JP3614665B2 - Operation method of variable speed pump - Google Patents

Description

[0001]
BACKGROUND OF THE INVENTION
The present invention provides a variable speed pump device in which a plurality of pumps are each driven at a variable speed by an inverter, and the pressure fluctuation during an increase in the number of pumps to be operated or a decrease in the number of pumps to be operated is reduced. with reduced relates to the operation how the variable speed pump operating time of each pump can be leveled.
[0002]
[Prior art]
A variable speed pump that performs an increase operation or a decrease operation that decreases the number of operating multiple pumps that are controlled by an inverter (variable speed operation means) according to the water demand. The driving method is known.
[0003]
In this conventional variable speed pump operation method, when the number of units is increased, the starting machine is operated at the highest speed and the pumps to be increased are started, and then the variable speed operation is performed.
Furthermore, when the number of vehicles is reduced, the last engine that is operating at variable speed is stopped, and the last engine that was started last is switched from the highest speed operation to the variable speed operation.
[0004]
FIG. 3 is an explanation of a pump device capable of operating the pumps from No. 1 to No. 4 in parallel.
FIG. 3 is a graph showing an operation situation in which the operation method of the variable speed pump is adopted. In FIG. 3, the vertical axis represents the flow rate, and the horizontal axis represents time. The numbers represent the pump number and the passage of time. Furthermore, in FIG. 3, the part represented by the square is operating at the highest speed and always has the maximum flow rate. Further, a portion represented by a triangle is a portion that is variable speed by an inverter.
[0005]
First, at time to, the No. 1 pump is started, and this No. 1 pump is operated at a variable speed by an inverter. Then, at time t1, the first machine, which is the starting machine, is operated at the highest speed, and the second machine is increased in number and operated at a variable speed by the inverter. Further, at time t2, the first and second machines, which are the starting machines, are operated at the highest speed, and the third machine is increased in number and operated at a variable speed by the inverter.
[0006]
Further, the state is maintained from time t3 to t4, and the reduction operation is performed at time t4.
That is, at time t4, the last machine that was started last is stopped. And the No. 2 machine which is the last machine started most recently is operated by the inverter at variable speed.
[0007]
When further reducing the number of cars, the second machine that was last started at time t5 is stopped, and the first machine that is started last and is operated at a variable speed by an inverter. Yes.
[0008]
In such a variable speed pump operation method, the first machine that was started first is continuously operated until it is stopped due to a small amount of water. Therefore, when such a variable speed pump operation method is used in condominiums and factories with a large number of households, it will rarely stop due to a small amount of water. Continue to drive.
[0009]
[Problems to be solved by the invention]
For this reason, in a variable speed pump operation method in which water is supplied by a pump controlled by a plurality of inverters, only a specific pump continues to operate for a long time, resulting in variations in life between pumps. There is a problem that it ends up.
[0010]
The present invention has been made in view of the above points, and an object of the present invention is to increase the number of pumps to be operated or to increase the number of pumps to be operated in a variable speed pump device in which a plurality of pumps are driven at a variable speed by an inverter. thereby reducing the pressure variation during the reduced table operation to reduce the number of pumps to provide a driving how variable speed pump operating time of each pump can be leveled.
[0011]
[Means for Solving the Problems]
According to a first aspect of the present invention, there is provided a variable speed pump operating method in which a plurality of pumps, each of which is controlled by a variable speed operation means, are operated in accordance with the demand for water, and the number of units is increased or decreased. When operating multiple pumps in parallel in the operation method of variable speed pumps that are operating in a reduced number of units, the first machine to be operated first is variable speed operated by the variable speed operation means, and the subsequent engine that is operated after the other is operated. When the number of pumps to be operated is increased, the number of pumps to be increased is slowly increased until reaching the maximum speed at a change speed below a predetermined speed, and then the maximum speed is increased. When the number of cars is reduced, the starting machine that is operating at variable speed is stopped, and the pump that has been started first among the following engines is switched from maximum speed operation to variable speed operation to become a new starting machine. And wherein the door.
[0013]
