KR101900678B1 - Apparatus and operating method for Smart Pump Gate - Google Patents

Abstract

The present invention relates to a smart pump integrated gate and a driving method thereof, comprising: a water level detecting portion for collecting data regarding a canal of a drain pump station arranged with the pump integrated gate and water levels at the inside and the outside; a water level introduction amount Data Logger for storing data collected from the water level detecting portion; a gate control portion for controlling opening and closing of a pump gate by analyzing water levels of the water level detecting portion; and a pump gate control portion performing smart driving by controlling a pump driving mode by analyzing the data, causing no hunting and cavitation in the pump when driving the pump at a low water level by a pump control portion, and increasing a design capacity when a highest water level is raised. Thus, the gate can be pre-operated for prior preparation, and controls driving of the pump such that flooding in a river valley installed with the pump can be prevented, thereby capable of preventing casualties of citizens and asset loss.

Description

TECHNICAL FIELD The present invention relates to a smart pump integrated gate and a driving method thereof,

The present invention relates to a smart pump integrated type water gate, and more particularly, to a smart pump integrated type water gate, including a control problem corresponding to a sudden rise in the water level, a hunting problem caused by sudden water level fluctuation of the liner, The problem of cavitation caused by the pump driving in the low water level of the lagoon and the problem of the number of pumps that solve the overload problem when reaching the maximum level due to excessive inflow are solved. And a driving method thereof.

Generally, drainage and drainage pumping stations are disposed at the lower part of the basin in order to discharge the internal water including rainfall occurring in the drainage area to the outside. In general, drainage is performed through a drainage door. When the water level in the outside water rises, And when the water level in the domestic water supply rises to a certain level or more, the water discharge pump is driven to discharge the forced water to prevent flooding in the drainage area.

In more detail, the problem of the dimension of the drainage pumping station in the prior art is that the drainage is installed in a river, a river bank, a seawall or the like, and the drainage is usually opened to drain the upstream side water to the downstream side, Or typhoon, and the water level rises above a certain level due to the increase of the rainfall, the water gate is firstly lowered to close the waterway, thereby preventing the foreign water from flowing into the domestic water side. If the water gate is closed at this time, the inflow of the outside water can be blocked, but the domestic water can not be drained. If the rain continues, the domestic water level will rise and the low-lying housing or agricultural land without additional drainage will flood, .

Therefore, drainage pumping station or rainwater pumping station is installed to prevent flooding caused by submergence of houses and farmland in lowlands. Purchasing cost of drainage pumping station and drainage site, drainage pump construction work, construction work of drainage pump, (NIMBY), which is against the installation of drainage pumping stations by residents due to the odor generated from the collection of the drainage pumping station, as well as a huge budget due to the overhead crane, There is a problem that can not be done.

Especially, in low-lying areas around rivers in cities connected with coastal cities or large rivers, there is no room for installing drainage pumping stations because the city is already mature. In addition, the central government and municipal governments, It is impossible to realize the construction of drainage pumping station in response to the demand. Therefore, when typhoons that occur every year, or recent frequent occurrences of guerrilla intense rains or rainy seasons, sudden rise in the water level and simultaneous rise in the domestic water level, inevitably flood the lowlands, causing damage to people and major property damage every year .

Conventional technology determines the amount of inundation area and design rainfall, and accordingly, when the area of the pump and the lagoons is planned, the discharge amount (Q) and head (H) of the pump suitable for the pump are determined. As for the capacity (Q) and the head (H) of the installed pump, coping with the increased capacity (Q) that flows in a short period of heavy rain or heavy rain due to global warming and weather changes in the field, Unless it is changed, it is impossible to flood the lowlands inevitably, resulting in deaths of people and large property losses.

In order to solve such a problem of the conventional drainage pumping station, the present applicant has filed and filed a pumping-type sluice gate in which an opening is formed in the sluice gate body and the pump is integrated into the opening.

(Korean Unexamined Patent Publication No. 10-0497044 (Pump Integrated Type Hydraulic Gate and Driving Method), Korean Patent Registration No. 10-0712604 (Hinata Hydrology and Driving Method), Korean Patent Registration No. 10-1049099 water gate)).

In the structure of the prior art as described above, the pump is integrally incorporated into the rectangular plate-shaped hydrograph body to organically control the opening and closing of the water gate and the driving and stopping of the pump automatically when the inside / outside water level reaches the set water level, There are a number of things in common.

That is, the hydrological section, the volume section, the pump section, the water problem section described in the patent document 1 invention, and the hydrologic gate, the opening and closing section, the pump, the water problem section mentioned in the invention of patent document 2, , Switchgear, pump, water problem fishermen fall into this category or some of them.

According to the first and second inventions, the opening and closing of the water gate is closed when the water level is lower than the external water level, and the pump is turned off between the driving of the water level set in the closed state of the water gate and the stop water level ), The function of the number problem fisher is proposed.

However, these conventional techniques have the following problems.

1) Due to global warming and meteorological changes, rainfall patterns are localized and occur in the form of surveillance heavy rainfall, so that the rising speed of rainfall is very fast, whereas conventional technologies can not cope with it quickly. For example, in spite of being a large drainage pumping station where a large number of large-scale drainage pumps are arranged like a flooding accident occurred in Busan Metropolitan City in 2017, it is impossible to shut off the inside and outside water when the pump is driven with the gate open Since the back flow occurs, the pump is configured to operate sequentially only after the water gate is fully closed and the pump has reached the operating water level. This is because, although the actual water level of the lagoon has already exceeded the pump operation level, the integrated liquid type gates are not structured so as to rapidly close corresponding to the actual water level, so that the flooded water damage has occurred because the pump mounted on the water gate can not be driven. That is, the conventional technology has a structural problem in that flooding occurs due to the fact that the built-in pump type integrated gate is not constructed so that the water level rises rapidly due to various weather conditions such as heavy rainfall and typhoon.

