JP2002034291A - Method for controlling speed of electric motor and method for controlling boiler - Google Patents

Abstract

PROBLEM TO BE SOLVED: To quickly change the speed of an electric motor, a blower in a boiler, and a water supply pump. SOLUTION: In the method for controlling the speed of a plurality of electric motors by an inverter device 14, when the speed of a specific electric motor is to be changed, the operation of other electric motors is incidentally controlled. Also, in the boiler 23 having the blower 26 and water supply pump 31, the speed of the blower 26 and water supply pump 31 are controlled by the inverter device 14. In this case, when the speed of one of the blower 26 and water supply pump 31 is changed, the operation of the other is incidentally controlled.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a method for controlling the number of revolutions of a motor for controlling the number of revolutions of a motor, and a method for controlling the number of revolutions of a blower and a water supply pump in a boiler. .

[0002]

2. Description of the Related Art A boiler is provided with a blower for supplying air for combustion. In some cases, the amount of air blown by the blower is adjusted by controlling the number of revolutions using an inverter device. In this boiler, when changing the combustion amount between the high combustion and the low combustion, the fuel supply amount is changed between the high combustion supply amount and the low combustion supply amount, and the fuel supply amount is changed. According to the change, the rotation speed of the blower is changed between a high combustion rotation speed and a low combustion rotation speed.

[0003] In the above configuration, the change of the fuel supply amount is completed in a very short time by opening and closing the fuel valve. However, the change of the rotation speed of the blower is completed only by the inertia force of the blower. And requires a relatively long time as compared with a change in the fuel supply amount.
In particular, it takes a long time to reduce the rotation speed from the high combustion rotation speed to the low combustion rotation speed. Then,
When the amount of combustion is changed, the balance between the amount of fuel supplied and the amount of air blow is likely to be disrupted, which may cause the flame to blow out or generate black smoke. Therefore, it is desirable that the change of the number of revolutions in the blower be completed in as short a time as possible.

[0004] Further, in order to reduce power consumption and the like, it has been demanded that a water supply pump attached to the boiler also perform rotation speed control using the inverter device. However, if the inverter device is simply 1
Providing an additional one requires an extra space as an installation space, and causes an increase in manufacturing cost.

[0005]

The problem to be solved by the present invention is to quickly change the number of revolutions of an electric motor, and to quickly change the number of revolutions of a blower and a water supply pump in a boiler. .

[0006]

Means for Solving the Problems The present invention has been made to solve the above-mentioned problems, and the invention according to claim 1 is a method for controlling the rotation speed of a plurality of electric motors by an inverter device. When changing the rotation speed of a predetermined motor among the motors, the operation of the other motors is incidentally controlled.

The invention according to claim 2 is characterized in that, when the rotation speed of the predetermined motor is reduced, the other motor is operated or the rotation speed of the other motor is increased.

The invention according to claim 3 is characterized in that when increasing the rotation speed of the predetermined motor, the other motor is stopped or the rotation speed of the other motor is decreased.

According to a fourth aspect of the present invention, in a boiler provided with a blower and a water supply pump, the number of rotations of the blower and the water supply pump is controlled by an inverter device,
When changing the rotation speed of one of the blower and the water supply pump, the operation of the other is controlled incidentally.

[0010] The invention according to claim 5 is characterized in that when the rotation speed of one of the blower and the water supply pump is reduced, the other is operated or the rotation speed of the other is increased.

Further, the invention according to claim 6 is characterized in that when increasing the rotation speed of one of the blower and the water supply pump, the other is stopped or the rotation speed of the other is decreased. .

[0012]

Next, an embodiment of the present invention will be described. According to the present invention, the rotation speeds of the plurality of electric motors are controlled by the inverter device. This inverter device includes a plurality of output units, and each of these output units is connected to each of the electric motors. That is, power of a predetermined frequency is output from each of the output units to each of the electric motors. When changing the rotation speed of a predetermined motor among the motors, the operation of the other motors is additionally controlled to shorten the time required for the change. Here, the predetermined motor is
A predetermined number (one or more) is selected from the respective motors, while the other motors are selected a predetermined number (one or more) from the respective motors excluding the predetermined motor. It has become.

