JP2021076335A - Combustion device - Google Patents

Abstract

To provide a combustion device in which quietness has been improved.SOLUTION: A combustion device includes: a leveler tank which holds a fixed oil level by receiving a supply of a fuel from an external tank; a fuel pump for supplying the fuel of the leveler tank to a combustion part; an oil level sensor for detecting the oil level height of the leveler tank; a pumping-up pump for supplying the fuel from the external tank to the leveler tank by a reciprocating plunger; a control part for controlling the oil amount of the fuel pump according to the size of fire power of a heater, for detecting the oil surface height in the leveler tank by the oil level sensor, and for performing start or stop of drive of the pumping-up pump; and change means for changing the stroke width of the plunger. The control part controls the change means in such a manner that the smaller the fire power of the heater, the shorter the stroke width of the plunger.SELECTED DRAWING: Figure 2

Description

The present invention relates to a combustion device that burns a liquid fuel such as petroleum to supply hot water, heat, and the like.

Conventionally, a pump that can pump fuel liquids such as oil and kerosene stored in an external fuel tank to a leveler tank that temporarily stores them between the fuel tank and the combustion device and adjusts the liquid level. There is known an electromagnetic pump configured to vibrate the plunger installed in the cylinder in a sliding contact state in the axial direction due to the periodic change of the magnetic force and to discharge the fuel in the external fuel tank toward the combustion part. ing.

Such an electromagnetic pump has a method of driving a commercial alternating current of 50 Hz or 60 Hz by a half-wave rectified pulse, and the plunger reciprocates 50 or 60 times per second to generate pulsation in the fuel liquid. ..

In order to absorb the vibration caused by the pulsation, it is known that an accumulator is provided in the middle of the piping between the pump and the external fuel tank or in the middle of the piping between the fuel pump and the combustion part to prevent the noise caused by the vibration. (See, for example, Patent Document 1.)

Japanese Patent No. 3839700

In a combustor such as a forced air supply / exhaust type oil hot air blower that uses such a pump, the combustion noise and the operating noise of the blower fan are loud during high-heat operation, and the driving noise of the pump is drowned out by this. During low-heat operation, the combustion noise and the operating noise of the blower fan are also reduced, so that the driving noise of the pumping pump becomes more noticeable, which causes discomfort to the user.

Further, in the fuel pump pumping pump to the leveler tank as described above, when the fuel oil in the leveler tank decreases and the oil level decreases to a certain level, the pumping pump starts to drive, and when a predetermined time elapses, the pumping pump stops driving. Therefore, the pump repeatedly turns the drive on and off during the operation of the product.

Therefore, even at the on / off timing of the drive of the pump, there is a problem that the drive sound of the pump becomes conspicuous due to the noise caused by the vibration described above, which causes discomfort to the user.

The present invention has been studied to solve the above problems, and an object of the present invention is to improve the quietness of the entire product by making the driving noise when the combustion device is low in heat and when the pump is turned on and off inconspicuous. The purpose is to provide a combustion device.

In order to achieve the above object, in claim 1 of the present invention, a leveler tank that receives fuel from an external tank and keeps the oil level constant, a fuel pump that supplies the fuel oil of the leveler tank to the combustion unit, and the leveler tank. An oil level sensor that detects the height of the oil level inside, a pump that supplies fuel oil from the external tank to the leveler tank by a plunger that reciprocates with a predetermined stroke width, and the above according to the magnitude of the thermal power of the heater. A control unit that controls the amount of oil in the fuel pump, detects the height of the oil level in the leveler tank with the oil level sensor, and starts or stops the pumping pump, and the stroke of the plunger of the pumping pump. The control unit includes changing means for changing the width, and the control unit controls the changing means so that the stroke width of the plunger becomes shorter as the heating power of the heater becomes smaller.

Further, in claim 2, the control unit sets the stroke width of the plunger to the first stroke width when the thermal power is larger than the predetermined thermal power of the heater, and the first stroke when the thermal power is equal to or less than the predetermined thermal power. It is characterized by having a second stroke width shorter than the width.

