of the combustion apparatus 10 equipped with the switching power supply apparatus 100 of this Example. It is explanatory drawing which showed the internal structure of the switching power supply device 150 of a modification.

FIG. 1 is an explanatory diagram showing a rough structure of a combustion device 10 equipped with a switching power supply device 100 of this embodiment. As shown in the figure, the combustion device 10 is a so-called hot air heating device having a structure in which a burner 12 for burning fuel gas, a combustion fan 13, and the like are housed in a housing 11. A gas pipe 14 for supplying fuel gas is connected to the burner 12, and the gas pipe 14 has a main valve 15 that opens and closes with an electromagnetic valve and a flow control valve whose valve opening degree can be controlled by a stepping motor. 16 is provided. Further, a fan motor 17 is connected to the rotation shaft of the combustion fan 13, and the combustion fan 13 is rotated by driving the fan motor 17. Then, when the combustion fan 13 is rotated by the fan motor 17, air is sucked into the housing 11 from the air intake port 18 opened on the back side of the housing 11. When the main valve 15 is opened in that state, fuel gas is supplied to the burner 12 from the gas pipe 14. Then, when the fuel gas is ignited by a spark plug (not shown), the fuel gas is burned by the burner 12 to generate high-temperature combustion exhaust. This combustion exhaust is mixed with the air sucked from the air intake port 18 inside the housing 11, and then blown out as warm air from the exhaust outlet 19 provided on the front side of the housing 11. The black arrows shown in FIG. 1 represent the flow of combustion exhaust gas discharged from the burner 12, and the white arrows shown in FIG. 1 indicate the flow of air sucked from the air intake port 18. Represents. Further, the shaded arrows represent the warm air blown from the exhaust outlet 19.

The flow rate of the fuel gas supplied to the burner 12 is controlled by the flow rate control valve 16, and when the valve opening degree of the flow rate control valve 16 is increased, the flow rate of the fuel gas burned by the burner 12 increases. Further, the air used for burning the fuel gas is covered by the air sucked from the air intake port 18. Therefore, when the opening degree of the flow rate control valve 16 is opened, the rotation speed of the fan motor 17 is increased. By doing so, as a result of increasing the flow rate of the air sucked from the air intake port 18, the flow rate of the air supplied to the burner 12 also increases, and the fuel gas can be normally burned. The operations of the main valve 15, the flow rate control valve 16, the fan motor 17, and the like are mainly controlled by the control unit 20 formed by the CPU, LSI, and the like. Further, electric power for operating the main valve 15, the flow rate control valve 16, and the control unit 20 is supplied from the switching power supply device 100. Further, the electric power for operating the fan motor 17 is also supplied from the switching power supply device 100.

Here, since the fan motor 17 consumes a large amount of electric power, it operates at a high voltage, whereas the main valve 15, the flow control valve 16, and the control unit 20 are as large as the fan motor 17. Since it does not consume power, it operates at a low voltage. Therefore, the switching power supply device 100 converts a so-called commercial power supply AC voltage into a DC voltage having a low voltage value for operating the main valve 15, the flow control valve 16, the control unit 20, and the like, and a fan motor. A DC voltage having a high voltage value for operating the 17 is generated. In the following, the voltage for operating the main valve 15, the flow rate control valve 16, the control unit 20, etc. will be referred to as "first output voltage", and the voltage for operating the fan motor 17 will be referred to as "second output". We will call it "voltage". Further, the thick broken line arrow shown in FIG. 1 conceptually represents the state in which the first output voltage is supplied, and the thick solid line arrow shown in FIG. 1 conceptually indicates that the second output voltage is supplied. It is conceptually represented.

FIG. 2 is an explanatory diagram showing the internal structure of the switching power supply device 100 of this embodiment. The switching power supply device 100 of this embodiment includes a transformer 101 and an input voltage application unit 104 that applies a DC input voltage to the input coil 102 on the primary side of the transformer 101. Inside the input voltage application unit 104, a rectifier circuit formed by combining diodes and a capacitor are mounted, and after rectifying the AC voltage supplied from the commercial power supply, it is smoothed to input DC. Generate a voltage. A switch element SW1 by a FET (field effect transistor) is connected to the downstream side of the input coil 102, and a flow detection resistor R1 is connected to the downstream side of the switch element SW1.