Hereinafter, additional control for controlling the other motor when changing the rotation speed of the predetermined motor will be described in detail.

First, the case where the rotation speed of the predetermined motor is reduced will be described. At this time, control for operating the other electric motor in a stopped state is performed.
That is, electric power is temporarily supplied to the other motor in a stopped state to be consumed, and regenerative braking is applied to the predetermined motor. Therefore, the rotation speed of the predetermined electric motor is reduced to a desired rotation speed in a short time. And
After the change of the rotation speed of the predetermined motor is completed, the other motor is returned to the stopped state again.

Further, depending on the embodiment, when decreasing the rotation speed of the predetermined motor, control for increasing the rotation speed of the other motor in the operating state may be performed. In other words, the amount of power supplied to the other motor in the operating state is temporarily increased to consume the increased power, and regenerative braking is applied to the predetermined motor. Therefore, the rotation speed of the predetermined electric motor is reduced to a desired rotation speed in a short time. Then, after the change of the rotation speed of the predetermined motor is completed, the rotation speed of the other motor is returned to the original rotation speed.

Next, an explanation will be given of a case where the rotation speed of the predetermined motor is increased. At this time, control for stopping the other electric motor in the operating state is performed. That is, the supply of power to the other motor in the operating state is temporarily stopped, and the entire power is supplied to the predetermined motor. Therefore, the rotation speed of the predetermined electric motor increases to a desired rotation speed in a short time. Then, after the change of the rotation speed of the predetermined motor is completed, the other motor is returned to the original operating state.

Further, depending on the embodiment, when increasing the rotation speed of the predetermined motor, control for decreasing the rotation speed of the other motor in operation may be performed. That is, the amount of power supplied to the other motor in the operating state is temporarily reduced, and the reduced power is passed to the predetermined motor. Therefore, the rotation speed of the predetermined electric motor increases to a desired rotation speed in a short time. Then, after the change of the rotation speed of the predetermined motor is completed,
The rotation speed of the other electric motor is returned to the original rotation speed.

If there is no other motor that is in the operating state, the control for changing the rotation speed of the predetermined motor is performed as it is. An operation command is not output to the other electric motor.

As described above, according to the above configuration, the rotation speed of each of the plurality of electric motors can be controlled by one inverter device, and the rotation speed of each of the electric motors can be quickly changed. .

Incidentally, the rotation speed control method can be applied to various devices as long as the device includes a plurality of the electric motors. For example, in a boiler, the present invention can be applied to the control of the rotation speed of an electric motor provided in a blower, a water supply pump, a fuel pump, and the like. That is,
At least two electric motors can be selected from the electric motors provided in each of these devices, and the rotation speed control method can be applied.

Hereinafter, a configuration of the boiler provided with the blower and the water supply pump to which the above-described rotation speed control method is applied will be specifically described. In this configuration, the rotation speed of the blower and the water supply pump is controlled by the inverter device, and when changing the rotation speed of one of the blower and the water supply pump, the other is used to reduce the time required for the change. The operation is controlled incidentally. Here, what is controlled by the inverter device is directly an electric motor provided in each of the devices, but in the following description, detailed description thereof will be omitted, and the blower and This will be described in terms of controlling the water supply pump.

First, the case where the rotation speed of one of the blower and the water supply pump is reduced will be described.
At this time, control for operating the other of the stopped states is performed. That is, electric power is temporarily supplied to the other one in the stopped state to be consumed, and regenerative braking is applied to the one. Therefore, the one rotational speed is
The number of revolutions decreases to a desired number in a short time. Then, after the change of the rotational speed of the one is completed, the other is returned to the stop state again.

Further, depending on the embodiment, when the one rotational speed is decreased, control for increasing the other rotational speed in an operating state may be performed. In other words, the amount of power supply to the other in the operating state is temporarily increased to consume the increased power, and regenerative braking is applied to the one. Therefore, the one rotation speed decreases to a desired rotation speed in a short time. Then, after the change of the rotation speed of the one is completed, the rotation speed of the other is returned to the original rotation speed.

Next, the case where one of the blower and the water supply pump is rotated will be described. At this time, control for stopping the other of the operating states is performed. That is, the supply of power to the other in the operating state is temporarily stopped, and the entire power is supplied to the one. Therefore, the one rotation speed increases to a desired rotation speed in a short time. Then, after the change in the number of revolutions on one side is completed, the other side is returned to the original operating state.