Further, in claim 3, the leveler tank that receives the fuel oil from the external tank and keeps the oil level constant, the fuel pump that supplies the fuel oil of the leveler tank to the combustion portion, and the oil level height in the leveler tank are detected. An oil level sensor, a pump that supplies fuel oil from the external tank to the leveler tank by a plunger that reciprocates with a predetermined stroke width, and an oil amount of the fuel pump are controlled according to the magnitude of the thermal power of the heater. A control unit that detects the oil level height in the leveler tank with the oil level sensor to start or stop driving the pump, and a changing means for changing the stroke width of the plunger of the pump. The control unit provides the changing means so that when the pumping pump is started to be driven, the stroke width of the plunger is started from a stroke width shorter than the predetermined stroke width and then gradually changed to the predetermined stroke width. It is characterized by controlling.

Further, in claim 4, the control unit gradually changes the stroke width of the plunger from a predetermined stroke width to a stroke width shorter than a predetermined stroke width when the drive of the pumping pump is stopped, and then the pumping unit. It is characterized by stopping the pump.

Further, in claim 5, the changing means for changing the stroke width of the plunger is characterized in that the stroke width is changed according to any one of the drive frequency, the power supply voltage, and the on-time of the pump.

According to claim 1 of the present invention, the control unit controls the changing means so that the smaller the heating power of the heater, the shorter the stroke width of the plunger. While the operating noise of the blower fan is reduced, the driving noise of the pumping pump can be suppressed to be small, and the entire equipment can be made quieter when the heating power is small.

Further, according to claim 2 of the present invention, the control unit sets the stroke width of the plunger to the first stroke width in the case of a thermal power larger than the predetermined thermal power of the heater, and in the case of the predetermined thermal power or less. Since the second stroke width is shorter than the first stroke width, the driving sound of the pumping pump can be suppressed more when it is driven by the second stroke width than by the first stroke width. It is possible to reduce the noise of the entire appliance at a predetermined small heat.

Further, according to claim 3, the control unit starts the stroke width of the plunger from a stroke width shorter than a predetermined stroke width at the start of driving the pump, and then sets the stroke width to a predetermined stroke width. Since the change is gradually made, the driving can be started from a small driving sound when the driving of the pumping pump is started, and the driving sound at the starting of driving of the pumping pump which repeats on / off can be made inconspicuous.

Further, according to claim 4, the control unit gradually changes the stroke width of the plunger from a predetermined stroke width to a stroke width shorter than the predetermined stroke width when the pumping pump is stopped. After that, since the pump is stopped, the drive can be stopped after the drive noise is reduced, and the drive noise when the drive of the pump that is repeatedly turned on and off can be made inconspicuous.

Further, according to claim 5 of the present invention, the changing means for changing the stroke width of the plunger of the pumping pump changes the stroke width according to any one of the drive frequency, the power supply voltage, and the on-time of the pumping pump. By changing the drive frequency, power supply voltage, and on-time that control the pump, the stroke width of the plunger can be changed, and the drive noise of the pump can be suppressed to operate the product.

Schematic block diagram of the heater according to the first embodiment of the present invention Sectional view of pump pump in the same embodiment Explanatory drawing at maximum thermal power which shows the drive part of the pump of the same embodiment Explanatory drawing at the time of minimum thermal power which shows the drive part of the pump of the same embodiment Relationship diagram showing thermal power and stroke width in the same embodiment Relationship diagram showing thermal power and stroke width in the second embodiment of the present invention A time chart showing a stroke width at the start of driving of the pump according to the third embodiment of the present invention. A time chart showing the stroke width when the pump is stopped in the third embodiment of the present invention. A time chart showing a stroke width at the start of driving of the pump according to the fourth embodiment of the present invention. A time chart showing the stroke width when the pump is stopped in the fourth embodiment of the present invention.

[First Embodiment]
Hereinafter, the heater 1 according to the first embodiment of the combustion device of the present invention will be described with reference to the drawings.
Reference numeral 2 is a housing of the heater 1, 3 is a bottom plate of the housing 2, and 2 is a shallow container-shaped lower tray having a rising portion 3a on the peripheral edge, and 4 is an operation panel having a display portion 4a and an operation switch 4b. Is.