DETAILED DESCRIPTION OF THE INVENTION
Hereinafter, an embodiment of the present invention will be described with reference to the drawings. FIG. 1 is a system configuration diagram of a variable speed pump apparatus in which a variable speed pump operating method according to the present invention is employed.
[0014]
In FIG. 1, reference numeral 11 denotes a CPU (central processing unit) that comprehensively controls the variable speed pump device. The CPU 11 is composed of a microcomputer and its peripheral circuits. The CPU 11 includes one D / A converter 11d.
[0015]
This one CPU 11 can control the operation of the four pumps p1 to p4.
The operation of each pump p1 to p4 is controlled by motors m1 to m4.
[0016]
Furthermore, the operating frequencies of the motors m1 to m4 are respectively controlled by inverters i1 to i4 which are variable speed operating means.
By the way, the CPU 11 is provided with ON terminals for outputting four increase / decrease table signals for outputting ON / ON signals for starting / stopping operations of the inverters i1 to i4.
[0017]
That is, the ON1 to ON4 signals are output from the four ON terminals to the inverters i1 to i4. In other words, the ON1 to ON4 signals output “0” in the initial state, and when performing a stand-up operation to increase the pump, a “1” signal is output to perform a stand-down operation to decrease the pump. The “0” signal is output to the output.
[0018]
Further, the CPU 11 has four OUT terminals. These OUT terminals turn on the corresponding OUT terminals when driving the pumps p1 to p4.
The Q1 to Q4 signals output from the four OUT terminals are respectively input to one input terminals of the adders 13a to 13d via the integrators 12a to 12d.
[0019]
By the way, the analog value proportional to the operating frequency of the inverters i1 to i4 output from the D / A converter 11d is input to the other input terminal of each of the adders 13a to 13d. The input of the D / A converter 11d is determined by the control of the CPU 11. That is, the size of the input of the D / A converter 11d is determined according to the amount of water supply that is demanded.
[0020]
Next, an embodiment of the present invention configured as described above will be described.
First, the variable speed pump device shown in FIG. 1 can operate four pumps p1 to p4 in parallel.
[0021]
When the pressure detected by a pressure sensor provided in a water supply pipe (not shown) becomes smaller than the starting pressure, the CPU 11 starts the pump and controls the starting machine so that the discharge pressure of the pump becomes the target pressure. If the target pressure is not reached even if the starting machine is controlled by the inverter, the additional operation for increasing the number of driving pumps is performed. In other words, when the number of units is increased, the number of rotations of the pumps to be increased is slowly increased until reaching the maximum speed at a predetermined change speed or less, and then the maximum speed is operated.
[0022]
On the other hand, when the demand for water decreases, a reduced-unit operation is performed to reduce the number of pumps to be operated. In other words, at the time of reduced vehicle operation, the starting machine that is operating at variable speed is stopped, and the pump that has been started first among the succeeding machines is switched from maximum speed operation to variable speed operation to become a new starting machine. ing.
[0023]
First, in the initial state, the ON1 to ON4 signals and the Q1 to Q4 signals are off.
First, a case where the pumps are sequentially started from a state where the pumps p1 to p4 are not driven at all will be described.
[0024]
First, when the discharge pressure of the pump becomes equal to or lower than the starting pressure, the pump p1 is started at time to in FIG. This is performed by driving the inverter i1 by setting the ON1 output of the CPU 11 to the “1” level.
[0025]
And only the pump p1 is drive | operated by the inverter i1, and the water supply quantity Q is controlled.
Here, the output of the D / A converter 11d is input to the inverter i1. The D / A converter 11d outputs an analog value proportional to the operating frequency of the inverter 11d so that the discharge pressure of the pump becomes the target pressure.
[0026]
Then, if the pump discharge pressure does not reach the target pressure even when the pump p1 is operated, the pump p2 is increased in number at time t1.
That is, at time t1, the CPU 11 changes the Q2 output to the “1” level. Since this signal is input to one input terminal of the adder 13b via the integrator 12b, the signal changes smoothly.
[0027]
Here, since the output of the D / A converter 11d is inputted to the other input terminal of the adder 13b, the pump p2 is operated at the maximum speed by the inverter 13d.
[0028]
Even if the pump p2 is activated, the signal input to the inverter i2 changes smoothly because the Q2 signal is output via the integrator 12b.
Therefore, since the rotation speed of the pump p2 operated by the inverter i2 changes at a change speed below a predetermined value and changes to the maximum speed, the fluctuation of the pump discharge pressure due to switching when the number of pumps p2 is increased is suppressed to a small level. Can do.
[0029]
