KR101586856B1 - Existing pump controller - Google Patents

Abstract

The present invention relates to a multi-stage feed pump control apparatus for a high-rise building, and more particularly, to a configuration including a PID (Pro- tional Integral Differential) Logic Controller and a DIOM (Direct Input Output Monitoring)
By using the water pump control device as described above, the remote operation and monitoring function is achieved, and overcurrent and overheating of the pump motor can be prevented.

Description

[0001] EXTING PUMP CONTROLLER [0002]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a water pump control apparatus, and more particularly to a multi-stage water pump control apparatus applied to a high-rise building.

The water supply system of apartment houses such as apartment buildings in the past is primarily used to raise tap water or ground water to a tank in a high-rise water tank on a high-rise roof, Water is also sent to the rooftop of the apartment building and then sent down again. This is not only unnecessary energy consumption, but also water pollution due to paint, rust, etc. coming out from the tank, .

In order to improve the existing water supply method for the above-mentioned high-rise apartment house, there is a method of directly supplying water to multiple houses by using a booster pump that pumps the principle of vacuum exhaust. However, this method is applied to a newly built apartment house, The booster pump and its system components must be newly purchased and installed. The booster pump used here is a pump of rated capacity produced for the purpose of control by the inverter, and the conventional pump can not be used. Also, due to the nature of the booster pump, It is necessary to separate them into two zones.

That is, when used in a high-rise building having 15 or more floors without distinguishing between the lower and upper floors, the pressure of the high-pressure high-pressure pump causes the breakage of the low-rise pipe, and the hydraulic pressure shortage occurs in the high- Therefore, the pressurized water supply method using the commercial inverter type booster pump can not use the existing water supply pump, and the water supply pipe can not use the existing pipe designed in the expensive water tank system, , It can be applied to a new apartment with a lot of cost, but it could not be applied to existing apartment house.

Therefore, it is not sent to water tank of high-priced water tank on the roof of high-rise apartment such as an apartment in water supply, but it is calculated by calculating the water supply pressure by water supply change caused by water supply change in the apartment house and using existing pump and pipe used in high water tank And a pressurized water supply device that directly supplies water to each household is required.

SUMMARY OF THE INVENTION An object of the present invention is to provide a water pump control apparatus capable of saving energy and stably supplying uncontaminated water.

In order to accomplish the above object, the feed pump control apparatus according to the present invention has a configuration as shown in FIGS. 1 to 16 of the present application.

In addition, the feedwater pump control device includes a PID (Propotional Integral Differential) logic controller and a DIOM (Logic Controller).

As described above, according to the feed water pump control apparatus of the present invention, the remote operation and monitoring functions are achieved, and the overcurrent and overheating of the pump motor can be prevented.

Further, according to the feed water pump control apparatus of the present invention, the idling prevention function and the correction of the sensor value can be performed to improve the life of the pump.

1 to 15 are block diagrams showing the construction of a water supply pump control device according to the present invention, respectively.
16 is a view for explaining a process of controlling a pump by a water pump control apparatus according to the present invention;

These and other objects and novel features of the present invention will become more apparent from the description of the present specification and the accompanying drawings.

Hereinafter, the configuration of the present invention will be described with reference to the drawings.

In the description of the present invention, the same parts are denoted by the same reference numerals, and repetitive description thereof will be omitted.

1 to 15 are block diagrams showing the construction of a water supply pump control apparatus according to the present invention, respectively.

The feedwater pump controller has a PID (Propotional Integral Differential) Logic Controller and a DIOM (Logic Controller).

That is, the basic concept of the PID control applied to the present invention is as follows.

P control adjusts the output frequency so that the output frequency and the deviation have a proportional relationship. I control corrects the output frequency by integrating the deviation that appears in the P control. D control differentiates the time deviation appearing in the I control, And corrects the frequency.

The proportional integration and differential operation are operations combining the three operations described above.

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The basic concept of DIOM control is as follows.

It handles all input / output signals,

It performs functions such as reading operation status and saving status.

The basic concept of operation in the present invention is as follows.

The PID logic controller and the DIOM logic controller communicate with RS232 and judge the status and operation status from time to time to maintain the optimum operation status.

Therefore, the present invention has a configuration as shown in Figs. 1 to 16.

Next, the operation according to the present invention will be described.