5 is a combustion unit that burns fuel oil such as kerosene, 6 is a fuel supply device that supplies fuel oil to the combustion unit 5, 7 is a combustion fan that supplies combustion air taken in from the outside to the combustion unit 5, and 8 is a combustion unit 5. An ignition device having a spark rod for blowing sparks for ignition, and 9 is a flame detection device having a frame rod for detecting the presence or absence of a flame in the combustion unit 5.

Reference numeral 10 denotes a combustion cylinder in which the burner head 5a on which the flame of the combustion unit 5 is formed faces and forms the combustion chamber 10a. A red hot cylinder, 12 is a heat exchanger formed on the upper part of the combustion cylinder 10 to exchange heat between combustion heat and indoor air, and 13 is an exhaust cylinder for discharging the combustion exhaust gas after heat dissipation to the outside by the heat exchanger 12. Reference numeral 14 denotes a blower fan that blows indoor air to the heat exchanger 12.

Next, the fuel supply device 6 will be described.
The fuel supply device 6 detects the level of the fuel oil in the leveler tank 15, the leveler tank 15 for storing the fuel oil supplied to the combustion unit 5, the fuel pump 16 for supplying the fuel oil of the leveler tank 15 to the combustion unit 5, and the fuel oil level in the leveler tank 15. It includes an oil level sensor 17 and a pump 18 that supplies fuel oil pumped from an outdoor external tank (not shown) to a predetermined height when the oil level in the leveler tank 15 drops below a predetermined height.

The leveler tank 15 is arranged on the lower tray 3, and the upper surface of the leveler tank 15 is closed with a tank lid, and the fuel pump 16 and the oil level sensor 17 are attached to the tank lid. In the fuel pump 16, a suction end 16a is provided in the leveler tank 15, and fuel oil in the leveler tank 15 is supplied to the combustion unit 5 via the fuel pipe 19 in an amount corresponding to the amount of combustion.

The oil level sensor 17 is provided with a float 17b having a magnet that can move up and down on the support column 17a, and has a low oil level reed switch 17c for detecting a predetermined low oil level in the support column 17a and a predetermined oil level reed switch 17c. A high oil level reed switch 17d for detecting a high oil level is provided. Here, the predetermined low oil level is the lower limit oil level of the constant oil level maintained by the leveler tank 15, and the predetermined high oil level is the oil level higher than the upper limit oil level of the constant oil level maintained by the leveler tank 15.

The end of the pump 18 on the discharge side is connected to the leveler tank 15 via the supply pipe 20, and the end on the suction side is connected to the oil supply pipe 21 for supplying fuel oil from an external tank installed outdoors. By operating, fuel oil is supplied from the external tank into the leveler tank 15, and by stopping, the fuel oil from the external tank is closed so as not to be supplied into the leveler tank 15. Further, since the pump 18 is used as a mechanism for supplying fuel to the leveler tank 15, the limitation of the height difference between the external tank and the leveler tank 15 (the limitation of the installation height of the external tank) can be significantly relaxed.

Next, the pump 18 will be described with reference to FIG.
The pump 18 is provided on a cylindrical cylinder 22, a plunger 23 reciprocally supported in the cylinder 22, a plunger spring 24 for urging the plunger 23 in the discharge direction, and an outer periphery of the cylinder 22. An electromagnetic coil 25 is provided.

The plunger 23 has a hollow cylindrical shape, and a suction valve seat 26, a suction valve 27, and a suction valve spring 28 for urging the suction valve 27 in the suction direction are provided in the lower portion thereof, and the plunger 23 has an upper end of the plunger 23. A closing valve 29 (valve body) having a path communicating with the inner space of the cylinder 22 in the radial direction is fixed.

A shutoff valve seat 30, a discharge valve seat 31, a discharge valve 32, and a discharge valve spring 33 for urging the discharge valve 32 in the suction direction are provided at the upper end of the cylinder 22, and the lower end of the cylinder 22 is provided with. A filter 34 is provided.