Further, depending on the embodiment, when increasing the one rotation speed, control for decreasing the other rotation speed in the operating state may be performed. That is, the amount of power supplied to the other in the operating state is temporarily reduced, and the reduced power is sent to the one. Therefore,
The one rotation speed increases to a desired rotation speed in a short time. Then, after the change of the rotation speed of the one is completed, the rotation speed of the other is returned to the original rotation speed.

If the other is not in operation,
Although the change control of the rotation speed in the one side is performed as it is,
Until the rotation speed change control is completed, no operation command is output to the other stopped state.

As described above, according to the above configuration, the rotation speeds of the blower and the water supply pump can be controlled by one inverter device, and the rotation speeds of the blower and the water supply pump can be quickly changed. can do. In particular, it is highly necessary for the blower to complete the change of the rotation speed in a short time in relation to the switching of the combustion amount, and is suitable for the change control.

[0028]

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, specific embodiments of the present invention will be described in detail with reference to the drawings. First, a first embodiment of the present invention will be described with reference to FIGS. In the first embodiment, the method of controlling the number of revolutions of a motor according to the present invention is applied to water supply control of a water tank in a wastewater treatment device or the like.

In FIG. 1, two water tanks, a first water tank 1 and a second water tank 2, are provided side by side, and a first water supply line 3 and a first discharge line 4 are connected to the first water tank 1. On the other hand, the second water tank 2 has a second water supply line 5.
And the second discharge line 6 is connected. The first water supply line 3 is provided with a first water supply pump 8 having a first electric motor 7, while the second water supply line 5 is provided with a second water supply pump having a second electric motor 9. 10 are provided.

The first water tank 1 and the second water tank 2 have a first water level sensor 11 and a second water level sensor 12 respectively.
Are provided respectively, and both of these sensors 11, 1
Reference numeral 2 detects the water level based on the pressure applied to the detection unit (symbol omitted). And the two sensors 1
Based on signals from the motors 1 and 12, the controller 13 controls the rotation speeds of the electric motors 7 and 9 via an inverter device 14, respectively. Here, the controller 13 is connected to the sensors 11 and 12 by signal lines 15 and 15. The controller 13 is connected to the electric motors 7 and 9 by the signal lines 15 via the inverter device 14, respectively.

Further, the configuration of the inverter device 14 will be described with reference to FIG. The inverter device 14 includes, as an output unit, the first output unit 1 arranged in parallel.
6 and a second output unit 17, and these two output units 16 and 17 are connected to the two electric motors 7 and 9, respectively. In addition, the two output units 16 and 17 include:
A first inverter control circuit 18 and a second inverter control circuit 19 are connected to each other. The controller 13 is connected to the two inverter control circuits 18 and 19 via an input unit 20. Further, the two output units 1
A common power supply unit 21 is connected to 6 and 17. In the illustrated embodiment, a converter is used as the power supply unit 21 and converts a 200V AC voltage from the AC power supply 22 into a DC voltage of about 280V. Therefore, the two output units 16 and 17 supply the two electric motors 7 and 9 with a predetermined frequency AC power based on the frequency signals from the two inverter control circuits 18 and 19 and the DC power from the power supply unit 21. Are respectively output.

The operation of the above configuration will be described. The water tanks 1 and 2 are for storing the water to be treated, and the water levels of the water tanks 1 and 2 are controlled to be substantially constant. That is, the water to be treated in the water tanks 1 and 2 is supplied via the water supply lines 3 and 5 by the amount of the water discharged from the discharge lines 4 and 6 to a processing device (not shown). It has become. Specifically, when the electric motors 7 and 9 respectively attached to the water supply pumps 8 and 10 are in a predetermined range when the water levels in the water tanks 1 and 2 are within a predetermined range, a predetermined normal rotation speed is set. Each rotating at a certain first rotation speed, and when the water level exceeds the predetermined range, each stops, and when the water level falls below the predetermined range,
It rotates at a second rotational speed for emergency supply which is higher than the first rotational speed. That is, the rotation speeds of the electric motors 7 and 9 are controlled in three stages of the first rotation speed, the second rotation speed, and the stop, respectively.