Further, a first output coil 103a and a second output coil 103b are provided on the secondary side of the transformer 101. Therefore, when the switch element SW1 is connected (hereinafter, ON state) and disconnected (hereinafter, OFF state) is repeated in a predetermined cycle, a direct current flows through the input coil 102 and does not flow. The state is repeated, and as a result, an electromotive force due to electromagnetic induction is generated in the first output coil 103a and the second output coil 103b. At this time, the voltage generated in the first output coil 103a is a voltage value determined according to the input voltage applied to the input coil 102 and the winding ratio between the input coil 102 and the first output coil 103a. .. Similarly, the voltage generated in the second output coil 103b is a voltage value determined according to the input voltage applied to the input coil 102 and the winding ratio between the input coil 102 and the second output coil 103b. ..

Further, a first smoothing portion C1 mainly formed by a capacitor is connected to the first output coil 103a, and a second smoothing portion C2 mainly formed by a capacitor is connected to the second output coil 103b. Has been done. Therefore, the voltage generated by the first output coil 103a is smoothed by the first smoothing portion C1, so that the first output voltage is generated. Similarly, the voltage generated by the second output coil 103b is smoothed by the second smoothing portion C2 to generate a second output voltage. The first output voltage generated in this way is supplied to the main valve 15, the flow rate control valve 16, and the control unit 20, and the second output voltage is supplied to the fan motor 17.

As shown in FIG. 2, in this embodiment, two output coils 103 (that is, the first output coil 103a and the second output coil 103b) are provided on the secondary side of the transformer 101. This is because the switching power supply device 100 of the embodiment generates two output voltages having different voltage values. Therefore, for example, when generating three output voltages, three output coils 103 may be provided on the secondary side of the transformer 101. In this embodiment, the first smoothing portion C1 connected to the first output coil 103a corresponds to the "first output voltage generating unit" in the present invention, and the second smoothing portion C2 connected to the second output coil 103b. However, it corresponds to the "second output voltage generation unit" in the present invention. Further, in the present embodiment, the main valve 15, the flow rate control valve 16, the control unit 20, and the like to which the first output voltage is supplied correspond to the “first load” in the present invention, and the second output voltage is supplied. The fan motor 17 corresponds to the "second load" in the present invention.

Further, a photocoupler PC is connected between the terminals for outputting the first output voltage (that is, in a state parallel to the first smoothing portion C1). The photocoupler PC is formed by combining a light emitting diode and a light receiving element, and when a voltage is applied to the light emitting diode, the light receiving element receives the light emitted by the light emitting diode, and the resistance value of the light receiving element decreases. It has become like. Therefore, if the resistance value of the light receiving element is lowered, it can be determined that the voltage is applied to the light emitting diode. Further, the amount of light generated by the light emitting diode decreases as the applied voltage decreases. Therefore, when the voltage decreases, the amount of light received by the light receiving element decreases, and the amount of decrease in the resistance value of the light receiving element decreases (therefore, the resistance value of the light receiving element increases). From this, it is possible to detect the amount of decrease in the voltage applied to the light emitting diode based on the resistance value of the light receiving element. The photocoupler PC of this embodiment is connected so that a first output voltage is applied to both ends of the light emitting diode, and when the first output voltage decreases, the resistance value of the light receiving element increases, and as a result, the photocoupler PC Is connected so that the voltage value output by is increased. The output of the photocoupler PC thus obtained is input to the FB terminal of the controller 105.

The controller 105 is mainly formed of an LSI, and switches an ON state or an OFF state of the switch element SW1 by outputting a control signal to the switch element SW1. That is, the control signal is a pulse waveform signal that periodically repeats the Hi state (high voltage value state) and the Low state (low voltage value state), and when the control signal is in the Hi state, the switch element SW1 Is in the ON state, and when the control signal is in the Low state, the switch element SW1 is in the OFF state. The ratio of the time during which the Hi state is in the control signal that periodically repeats the Hi state and the Low state is called the duty ratio.

Further, the controller 105 includes an IS terminal connected to the upstream end of the flow detection resistor R1 in addition to the FB terminal connected to the photocoupler PC. As will be described later, the input value from the FB terminal is a value corresponding to the current consumption of the first load (here, the main valve 15, the flow rate control valve 16, the control unit 20, etc.) connected to the first output voltage. The input value from the IS terminal is a value corresponding to the amount of current flowing through the input coil 102 of the transformer 101. The controller 105 outputs to the switch element SW1 so that the input value of the switch element SW1 corresponding to the current amount of the input coil 102 becomes a value corresponding to the current consumption of the first load obtained from the input value of the FB terminal. The duty ratio of the control signal is controlled. This point will be described in detail later.