Then, when the electromagnetic coil 25 is intermittently excited by a drive command of the pump 18 at a predetermined on-time and a predetermined drive frequency and at a predetermined power supply voltage, the plunger 23 closes the valve due to the magnetic flux at the time of energization. From the stop position where 29 is closed, it is pulled downward in the figure against the urging force of the plunger spring 24. At that time, the suction valve 27 is opened, the discharge valve 32 is closed, and the closing valve 29 integrated with the plunger 23 is closed. Will open. Then, the fuel oil is moved from the lower space of the cylinder 22 with the plunger 23 as a boundary to the upper space.

Next, when the magnetic flux disappears when the electromagnetic coil 25 is not energized, the plunger 23 rises upward in the figure due to the urging force of the plunger spring 24, and at that time, the suction valve 27 closes, the discharge valve 32 opens, and the plunger opens. The fuel oil in the upper space of 23 is discharged to the supply pipe 20, and the fuel oil from the oil supply pipe 21 is sucked into the lower space.

Then, the electromagnetic coil 25 is energized before the plunger 23 reaches the stop position to supply fuel oil from the external tank to the leveler tank 15. When the drive command of the pump 18 disappears, the electromagnetic coil 25 is stopped. , The plunger 23 stops at the stop position.

In this way, since the shutoff valve 29 is integrated with the plunger 23 and is urged in the discharge direction by the plunger spring 24, even if pressure is applied from the external tank, the shutoff valve 29 reliably closes the shutoff valve 29 from the leveler tank 15. It is possible to prevent the overflow of fuel oil, and since the electromagnetic coil 25 that opens and closes the shutoff valve 29 is also used to reciprocate the plunger 23, a coil only for opening and closing the shutoff valve 29 is unnecessary and the cost is low. It can be transformed into.

Next, reference numeral 35 denotes a control unit for controlling the heater 1, which is equipped with a microcomputer in which a program is stored in advance, and detects values of various sensors such as the flame detection device 9 and the oil level sensor 17 and outputs of the operation switch 4b. Is input to control the operation of the display unit 4a, the combustion fan 7, the ignition device 8, the blower fan 14, the fuel pump 16, and the pump pump 18.

Further, 36 is a changing means for changing the stroke width of the plunger 23 of the pump 18 in response to a command from the control unit 35, and has a drive frequency variable circuit and changes the drive frequency of the electromagnetic coil 25 to change the stroke width. It is possible to control the pumping flow rate of fuel oil by making changes to. When the driving frequency is small, the stroke width of the plunger 23 becomes long, the flow rate of the fuel oil increases, and the vibration becomes large, so that the driving noise also increases. On the contrary, when the drive frequency is high, the stroke width of the plunger 23 is shortened, the flow rate is reduced, the vibration is reduced, and the drive noise is also reduced.

Then, when the operation switch 4b is operated and an instruction to start the heating operation is given, the control unit 35 drives the fuel pump 16, the combustion fan 7, and the blower fan 14, and the fuel oil from the fuel supply device 6 and the combustion fan 7 The combustion air from the combustion unit 5 is supplied to the combustion unit 5, drives the ignition device 8 to start combustion, and the combustion gas from the combustion unit 5 is heat-exchanged with the indoor air by the heat exchanger 12 to become combustion exhaust gas. While the indoor air is discharged to the outside through the exhaust pipe 13, the indoor air is heated by the heat exchanger 12 by the blower fan 14 and blown out from the warm air outlet (not shown) for heating.

In the fuel supply device 6, when the oil level drops during the heating operation and the low oil level reed switch 17c detects the magnet of the float 17b, the control unit 35 starts driving the pump 18 and starts time counting. When a predetermined time elapses, the pumping pump 18 is stopped to be driven so that the inside of the leveler tank 15 is kept at a constant oil level. Here, the control unit 35 constantly monitors the output of the oil level sensor 17 regardless of whether the heating operation is in operation or stopped.