The method for controlling the rotational speed of the electric motor according to the present invention is applied when the rotational speed of one of the two electric motors 7 and 9 is changed. In the following description, the case where the rotation speed of the first electric motor 7 is changed will be described assuming that the rotation speed of the first electric motor 7 is preferentially changed.

First, a description will be given of a case where the rotation speed of the first electric motor 7 is decreased, that is, a case where the second rotation speed is changed to the first rotation speed or a case where the first rotation speed is changed to the stopped state. . At this time, if the second electric motor 9 is stopped, the second electric motor 9 is operated to rotate the second electric motor 9 at the first rotation speed for a predetermined time (several seconds). I have to. That is,
Temporarily supplying power to the second motor 9 for consumption,
Regenerative braking is applied to the first electric motor 7.
Therefore, the rotation speed of the first electric motor 7 decreases to the first rotation speed or the stopped state in a short time. After the lapse of the predetermined time, the second electric motor 9 is returned to the stop state again.

When the rotation speed of the first motor 7 is reduced, if the second motor 9 is operating at the first rotation speed, the second motor 9 is maintained for a predetermined time (several seconds). 9 is rotated at the second rotation speed. That is, the amount of electric power supplied to the second electric motor 9 is temporarily increased, the increased electric power is consumed, and regenerative braking is applied to the first electric motor 7. Therefore, the rotation speed of the first electric motor 7 decreases to the first rotation speed or the stopped state in a short time. After the lapse of the predetermined time, the rotation speed of the second electric motor 9 is returned to the original first rotation speed.

Next, a description will be given of a case where the rotation speed of the first electric motor 7 is increased, that is, a case where the first rotation speed is changed from the first rotation speed to the second rotation speed or a case where the rotation speed is changed from the stopped state to the first rotation speed. I do. At this time, if the second electric motor 9 is operating at the first rotational speed, the second electric motor 9 is stopped for a predetermined time (several seconds). That is, the supply of electric power to the second electric motor 9 is temporarily stopped, and the entire electric power is supplied to the first electric motor 7. Therefore, the rotation speed of the first electric motor 7 increases to the second rotation speed or the first rotation speed in a short time. After the lapse of the predetermined time,
The second electric motor 9 is returned to the state where it is operating at the original first rotation speed.

When increasing the rotation speed of the first motor 7, if the second motor 9 is operating at the second rotation speed, the second motor 9 is maintained for a predetermined time (several seconds). 9 is rotated at the first rotation speed. That is, the amount of electric power supplied to the second electric motor 9 is temporarily reduced, and the reduced electric power is sent to the first electric motor 7. Therefore, the rotation speed of the first electric motor 7 increases to the second rotation speed or the first rotation speed in a short time. After the lapse of the predetermined time, the rotation speed of the second electric motor 9 is returned to the original second rotation speed.

Here, each of the predetermined times is a time sufficient to complete the change of the rotation speed of the first electric motor 7, and the fluctuation range of the water level in the second water tank 2 is small, and the water level control is performed. Is set to a time that does not significantly affect Further, depending on the implementation, the rotation speed of the first electric motor 7 is detected, and when it is detected that the change of the rotation speed of the first electric motor 7 is completed, the second electric motor 9 is returned to the original state. You can also do so.

As described above, according to the first embodiment,
When changing the rotation speed of the first electric motor 7, the rotation speed of the first electric motor 7 can be changed in a short time by additionally controlling the operation of the second electric motor 9. In addition, the rotation speeds of the two electric motors 7 and 9 can be controlled by one inverter device 14, and the inverter device 14 uses the same power supply unit 21 to reduce the size and cost. Configuration.

Next, a second embodiment of the present invention will be described with reference to FIGS. The second embodiment shows one embodiment of the boiler control method according to the present invention.

In FIG. 3, the boiler 23 has a can 24, and a burner 25 is mounted on the can 24. The burner 25 includes an electric motor (not shown).
Is connected. Further, a fuel supply line 27 is connected to the burner 25, and a first fuel valve 28 and a second fuel valve 29 are provided in parallel with the fuel supply line 27. The can 2
A water supply line 30 is connected to a lower part of the water supply line 4, and the water supply line 30 is provided with a water supply pump 31 provided with an electric motor (not shown) and a check valve 32 in order from the upstream side. A water level control cylinder 35 is connected to a side of the can body 24 via an upper communication pipe 33 and a lower communication pipe 34, and a water level sensor 36 is provided in the water level control cylinder 35. Further, the can body 24 is provided with a pressure sensor 37 for detecting a steam pressure.
A steam line 38 is connected.