Further, in the switching power supply device 100 of this embodiment, the upstream end of the flow detection resistor R1 and the control signal output to the switch element SW1 are connected by the connection resistor R2 (see FIG. 2). Then, the bypass resistor R3 and the switch element SW2 are connected in parallel to the connection resistor R2. The switch element SW2 is also formed by an FET, and the switch element SW2 is switched to either an ON state or an OFF state depending on a signal output from the control unit 20.

Here, an operation in which the controller 105 of the switching power supply device 100 controls the duty ratio of the control signal output to the switch element SW1 based on the input values of the FB terminal and the IS terminal will be described. First, it is assumed that the controller 105 outputs a control signal of a certain duty ratio to the switch element SW1. As described above, when the control signal is in the Hi state, the switch element SW1 is in the ON state and a current flows through the input coil 102, and when the control signal is in the Low state, the switch element SW1 is in the OFF state and the input coil 102. No current flows through. As a result of repeating this in a predetermined cycle, an electromotive force is generated in the first output coil 103a and the second output coil 103b, a DC first output voltage is generated in the first smoothing section C1, and the second smoothing section C2 is generated. Then, a DC second output voltage is generated. Further, at this time, the amount of current generated by each of the first smoothing portion C1 and the second smoothing portion C2 is determined by the amount of current flowing through the input coil 102.

However, if the amount of current consumed by the first load (that is, the main valve 15, the flow rate control valve 16, the control unit 20, etc.) increases and exceeds the amount of current generated by the first smoothing unit C1, the first load is increased. 1 The output voltage cannot be maintained and the voltage value drops. Then, as a result of the light emitting amount of the light emitting element in the photocoupler PC decreasing, the resistance value of the light receiving element increases, and the input value of the FB terminal output from the photocoupler PC increases. When the input value of the FB terminal increases, the controller 105 determines that the amount of current consumed by the first load has increased, and increases the duty ratio of the control signal. As a result, the amount of current flowing through the input coil 102 of the transformer 101 increases, and a larger amount of current can be supplied from the first smoothing portion C1. As described above, the photocoupler PC has a function of detecting the current consumption in the first load (that is, the main valve 15, the flow rate control valve 16, the control unit 20, etc.). Therefore, the photocoupler PC of this embodiment corresponds to the "current consumption detection unit" in the present invention.

Further, the input value of the IS terminal, which is the voltage value at the upstream end of the flow detection resistor R1, is a value corresponding to the amount of current flowing through the input coil 102. This point will be described with reference to FIG. In FIG. 3, the ON / OFF state of the switch element SW1 is switched as the control signal is switched between the Hi state and the Low state, and the voltage value (IS) at the upstream end of the flow detection resistor R1 is accompanied by this. It is explanatory drawing which showed how the input value of a terminal (hereinafter referred to as voltage IS at an end) changes. As described above, since the switch element SW1 is in the OFF state while the control signal is in the Low state, the input voltage from the input voltage application unit 104 is not applied to the flow detection resistor R1, and the flow is detected. The value of the voltage IS at the upstream end of the resistor R1 is 0V.

After that, when the control signal is in the Hi state, the switch element SW1 is turned on, and the input voltage from the input voltage application unit 104 is applied to the input coil 102. However, the current flowing through the input coil 102 slowly increases due to the inductance of the input coil 102. Therefore, the current flowing through the flow detection resistor R1 also slowly increases, and the voltage IS at the upstream end of the flow detection resistor R1 also slowly increases. Further, as described above with reference to FIG. 2, the upstream end of the galvanometer resistor R1 is connected to the control signal by the connection resistor R2. The bypass resistor R3 and the switch element SW2 are connected in parallel to the connection resistor R2, but since the switch element SW2 is normally in the OFF state, the bypass resistor R3 is actually connected. It is in a state equivalent to not. Therefore, when the control signal is switched to the Hi state, the value of the voltage IS is raised by the voltage corresponding to the Hi state of the control signal. The voltage value at this time is a value obtained by dividing the voltage value corresponding to the Hi state of the control signal by the connection resistor R2 and the flow detection resistor R1. After that, the voltage value slowly increases as the current flowing through the input coil 102 increases. Then, when the control signal is switched to the Low state while the voltage IS is increasing, the switch element SW1 is turned OFF, and as a result, the upstream end of the flow detection resistor R1 comes from the input voltage application unit 104 and the input coil 102. As a result of being disconnected, the value of the voltage IS becomes 0V again.