When the operation switch 4b is operated and an instruction to stop the heating operation is given, the control unit 35 stops the fuel pump 16 and the combustion fan 7 to stop the combustion, and then re-drives the combustion fan 7 and determines a predetermined value. The combustion fan 7 and the blower fan 14 are continuously driven until the time elapses, and when the inside of the equipment is cooled, the drive of the combustion fan 7 and the blower fan 14 is stopped to end the operation.

Next, the characteristic operation of the present invention will be described with reference to the drawings.
As shown in FIGS. 3 and 4, the plunger 23 is moved from the stop position where the closing valve 29 closes the closing valve seat 30 to the downward stroke width S1 in the figure by the drive start command of the pump 18 from the control unit 35. Fuel is pumped up by performing the reciprocating motion at the position. At this time, the reciprocating motion of the plunger 23 produces a driving sound of the pumping pump 18. In the present invention, the stroke width in the case of the maximum thermal power is set to S1 (FIG. 3), and the stroke width in the case of the minimum thermal power is set to S2 (FIG. 4) shorter than S1 by changing the drive frequency by the changing means 36. For example, S2 can be 50% of S1.

As shown in FIG. 5, for example, when there are 6 levels of thermal power, the stroke width is determined in advance according to the level of thermal power, and the level of thermal power is the smallest thermal power, level 1 to level 6. As the thermal power increases toward, the stroke width is controlled from S2 to S1 so as to correspond to each of the changing means 36.
Specifically, the control unit 35 controls the changing means 36 to change the drive frequency, and is 50% of S1 at level 1, 60% of S1 at level 2, 70% of S1 at level 3, and S1 at level 4. 80% of, 90% of S1 at level 5, S1 at level 6, and so on. Here, S2 is set to 50% of S1, but other proportions shorter than S1 may be used.

As a result, when the user changes the thermal power level from the large thermal power to the small thermal power on the operation panel 4, the combustion noise and the operating noise of the blower fan can be reduced, and the driving noise of the pump 18 can be suppressed to be small. It is possible to reduce the noise of the entire equipment when the heat is low.
When the level of thermal power was set to small thermal power, the stroke width of the pump 18 was shortened. Although this reduces the flow rate for pumping fuel, the amount of fuel fuel burned in the product is small when the thermal power is small. Therefore, the stroke width can be shortened to reduce the flow rate, and the driving noise can be suppressed to be small.

[Second Embodiment]
Next, the second embodiment will be described.
In the case of a heater in which the combustion noise and the operating noise of the blower fan are relatively loud, it is not necessary to change the stroke width in proportion to the thermal power as in the first embodiment, and the stroke width in the case of a large thermal power. There may be two stages, S1 and S2 at the time of other thermal power.

That is, when the thermal power is larger than the predetermined thermal power, the stroke width is set to S1, and when the thermal power is equal to or less than the predetermined thermal power, the stroke width is set to S2.
Explaining the case where there are 6 levels of thermal power as an example, as shown in FIG. 6, the stroke width is S2, which is 50% of S1 at the thermal power levels 1 and 2, and the stroke width is S1 at the levels 3 to 6. The changing means 36 is controlled so as to be. Here, S2 is set to 50% of S1, but other proportions shorter than S1 may be used.

As a result, when the user changes the thermal power level from the large thermal power to the small thermal power on the operation panel 4, the combustion noise and the operating noise of the blower fan can be reduced, and the driving noise of the pump 18 can be suppressed to be small. It is possible to reduce the noise of the entire equipment when the heat is low.

[Third Embodiment]
Next, the third embodiment will be described.
First, the control of the stroke width at the start of driving the pump 18 will be described.

As shown in FIG. 7, when the control unit 35 commands the start of driving of the pumping pump 18 while the product is operating with a predetermined thermal power, the stroke width is 50% of the predetermined stroke width S1 at the driving start time T0. The driving is started, the changing means 36 is controlled to change the driving frequency, and the stroke width is gradually increased so that the stroke width S1 is reached at the time T1 when the predetermined time elapses.

As a result, when the pump 18 is started to be driven, the drive can be started from a small drive sound, so that the drive sound at the start of the drive of the pump 18 which is repeatedly turned on and off can be made less noticeable.

Although the stroke width at time T0 has been described as 50% of S1, other ratios shorter than S1 may be used.