Furthermore, if the pump discharge pressure does not reach the target pressure even when the pump p2 is increased, the Q3 signal is changed to the “1” level at time t2.
Accordingly, the pump p3 is operated at the highest speed in the same manner as the pump p2 that has already been started.
[0030]
When the pump discharge pressure reaches the target pressure due to the additional operation of the pump p3, the state in which the three pumps p1 to p3 are continuously operated continues.
This state is maintained even after the time t3, and when the pump discharge pressure greatly exceeds the target pressure due to a decrease in pump demand at the time t4, the number of pumps to be reduced is reduced. Driving is performed.
[0031]
In this reduction operation, the starting machine under inverter control, that is, the operation of stopping the pump p1 is performed.
That is, the ON1 signal output to the inverter i1 corresponding to the pump p1 is turned off. Thereby, the inverter i1 is stopped.
[0032]
Further, the Q2 signal is set to “0”. As a result, the pump p2 that has been operated at the maximum speed until then is inverter-controlled by the inverter i2. Here, the operating frequency of the inverter i2 is controlled according to the analog value output from the D / A converter 11d.
[0033]
In this way, the pumps p2 and p3 are operated in parallel from the time t4, and the pump p1 is stopped.
Further, when the demand for water in the pump decreases, a process for stopping the pump p2 is performed at time t5.
[0034]
That is, the ON2 signal output to the inverter i2 corresponding to the pump p2 is turned off. Thereby, the inverter i1 is stopped.
Further, the Q3 signal is set to “0”. As a result, the pump p3 that has been operated at the maximum speed is inverter-controlled by the inverter i3. Here, the operating frequency of the inverter i3 is controlled according to the analog value output from the D / A converter 11d.
[0035]
As described above, when a plurality of pumps are operated in parallel, the first machine to be operated first is operated at a variable speed by the inverters i1 to i4, and the subsequent machine to be operated from the other is operated at the maximum speed. When the number of pumps is increased, the number of pumps to be increased is slowly increased until reaching the maximum speed at a change speed below a predetermined speed, and then operated at the maximum speed. When the number of pumps is decreased, the inverter is operated. The starter is stopped, and the pump that has been started first among the following is switched from maximum speed operation to variable speed operation so that it becomes a new starter, so the starter will not be driven for a long time. The operation time of each pump can be leveled.
[0036]
Further, since the operation of the four inverters i1 to i4 is controlled with only one D / A converter 11d, the CPU 11 can be made inexpensive.
Furthermore, the Q1 to Q4 outputs are switched to “1” during the expansion operation, but since the signals are input to the inverters i1 to i4 via the integrators 13a to 13d, the signal input to the inverter i2 changes smoothly. To do.
[0037]
Therefore, since the rotation speed of the pump operated by the inverters i1 to i4 changes at a change speed below a predetermined value and changes to the maximum speed, the fluctuation of the pump discharge pressure due to switching when the number of pumps is increased should be suppressed. Can do.
[0038]
【The invention's effect】
According to the first aspect of the present invention, in the variable speed pump device in which a plurality of pumps are driven at a variable speed by an inverter, the number of pumps to be operated is increased or the number of pumps to be decreased is decreased. It is possible to provide a variable speed pump operation method capable of reducing pressure fluctuation during operation and leveling the operation time of each pump.
[Brief description of the drawings]
FIG. 1 is a diagram showing a system configuration of a variable speed pump device according to an embodiment of the present invention.
FIG. 2 is a state diagram for explaining the operation of the embodiment;
FIG. 3 is a state diagram for explaining the operation of a conventional variable speed pump device.
[Explanation of symbols]
11 ... CPU (central processing unit),
12a to 12d: integrators.

Claims (1)

A variable speed pump operating method in which a plurality of pumps, each of which is controlled at variable speed by means of variable speed operation means, are operated in accordance with the demand for water to increase the number of units or decrease the number of units to be operated. In
When multiple pumps are operated in parallel, the first machine to be operated first is operated at variable speed by the variable speed operation means, and the other engine that is operated later is operated at the maximum speed to increase the number of pumps to be operated. When the number of units is increased, the number of pumps to be increased is slowly increased until reaching the maximum speed at a change speed below a predetermined speed, and then the maximum speed is operated. The operation method of the variable speed pump is characterized in that the pump that has been started first among the subsequent engines is switched from the operation at the maximum speed to the variable speed operation to be a new one.

Images