As described above, the voltage IS at the upstream end of the flow detection resistor R1 changes with the waveform shown by the solid line in FIG. 3 in accordance with the movement of the control signal switching to the Hi state or the Low state. Further, as shown by the broken line in the figure, when the time that the control signal is in the Hi state becomes long (that is, when the duty ratio of the control signal increases), the current flowing through the input coil 102 increases, and the voltage IS increases. The value also increases. As described above, the value of the voltage IS is a value corresponding to the amount of current flowing through the input coil 102.

Therefore, when the controller 105 outputs a control signal having a duty ratio according to the input value from the FB terminal to the switch element SW1, the amount of current flowing through the input coil 102 based on the input value from the IS terminal is increased from the FB terminal. Judge whether the amount of current corresponds to the input value. Then, when it is determined that the input value of the IS terminal is smaller than the input value from the FB terminal and therefore the amount of current of the input coil 102 is small, the duty ratio of the control signal is increased, and conversely, the duty ratio from the FB terminal is increased. When it is determined that the input value of the IS terminal is larger than the input value and therefore the amount of current of the input coil 102 is large, the duty ratio of the control signal is reduced. Furthermore, the controller 105 of this embodiment is also equipped with a function of intermittently operating the switch element SW1 by intermittently outputting a control signal when the input value of the FB terminal is particularly small.

FIG. 4 is a block diagram showing the internal structure of the controller 105 of this embodiment. As shown in the figure, a drive signal generation unit 105a for generating a drive signal described later, a switching signal generation unit 105b for generating a switching signal described later, and an AND circuit 105c are mounted inside the controller 105. .. The control signal output to the switch element SW1 is generated by taking the logical product of the drive signal output by the drive signal generation unit 105a and the switching signal output by the switching signal generation unit 105b. Further, the input value of the FB terminal and the input value of the IS terminal are input to the drive signal generation unit 105a, and the input value of the FB terminal is input to the switching signal generation unit 105b.

FIG. 5 is an explanatory diagram showing how the controller 105 generates a control signal for the switch element SW1 by taking a logical product of the drive signal and the switching signal. For convenience of explanation, first, the switching signal generated by the switching signal generation unit 105b will be described. The switching signal generation unit 105b is in the Hi state when the input value of the FB terminal is equal to or higher than a predetermined threshold value, but when the input value of the FB terminal becomes lower than the threshold value, the Hi state and the Low state are repeated in a predetermined cycle. Generates a switching signal. In the example shown in FIG. 5, it is assumed that the input value of the FB terminal decreases with the passage of time taken on the horizontal axis. Therefore, the switching signal remains in the Hi state at the beginning. After the input value of the FB terminal reaches the threshold value at a certain point, the signal is such that the Hi state and the Low state are switched at a predetermined cycle.

Further, the control signal is a signal obtained by taking the logical product of such a switching signal and a driving signal. Therefore, while the input value of the FB terminal is larger than the threshold value, the control signal is a signal in which the drive signal is output as it is. That is, the drive signal generation unit 105a generates a drive signal whose duty ratio decreases as the input value of the FB terminal decreases (as described above with reference to FIG. 3), and the drive signal generation unit 105a generates a drive signal according to the input value of the IS terminal. The duty ratio of the drive signal is corrected. The upper part of FIG. 5 shows how a drive signal is generated in which the duty ratio becomes smaller as the input value of the FB terminal decreases. Then, when the input value of the FB terminal becomes equal to or less than the threshold value, the switching signal is switched to a signal that repeats the Hi state and the Low state in a predetermined cycle. As a result, as shown in the lower part of FIG. 5, the control signal is output as it is while the switching signal is in the Hi state, but when the switching signal is in the Low state, the control signal is also fixed in the Low state. It becomes a signal like.