The first fuel valve 28, the second fuel valve 29, the water level sensor 36 and the pressure sensor 37
Are connected to the controller 40 by signal lines 39, 39,... The controller 40 is connected to the blower 26 and the water supply pump 3 by the signal lines 39 via the same inverter device 14 as in the first embodiment.
1 is connected.

FIG. 4 shows the structure of the inverter device 14 in the second embodiment. The basic structure is the same as that of the inverter device 14 in the first embodiment. The same components are denoted by the same reference numerals, and detailed description thereof will be omitted. Now, in the inverter device 14 in the second embodiment, the two output sections 16 and 17 are connected to the blower 26 and the water supply pump 31, respectively. Here, the two output units 16 and 17 are directly connected to the two electric motors provided in the blower 26 and the water supply pump 31, but are not shown. Also, in the following description, the description will be made with the expression that the blower 26 and the water supply pump 31 are controlled by the inverter device 14.

The operation of the above configuration will be described. The amount of combustion of the burner 25 is determined by the pressure sensor 3
The control is performed in accordance with the steam pressure based on the signal from the control unit 7, and the control is performed in three stages of high combustion, low combustion, and standby. The fuel supply amount is controlled by opening and closing the two fuel valves 28 and 29. When the combustion is high, the fuel valves 28 and 29 are opened. When the combustion is low, only the first fuel valve 28 is opened. During standby, both fuel valves 28 and 29 are closed. In addition, the control of the amount of combustion air
It is performed by controlling the rotation speed of the blower 26,
At the time of high combustion, the rotation speed of the blower 26 becomes the high combustion rotation speed, at the time of low combustion, the rotation speed of the blower 26 becomes the low combustion rotation speed, and at the time of standby, the blower 26 stops.

The water supply pump 31 is controlled based on a signal from the water level sensor 36 so as to maintain the water level in the can 24 within a predetermined range. That is,
The rotation speed of the water supply pump 31 is controlled according to the water level,
At the time of water supply, the rotation speed of the water supply pump 31 is controlled to the rotation speed for water supply, and at the time of non-water supply, the rotation speed of the water supply pump 31 is controlled to the rotation speed for idling. The idling rotation speed is set to a value smaller than the water supply rotation speed. At the idling rotation speed, the water supply pump 31 is rotating but lower than the pressure in the can body 24. In the state of the discharge pressure, it is in a so-called idling state. Therefore, at the time of water supply, the inrush current is remarkably reduced as compared with the case of starting from a stopped state.

Further, a method of controlling the number of rotations of the blower 26 and the water supply pump 31 will be specifically described.
In the following description, a case where the rotation speed of the blower 26 is changed will be described. The blower 26 has a high necessity to complete the change of the number of revolutions in a short time in relation to the switching of the combustion amount, and is very effective in practicing the present invention.

First, a description will be given of a case where the rotation speed of the blower 26 is decreased, that is, a case where the high combustion rotation speed is changed to the low combustion rotation speed. At this time,
If the water supply pump 31 is operating at the idling rotation speed, the rotation speed of the water supply pump 31 is changed from the idling rotation speed to the water supply rotation speed for a predetermined time (several seconds). I have to. That is, the amount of electric power supplied to the water supply pump 31 is temporarily increased to consume the increased electric power, and regenerative braking is applied to the blower 26. Therefore, the blower 2
The number of revolutions of 6 is reduced to the low-combustion number of revolutions in a short time. After the lapse of the predetermined time, the water supply pump 3
The number of rotations of 1 is returned to the original number of rotations for idling.