Next, control of the stroke width when the drive of the pump 18 of the third embodiment is stopped will be described.

As shown in FIG. 8, when the control unit 35 commands the pumping pump 18 to stop driving while the product is operating with a predetermined thermal power, the control unit 35 drives the pump with a predetermined stroke width S1 at the driving time t0. The changing means 36 is controlled to change the drive frequency to gradually reduce the stroke width so that the stroke width becomes 50% of the stroke width S1 at the time t1 when a predetermined time elapses.

As a result, when the drive of the pump 18 is stopped, the drive can be stopped after the drive sound is reduced, so that the drive sound of the pump 18 that is repeatedly turned on and off can be made less noticeable.

Although the stroke width at time t1 has been described as 50% of S1, other ratios shorter than S1 may be used.

[Fourth Embodiment]
Up to this point, the control of the pump 18 according to the thermal power has been described in the first and second embodiments, and the control at the start and stop of the drive of the pump 18 has been described in the third embodiment, but these are combined and implemented. It is also possible.
Next, a fourth embodiment in which the second embodiment and the third embodiment are combined will be described with reference to FIGS. 9 and 10.

For example, when the control unit 35 starts driving the pump 18 while the thermal power is being operated at the level 6, as shown by the solid line in FIG. 9, the stroke width is 50% of the stroke width S1 at the drive start time T0. The driving is started at, the changing means 36 is controlled to change the driving frequency, and the stroke width is gradually increased so that the stroke width S1 is reached at the time T1 when the predetermined time elapses.

On the other hand, when the pumping pump 18 is started to be driven while the thermal power is being operated at the level 1, as shown by the broken line in FIG. 9, the driving is started at the drive start time T0 with a stroke width of 50% of the stroke width S2. , The changing means 36 is controlled to change the drive frequency and gradually increase the stroke width so that the stroke width S2 is reached at the time T1 when the predetermined time has elapsed.

Further, when the driving of the pump 18 is stopped while the thermal power is being operated at the level 6, as shown by the solid line in FIG. 10, the driving time is t0 and the pump is driven with the predetermined stroke width S1. 36 is controlled to change the drive frequency to gradually reduce the stroke width so that the stroke width becomes 50% of the stroke width S1 at the time t1 when a predetermined time elapses.

On the other hand, when the driving of the pump 18 is stopped while the thermal power is being operated at the level 1, as shown by the broken line in FIG. 10, the driving time is t0 and the pump is driven with the predetermined stroke width S2. 36 is controlled to change the drive frequency to gradually reduce the stroke width so that the stroke width becomes 50% of the stroke width S2 at the time t1 when a predetermined time elapses.

As a result, when the user sets the thermal power level to a small thermal power on the operation panel 4, the driving noise of the pump 18 can be suppressed to a small level while the combustion noise and the operating noise of the blower fan are reduced. In addition to making it possible to reduce the noise of the entire device, when the pump 18 that repeatedly turns the drive on and off while the device is operating, the drive can be started from a small drive sound, making the drive sound at the start of drive less noticeable. Further, when the drive of the pump 18 is stopped, the drive can be stopped after the drive sound is reduced, so that the drive sound at the time of the drive stop can be made inconspicuous.

The stroke widths of the times T0 and T1 in FIG. 9 differ depending on the thermal power, but may be a constant stroke width regardless of the thermal power. Similarly, the stroke widths at times t0 and t1 in FIG. 10 differ depending on the thermal power, but may be a constant stroke width regardless of the thermal power.

[Another Embodiment]
Next, another specific configuration of the changing means 36 for changing the stroke width of the plunger 23 of the pump 18 will be described. In the first to fourth embodiments described above, the content of changing the stroke width of the plunger 23 by changing the drive frequency of the electromagnetic coil 25 is shown, but there are cases where the power supply voltage of the electromagnetic coil 25 is changed and the electromagnetic coil 25. Each case of changing the on-time of is described.