Therefore, in the switching power supply device 100, while the switching signal is in the Hi state, a current flows through the input coil 102 according to the duty ratio at that time to generate the first output voltage and the second output voltage, but the switching signal is generated. In the Low state, no current flows through the input coil 102, and the generation of the first output voltage and the second output voltage is suspended, which is repeated in a predetermined cycle. In the following, such an operating state of the switching power supply device 100 will be referred to as an "intermittent operating state". On the other hand, an operating state in which the first output voltage and the second output voltage are continuously generated without being interrupted is referred to as a "continuous operating state". Further, the drive signal generation unit 105a of the present embodiment that generates a drive signal corresponds to the "switch element drive unit" in the present invention, and the switching signal generation unit 105b of the present embodiment that generates a switching signal corresponds to the "switch element drive unit" in the present invention. Corresponds to "intermittent operation switching unit".

When the input value of the FB terminal is small (that is, when the power consumption in the first load is small), even if the switching power supply device 100 is in the intermittent operation state and the generation of the first output voltage is stopped, the first output voltage is generated. A current can be supplied by using the electric charge stored in the smoothing portion C1. Further, if the generation of the first output voltage is restarted before the electric charge stored in the first smoothing portion C1 is exhausted, the electric charge can be stored in the first smoothing portion C1 again. By doing so, it is not necessary to wastefully generate the current, so that the power consumed by the transformer 101 can be suppressed.

However, when the switching power supply device 100 is in the intermittent operation state, the second output voltage is generated only intermittently even in the second smoothing portion C2. Therefore, when an attempt is made to supply a current to the second load (here, the fan motor 17) connected to the second smoothing portion C2, the voltage cannot be maintained and the operation of the second load becomes unstable. Therefore, in the switching power supply device 100 of this embodiment, as described above with reference to FIG. 2, a connection resistor R2 is connected to the upstream end of the flow detection resistor R1, and the connection resistor R2 is connected in parallel with the connection resistor R2. The bypass resistor R3 and the switch element SW2 are connected. The reason for this will be described below.

FIG. 6 is an explanatory diagram showing how the value of the voltage IS and the duty ratio of the control signal change when the switch element SW2 is turned on. In the normal state, the switch element SW2 is in the OFF state. In this state, the value of the voltage IS is the voltage waveform shown by the solid line in FIG. 6 (a) (that is, once the control signal is in the Hi state, it rises once and then time, according to the mechanism described above with reference to FIG. It becomes a voltage waveform that increases with the passage of time and repeatedly decreases to 0V when the control signal is in the Low state). The voltage value that rises once when the control signal enters the Hi state is a voltage value obtained by dividing the voltage value corresponding to the Hi state of the control signal by the connection resistor R2 and the flow detection resistor R1.

However, when the switch element SW2 is turned on, the bypass resistor R3 is connected in parallel with the connection resistor R2, and the resistance value of the combined resistance of the connection resistor R2 and the bypass resistor R3 is higher than the resistance value of the connection resistor R2. Also becomes smaller. Therefore, as shown by the broken line in FIG. 6A, the voltage value that temporarily rises when the control signal is in the Hi state is higher than that when the switch element SW2 is in the OFF state. After that, the value of the voltage IS will increase with the passage of time from the high voltage value.

Further, since the controller 105 detects the amount of current of the input coil 102 based on the input value of the IS terminal (that is, the value of the voltage IS), when the voltage IS becomes high as shown by the broken line in FIG. 6A. , It is erroneously determined that the amount of current of the input coil 102 has increased. As a result, as shown in FIG. 6B, the duty ratio of the control signal is reduced. Of course, the value of the voltage IS became high because the switch element SW2 was turned on, and the current amount of the input coil 102 did not increase. From that state (that is, the state in which the amount of current is not actually increased), the amount of current of the first output voltage generated by the first smoothing portion C1 as a result of the controller 105 reducing the duty ratio of the control signal. Decreases, making it impossible to maintain the first output voltage. Therefore, the amount of light emitted from the light emitting diode in the photocoupler PC (see FIG. 2) decreases, the resistance value of the light receiving element increases, and the input value of the FB terminal output from the photocoupler PC increases. Of course, the real cause of the increase in the input value of the FB terminal is that the controller 105 reduces the duty ratio of the control signal, but the controller 105 determines that the amount of current in the input coil 102 is excessive and the duty of the control signal. The ratio is decreasing. Therefore, it is erroneously determined that the reason why the input value of the FB terminal has increased is that the current consumption in the first load (here, the main valve 15, the flow rate control valve 16, the control unit 20, etc.) has increased. Become. If the input value of the FB terminal is equal to or higher than a predetermined threshold value, the switching signal is set to the Hi state, and as a result, the switching power supply device 100 operates in the continuous operation state.