After the operation button is clicked, the output of the pump P1 starts to be generated. Since the minimum output of the control setting-inverter setting items is 40%, the pressure is immediately increased to 40% and then the maximum pressure increases to 100%.

 If the current pressure does not reach the set pressure even if the pump operates up to 100% of the maximum output. Control setting - Aux. Starting deviation according to auxiliary setting item -0.3 bar, ie auxiliary starting pressure = set pressure - auxiliary starting deviation = Since the subordinate subordinate condition is in the state of 5.0-0.3 = 4.7 bar, the pump P2 starts to operate immediately after the auxiliary start delay time and the pump P2 starts.

After the auxiliary start delay time

Auxiliary stop pressure = set pressure + auxiliary stop deviation = 5.0 + 0.2 = 5.1bar

And the pump P3 starts to work at the same time.

Next, the control process of the pump will be described with reference to Fig.

16 is a view for explaining the process of controlling the pump by the feed pump control apparatus according to the present invention.

Details of the sections in FIG. 16 are as follows.

1 section (pressure change 5.0 bar - > 4.7 bar reduction)

- all pumps stopped

2 sections (pressure change 4.7 bar -> 4.6 bar reduction) Friction compensation value 0.1 bar

- Main (Inverter control) Starting from the minimum output 40% set by the pump and rising to the maximum output 100%

Three sections (maintain or reduce pressure variation 4.6 bar)

- The point at which the auxiliary pump is ready to start with the discharge pressure less than the set pressure

- Aux pump start delay time interval

4 sections (maintain or reduce pressure change 4.6 bar)

- While the auxiliary pump (1) is activated, the main pump and the auxiliary pump are simultaneously operating

- Auxiliary pump start delay time interval of auxiliary pump (2)

5 sections (pressure change 4.6 bar-> 5.1 bar rise)

- Auxiliary pump start delay time interval of auxiliary pump (2)

- Main pump + Auxiliary pump 1 + Auxiliary pump 2 At the same time the operating state Pressure rising section

6 sections (maintain pressure change 5.1 bar)

- Main pump + Aux pump 1 + Aux pump 2 Status at the same time Maintain or maintain pressure

- the section where the main pump operation rate decreases

- Auxiliary pump 2 Section applied to auxiliary pump stop delay time

7 sections (maintain pressure change 5.1 bar)

- Main pump + auxiliary pump 1 is in operation at the same time and auxiliary pump 2 is stopped

- The interval in which the main pump operation rate falls below the stop rate

 - Auxiliary pump 1 Section applied to the auxiliary pump stop delay time

8 sections (maintain pressure change 5.1 bar)

- Main pump is in operation and auxiliary pump 1 is stopped

 - When the operation of auxiliary pump No. 1 is stopped,

9 sections (maintain pressure change 5.1 bar)

- Main pump in operation

- The interval in which the main pump operation rate falls below the stop rate

10 sections (pressure change 5.1 bar -> 5.0 bar reduction)

- Main pump in operation

- The interval applied to the stopping time as the main pump operation rate decreases to the minimum rate

- Friction compensation value (+0.1 bar) disappears as it reaches the minimum output.

11 sections (pressure change 5.0 bar -> 4.7 bar reduction)

- all pumps stopped

12 sections (pressure change 4.7 bar -> 5.1 bar increase) Friction compensation value 0.1 bar

- Main (Inverter control) Starting from the minimum output 40% set by the pump and rising to the maximum output 100%

13 sections (pressure change is maintained at 5.1 bar) Friction compensation value includes 0.1 bar

- Main (Inverter control) interval in which operation continues at a constant rate set by the pump

14 sections (pressure change is maintained at 5.1 bar) Friction compensation value including 0.1 bar

- The main (inverter control) interval in which the pump judges the pressure change through the output inspection cycle

15 sections (pressure change is maintained at 5.1 bar) Friction compensation value is 0.1 bar

 - The main (inverter control) pump determines that there is no pressure change through the output inspection cycle and reduces the output from the stopping rate to the minimum output state.

16 sections (pressure change 5.1 bar -> 5.0 bar reduction) Friction compensation value included 0.1 bar removed

- Main (inverter control) section where the pump stops

The following is an example of the section-by-section.