First, a case where the power supply voltage of the electromagnetic coil 25 is changed will be described.
The changing means 36 has a power supply voltage variable circuit, and changes the stroke width by changing the power supply voltage of the electromagnetic coil 25 of the pumping pump 18.
When the power supply voltage is increased, the electromagnetic force of the electromagnetic coil 25 becomes stronger, the force of pulling the plunger 23 becomes stronger, the stroke width becomes longer, the vibration becomes larger, and the driving sound also increases.
On the other hand, when the power supply voltage is lowered, the electromagnetic force of the electromagnetic coil 25 is weakened, the force for pulling the plunger 23 is weakened, and the stroke width is shortened, whereby the vibration is reduced and the driving noise can be reduced.
As a result, the stroke width of the plunger 23 can be changed by changing the power supply voltage as in the case of changing the drive frequency described above.

Next, a case where the on-time of the electromagnetic coil 25 is changed will be described.
The changing means 36 has an on-time variable circuit, and changes the stroke width by changing the on-time of the electromagnetic coil 25 of the pumping pump 18.
When the on-time is lengthened, the time for pulling the plunger 23 due to the electromagnetic force of the electromagnetic coil 25 becomes longer, the stroke width becomes longer, the vibration becomes larger, and the driving sound also increases.
On the other hand, when the on-time is shortened, the time for pulling the plunger 23 is shortened and the stroke width is shortened, whereby the vibration is also reduced and the driving sound can be reduced.
As a result, the stroke width of the plunger 23 can be changed by changing the on-time as in the case of changing the drive frequency described above.

The present invention is not limited to the above-described embodiment, and modifications, improvements, and the like within the range in which the object of the present invention can be achieved are included in the present invention. Thus, various modifications can be made without departing from the spirit or scope of the general concept of the invention as defined by the appended claims and their equivalents.

1 Heater 15 Leveler tank 16 Fuel pump 17 Oil level sensor 18 Pumping pump 23 Plunger 35 Control unit 36 Changing means

Claims (5)

A leveler tank that receives fuel from an external tank and keeps it at a constant oil level,
A fuel pump that supplies the fuel oil of the leveler tank to the combustion unit,
An oil level sensor that detects the oil level in the leveler tank and
A pump that supplies fuel from the external tank to the leveler tank by a plunger that reciprocates with a predetermined stroke width, and
A control unit that controls the amount of oil in the fuel pump according to the magnitude of the heating power of the heater, detects the oil level height in the leveler tank with the oil level sensor, and starts or stops the pumping pump. When,
A changing means for changing the stroke width of the plunger of the pumping pump is provided.
The control unit is a combustion device that controls the changing means so that the smaller the heating power of the heater, the shorter the stroke width of the plunger. The control unit sets the stroke width of the plunger as the first stroke width when the thermal power is greater than the predetermined thermal power of the heater, and the second stroke shorter than the first stroke width when the thermal power is equal to or less than the predetermined thermal power. The combustion apparatus according to claim 1, wherein the width is set. A leveler tank that receives fuel from an external tank and keeps it at a constant oil level,
A fuel pump that supplies the fuel oil of the leveler tank to the combustion unit,
An oil level sensor that detects the oil level in the leveler tank and
A pump that supplies fuel from the external tank to the leveler tank by a plunger that reciprocates with a predetermined stroke width, and
A control unit that controls the amount of oil in the fuel pump according to the magnitude of the heating power of the heater, detects the oil level height in the leveler tank with the oil level sensor, and starts or stops the pumping pump. When,
A changing means for changing the stroke width of the plunger of the pumping pump is provided.
The control unit controls the changing means so as to start the stroke width of the plunger from a stroke width shorter than the predetermined stroke width and then gradually change the stroke width to the predetermined stroke width at the start of driving the pump. Combustion device featuring. The control unit is characterized in that when the drive of the pump is stopped, the stroke width of the plunger is gradually changed from a predetermined stroke width to a stroke width shorter than the predetermined stroke width, and then the pump is stopped. The combustion apparatus according to claim 3. The combustion apparatus according to claim 1 to 4, wherein the changing means for changing the stroke width of the plunger changes the stroke width according to any one of the drive frequency, the power supply voltage, and the on-time of the pump.

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