From this, when the control unit 20 of the combustion device 10 operates the fan motor 17, if the switch element SW2 is turned on, the current in the main valve 15, the flow rate control valve 16, the control unit 20, etc. Even if the consumption is small, the switching power supply device 100 can be operated in a continuous operation state. As a result, it is possible to avoid a situation in which the operation of the fan motor 17 becomes unstable. As is clear from the above description, the switch element SW2 is turned on when the second load (here, the fan motor 17) consumes current, so that the switching power supply device 100 maintains a continuous operation state. Has the function of Therefore, the switch element SW2 of this embodiment corresponds to the "continuous operation holding unit" in the present invention.

FIG. 7 is an explanatory diagram showing the operation of the combustion device 10 equipped with the switching power supply device 100 of the present embodiment described above. During the combustion operation of the combustion device 10, warm air is blown out from the exhaust outlet 19 by burning the fuel gas with the burner 12 while rotating the combustion fan 13 and sucking air into the housing 11. The flow rate of the fuel gas to be burned by the burner 12 is calculated by the control unit 20 based on the set temperature set by the user of the combustion device 10 and the room temperature detected by a temperature sensor (not shown), and is adjusted to the flow rate. It controls the valve opening degree of the flow rate control valve 16 and the rotation speed of the fan motor 17. Therefore, during the combustion operation, the current consumption of the control unit 20, the main valve 15, and the flow rate control valve 16 and the current consumption of the fan motor 17 are all large.

On the other hand, before and after the combustion operation, there is an operation state called a purge in which the combustion fan 13 is rotated while the fuel gas is not burned. The purge performed immediately before the combustion operation is called "pre-purge", and the purge performed immediately after the combustion operation is called "post-purge". In these purged states, since the fuel gas is not burned, the main valve 15 remains closed, it is not necessary to control the flow rate of the fuel gas with the flow rate control valve 16, and the control unit 20 calculates the flow rate of the fuel gas. You don't even have to. Further, although the fan motor 17 is rotating, it is not necessary to control the rotation speed. Therefore, the current consumption of the main valve 15, the flow rate control valve 16, the control unit 20, etc. in the purge state is about the same as the current consumption in the standby state of the combustion device 10. Nevertheless, the fan motor 17 consumes a certain amount of current. Therefore, the combustion device 10 of this embodiment turns on the switch element SW2 by a signal from the control unit 20 during purging. By doing so, as shown in FIG. 7, since the switching power supply device 100 can be operated in the continuous operation state during the purging as in the combustion operation, the fan motor 17 can be operated stably. , It is possible to reliably perform the purge operation.

In the switching power supply device 100 of the present embodiment described above, it has been described that the directly connected bypass resistor R3 and the switch element SW2 are connected in parallel with the connection resistor R2. However, if the value of the voltage IS can be increased by switching the ON / OFF state of the switch element SW2, another circuit configuration can be used. For example, in the switching power supply device 150 of the modified example illustrated in FIG. 8, the connection resistor R2 and the bypass resistor R3 are connected in series, and one end side of the resistor connected in series is connected to the upstream end of the galvanometer resistor R1. And the other end is connected to the control signal. Then, the switch element SW2 is connected in parallel with the bypass resistor R3.

In this way, the value of the voltage IS when the control signal is in the Hi state is the voltage corresponding to the Hi state of the control signal when the switch element SW2 is in the OFF state, and the connection resistor R2 and the bypass resistor R3 are connected in series. The voltage value is divided by the combined resistance connected to and the flow detection resistor R1. On the other hand, when the switch element SW2 is turned on, the bypass resistor R3 is bypassed, so that the voltage value is divided by the connection resistor R2 and the flow detection resistor R1. When the switch element SW2 is in the OFF state, the connection resistor R2 and the bypass resistor R3 are connected in series, and when the switch element SW2 is in the ON state, the connection resistor R2 is in a single state, so that the resistance value decreases. , The value of voltage IS increases. Therefore, the switching power supply device 150 of the modified example shown in FIG. 8 can be operated in the same manner as the switching power supply device 100 of the present embodiment.