1. Basic condition contents

- [Operation setting] Setting pressure: 5.0 bar, upper limit pressure: 6.5 bar, lower limit pressure: 0.01 bar,

Starting deviation: -0.03 bar

- [Control Setting] -> [Inverter] Stop Time: 20 seconds, Minimum Output: 40%, Stop Rate: 70%

Output inspection cycle: 60 seconds, inspection tolerance: -0.01 bar

- [Control Setting] -> [Auxiliary Setting] Auxiliary Start Deviation: -0.04bar, Auxiliary Start Delay: 3sec

Auxiliary stopping deviation: 0.01bar, auxiliary stop delay: 3sec

- [Preferences] -> [Function Settings] Friction Compensation: 0.02bar

2. Explanation of main & auxiliary pump operation

2-1. Main (inverter control) pump starting point

- Applicable items: set pressure, start deviation, minimum output, friction compensation

- Current pressure starts at 4.7 bar (reason: set pressure - start deviation = 5.0 - 0.3 = 4.7 bar)

 2-2. Starting point of auxiliary pump

- Applicable items: auxiliary pump start deviation, auxiliary pump start delay

- Current pressure starts at 4.6 bar (reason: set pressure - start deviation = 5.0 - 0.4 = 4.6 bar)

However, even after reaching 4.6 bar, start-up after auxiliary pump start delay time

- If the auxiliary pump 1 is started but kept at 4.6 bar or less, the auxiliary pump start delay time

- After the auxiliary pump start delay time, the auxiliary pump 2 is started. Same conditions from 3 to 6

 2-3. Main (inverter control) Pump stop point

- Applicable items: stop ratio, stop time, minimum output, output inspection cycle, friction compensation

- If the current pressure is stopped at 5.0 bar but the inverter output is stopped after 20 seconds of stoppage time at the stop rate of 70% or less, but remains at the minimum output for 15 seconds,

- If the current pressure is equal to the set pressure, the inverter output is at a constant rate with the stop rate exceeding 70%. Output at a constant rate in the test cycle status Even if the output test cycle time is 60 seconds, To maintain the stop ratio at 70%. In the absence of pressure fluctuation, the output is slowly lowered and stopped at the minimum output and stop time.

2-4. Stop point of auxiliary pump

- Applicable items: auxiliary pump stopping deviation, auxiliary pump stop delay, stopping ratio

- After starting the auxiliary pump 1.2,

Setting pressure + auxiliary pump stopping deviation = 5 + 0.1 = 5.1bar

The auxiliary pump 3 stops after the auxiliary pump stop delay time and the auxiliary pump 2 stops after the auxiliary pump delay time. However, even if the auxiliary pump is at 5.0 bar and the main pump ratio falls below the stop rate, the pump stops in the order of 3 and 2 sequentially after the stop delay time of the auxiliary pump.

Although the present invention has been described in detail with reference to the above embodiments, it is needless to say that the present invention is not limited to the above-described embodiments, and various modifications may be made without departing from the spirit of the present invention.

Claims (5)

A multi-stage feed pump control apparatus for a high-rise building,
P controls the output frequency so that the output frequency and the deviation have a proportional relationship, the I control corrects the output frequency by integrating the deviation represented by the P control, and the D control changes the time deviation represented by the I control by the differential A PID (Propotional Integral Differential) logic controller that corrects the output frequency, and
A Direct Input Output Monitoring (DIOM) logic controller that governs all input / output signals and performs anomalous signal filtering, read operation status, and status storage,
Further comprising a main pump and a plurality of auxiliary pumps,
A plurality of auxiliary pumps are operated when the main pump fails,
The PID logic controller and the DIOM logic controller communicate with each other via RS232,
LCD displays Korean, English, and Chinese characters.
The Direct Input Output Monitoring (DIOM) logic controller includes first and second controllers separated from each other,
The first and second controllers are operated simultaneously, and each is used for a main pump and an auxiliary pump,
The operation setting of the feed pump is set to a set pressure of 5.0 bar, an upper limit pressure of 6.5 bar, a lower limit pressure of 0.01 bar, a starting deviation of -0.03 bar,
The main pump is now started at a pressure of 4.7 bar,
Wherein said auxiliary pump is started at a current pressure of 4.6 bar and starts to start after an auxiliary pump startup delay time even if it reaches 4.6 bar. delete delete The method according to claim 1,
Wherein the main inverter and the auxiliary inverter are provided corresponding to the main pump and the plurality of auxiliary pumps, respectively, and the auxiliary inverter is operated when the main inverter fails.
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