Next, a description will be given of a case where the rotational speed of the blower 26 is increased, that is, a case where the rotational speed for low combustion is changed to the rotational speed for high combustion. At this time, if the water supply pump 31 is operating at the idling rotation speed or the water supply rotation speed, the water supply pump 31 is stopped for a predetermined time (several seconds). That is, the supply of electric power to the water supply pump 31 is temporarily stopped, and the entire electric power is supplied to the blower 26. Therefore, the rotation speed of the blower 26 increases to the high combustion rotation speed in a short time.
After the lapse of the predetermined time, the rotation speed of the water supply pump 31 is returned to the original rotation speed.

Further, depending on the implementation, when the rotation speed of the blower 26 is increased, if the water supply pump 31 is in the operating state at the water supply rotation speed, the water supply pump 31 is operated for a predetermined time (several seconds). The water supply pump 31 may be rotated at the idling speed. That is, the supply amount of electric power to the water supply pump 31 is temporarily reduced,
The reduced power is sent to the blower 26. Therefore, the rotation speed of the blower 26 increases to the high combustion rotation speed in a short time. After the lapse of the predetermined time, the rotation speed of the water supply pump 31 is returned to the original rotation speed for water supply.

Here, each of the predetermined times is set to a time that is sufficient to complete the change of the rotation speed of the blower 26 and that does not significantly affect the water level control in the can 24. ing. Also, depending on the implementation,
The rotation speed of the blower 26 is detected, and when it is detected that the change of the rotation speed of the blower 26 is completed, the water supply pump 31 may be returned to the original state.

As described above, according to the second embodiment,
When changing the rotation speed of the blower 26, the rotation speed of the blower 26 can be changed in a short time by additionally controlling the operation of the water supply pump 31. In addition, the rotation speed of the blower 26 and the water supply pump 31 can be controlled by one inverter device 14, and the inverter device 14 has a small power supply unit 21. Thus, a low-cost configuration can be achieved.

[0052]

According to the present invention, the rotation speeds of a plurality of motors can be controlled by one inverter, and the rotation speeds of the motors can be changed quickly. .

According to the present invention, the rotation speeds of the blower and the water supply pump can be controlled by one inverter device, and the rotation speeds of the blower and the water supply pump can be quickly changed. be able to.

[Brief description of the drawings]

FIG. 1 is an explanatory diagram showing a first embodiment of the present invention.

FIG. 2 is an explanatory diagram showing a specific example of the inverter device in FIG.

FIG. 3 is an explanatory view showing a second embodiment of the present invention.

4 is an explanatory diagram showing a specific example of the inverter device in FIG.

[Explanation of symbols]

 7 First motor 9 Second motor 14 Inverter device 23 Boiler 26 Blower 31 Water feed pump

Continued on front page F term (reference) 3K003 JA11 KA01 LA06 NA04 3L021 AA05 CA10 DA06 DA25 EA04 FA03 FA14 5H572 AA07 AA10 BB06 CC05 DD02 EE04 FF01 FF03 FF05 FF06 GG07 HB07 HC01 HC04 HC07 JJ18 KK07 LL01LL33

Claims (6)

[Claims] In a method of controlling the rotation speed of a plurality of motors by an inverter device, when the rotation speed of a predetermined motor among the motors is changed, the operation of other motors is additionally controlled. A method for controlling the number of revolutions of a motor. 2. The method according to claim 1, wherein when the rotation speed of the predetermined motor is reduced, the other motor is operated or the rotation speed of the other motor is increased.
3. The method for controlling the number of revolutions of an electric motor according to claim 1. 3. The method according to claim 1, wherein when increasing the rotation speed of the predetermined motor, the other motor is stopped or the rotation speed of the other motor is decreased.
3. The method for controlling the number of revolutions of an electric motor according to claim 1. 4. In a boiler 23 provided with a blower 26 and a water supply pump 31, the number of rotations of the blower 26 and the water supply pump 31 is controlled by an inverter device 14, and one of the rotations of the blower 26 and the water supply pump 31 is controlled. A method for controlling a boiler, characterized in that when the number is changed, the operation of the other is incidentally controlled. 5. The blower 26 and the water supply pump 3.
5. The control method for a boiler according to claim 4, wherein when one of the rotation speeds is decreased, the other is operated or the other rotation speed is increased. 6. The blower 26 and the water supply pump 3.
5. The control method for a boiler according to claim 4, wherein when increasing the rotation speed of one of the ones, the other is stopped or the rotation speed of the other is decreased.