The switching power supply device 100 of the present embodiment and the switching power supply device 150 of the modified example have been described above, but the present invention is not limited to the above-described embodiment and the modified example, and various types are described without departing from the gist thereof. It can be carried out in an embodiment. For example, in the above-described embodiment, the combustion device 10 has been described as a so-called hot air heating device. However, the combustion device 10 is not limited to this, and may be a hot water supply device provided with a combustion fan or the like.

10 ... Combustion device, 12 ... Burner, 13 ... Combustion fan,
15 ... main valve, 16 ... flow control valve, 17 ... fan motor,
20 ... Control unit, 100 ... Switching power supply, 101 ... Transformer,
102 ... Input coil, 103a ... First output coil,
103b ... Second output coil, 104 ... Input voltage application unit,
105 ... controller, 105a ... drive signal generator (switch element drive unit),
105b ... Switching signal generation unit (intermittent operation switching unit),
150 ... Switching power supply device, C1 ... First smoothing unit (first output voltage generating unit),
C2 ... 2nd smoothing part (2nd output voltage generating part), R1 ... Flow detection resistor,
R2 ... connection resistance, R3 ... bypass resistance,
PC ... Photocoupler (current consumption detector), SW1 ... Switch element,
SW2 ... Switch element (continuous operation holding unit).

Claims (3)

By switching the DC input voltage applied to the input coil on the primary side of the transformer, a DC first output voltage and a DC second output voltage having a voltage value higher than the first output voltage are generated. In a switching power supply
An input voltage application unit that applies the input voltage to the input coil,
A switch element that is connected in series to the input coil and switches between an ON state in which the input voltage is applied to the input coil and an OFF state in which the input voltage is cut off.
A galvanometer resistor connected to the downstream side of the switch element,
A first output voltage generator that is connected to a first output coil provided on the secondary side of the transformer and generates the first output voltage,
A second output voltage generator that is connected to a second output coil provided on the secondary side of the transformer and generates the second output voltage.
A current consumption detection unit that detects the current consumption of the first load connected to the first output voltage generation unit, and a current consumption detection unit.
The switch element is driven so that the duty ratio in the ON state becomes smaller as the current consumption in the first load becomes smaller, and the switch element is obtained based on the voltage value detected at the upstream end of the galvanizing resistor. A switch element drive unit that controls the duty ratio so that the current value of the input coil becomes a current value corresponding to the current consumption of the first load.
When the current consumption in the first load becomes equal to or less than a predetermined threshold value, the operating state of the switch element driving unit is changed to the state of driving the switch element at the duty ratio and the driving of the switch element is suspended. An intermittent operation switching unit that switches to an intermittent operation state that repeats the state of
When the second load connected to the second output voltage generation unit consumes current, the operation of the switch element drive unit even if the current consumption amount in the first load is equal to or less than a predetermined threshold value. A continuous operation holding unit for holding the state in a continuous operation state for driving the switch element at the duty ratio is provided.
By increasing the voltage value at the upstream end of the flow detection resistor, the continuous operation holding unit causes the intermittent operation switching unit to erroneously recognize that the current consumption amount in the first load is larger than the threshold value. , A switching power supply device characterized by holding the continuous operating state. In the switching power supply device according to claim 1,
A connection resistor for connecting a control signal output from the switch element drive unit to the switch element and an upstream end of the galvanometer resistor is provided.
The continuous operation holding unit is a switching power supply device characterized in that the voltage value at the upstream end of the permeation resistor is increased by lowering the resistance value of the connection resistor. A burner that burns fuel gas inside the housing, a combustion fan that sucks air into the housing and supplies it to the burner, and blows out combustion exhaust from the exhaust outlet of the housing, and a fan motor that rotates the combustion fan. In a combustion device equipped with a control unit that controls the operation of the burner and the fan motor, and the switching power supply device according to claim 1 or 2.
The first load includes at least the control unit.
The second load includes at least the fan motor.
When the continuous operation holding unit receives information from the control unit that the burner does not burn the fuel gas but rotates the combustion fan, the continuous operation holding unit holds the operating state of the switch element driving unit in the continuous operating state. A combustion device characterized by that.

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