2) In order to solve the problem that there is no space to install a conventional drainage pump station due to urbanization and advanced use, the drainage pumping station adopting the integrated pump type sluice gate integrates the pump into the water gate of the waterway, The problem could be solved. On the other hand, due to the increase in the design of rainfall intensity, the lower number of pumps to discharge the same amount of emissions is more economical, and the tendency of the discharge speed of the discharged water to increase due to the development of the mechanical technology, When a large amount of domestic water is discharged through the pump at a time, the water level near the pump suddenly drops. At this time, the water level meter which detects the water level detects the sudden drop level and stops the pump. The water level in the unstable lagoon rises sharply to the contrary, and hunting phenomenon occurs in which the pump is driven again by detecting the pump driving water level. This hunting phenomenon is caused by frequent starting and stopping of the pump due to the narrow water reservoir, which makes it impossible to perform a stable drainage operation and causes the pump and the motor to fail.

3) On the other hand, the drainage pumping station adopting the integrated pump type water gate is driven at a low level which suddenly deviates from the operation range of the pump in the unstable state due to the sudden change of the water level of the water discharge place due to the site restriction of the installation site, Cavitation phenomenon occurs which makes the normal operation of the pump impossible due to the severe vibration caused by the generation of the air bubble or the damage of the pump in the severe case. Most of the drainage pumps are driven for a long time even under abnormal operating conditions when the power is not shut off by an external program. Therefore, forced stopping due to abnormal signal detection due to overload of the pump motor and cavitation are the biggest causes of failure of the pump There is a maintenance problem that can not cope with flooding while the pump is being repaired in a manufacturing factory.

4) In the conventional technology, when the discharge amount (Q) and the head (H) of the pump suitable for the initial stage of the drain pump are determined and installed, the increased capacity And the operation of increasing the capacity of the pump to cope with the problem is that the low area is inundated due to the overload occurring unless the design assumption performed so far is changed.

Korean Registered Patent No. 10-0497044 Korean Patent No. 10-0712604 Korean Registered Patent No. 10-1049099

SUMMARY OF THE INVENTION It is an object of the present invention to solve the above-mentioned problems. It is an object of the present invention to provide a system in which the opening and closing of a pump can be pre-paired to cope with a rapid rise in the water level, The present invention provides a smart pump integrated type sluice gate and a method of driving the same, which can realize a pre-corresponding operation even when the rising speed of the rainfall rapidly increases.

It is another object of the present invention to provide a hunting system in which the pump and the motor are broken due to frequent start and stop of the pump by changing the driving of the pump so as to prevent the water level in the liquefied water tank, And to provide a smart pump integrated type water gate and a driving method thereof.

It is a further object of the present invention to provide a pump capable of preventing normal pump operation due to severe vibration due to bubbles generated between the blades of the pump by changing the drive of the pump so as to prevent the water level in the liquefied water tank, The present invention also provides a smart pump integrated type water gate and a driving method thereof that can prevent a cavitation phenomenon caused by a pump.

It is still another object of the present invention to provide a pump which is capable of increasing the pump drive speed and increasing the pump discharge amount and lifting amount to the design capacity when the water level of the liquefied water suddenly rises to the maximum water level The present invention provides a smart pump integrated type gate and a method of driving the same.

To achieve these and other advantages and in accordance with the purpose of the present invention, as embodied and broadly described herein, there is provided a smart pump integrated type water gate in accordance with the present invention, comprising: a pump gate installed in a water channel to open a water channel to naturally damp down and close internal water to the external water side to block reverse flow of external water; The present invention relates to a pump-integrated type gate which comprises a pump for forcedly draining the domestic water to the outside. The pump gate can be operated in advance when the flood level rises, preventing unstable operation and failure due to hunting and cavitation, A pump number problem fisher is provided so that the drive can be implemented even in the event of a torrential rain; The number of pump-related problems is determined by a rainfall amount sensing unit installed at a drainage pump station where the pump-integrated sluice gate is disposed to detect the amount of rainfall, and a drainage pump installed at the drainage pump station, A water level sensor for analyzing the data transmitted from the inside / outside water level sensing unit connected to the inside / outside water level sensing unit to control the opening / closing time and the opening / closing speed of the pump water; A water level inflow amount data logger connected to the sensing unit and storing the water level and inflow amount data collected by the internal water level sensing unit and the rainfall sensing unit, and a water level inflow amount data logger connected to the water level inflow data logger and the water problem fishery unit, And water problem The information about the hydrological shutdown information of the fishermen is collected and the operation mode of the pump is determined to control the number of driven pumps A pump operation mode control unit for controlling the flow rate Q and the head H of the internal water of the drainage pump by controlling the speed of rotation of the pump by varying the speed of the pump, A hunting control unit for preventing hunting caused by abrupt water level fluctuation of the liquefied water due to the low water level of the pump by the organic shift control of the pump control unit 2 and the cavitation occurring due to the sudden drop in the water level due to the low water level driving of the pump, And a cavitation control unit for preventing the shift control by the shift control; The pump operation mode control unit, and the pump control unit by analyzing data of the internal / external water level sensing unit and the water level inflow data logger.

Another feature of the smart pump integrated type water pump of the present invention is that a power unit is supplied from a power source unit, a PLC unit which detects and processes an analog signal and outputs a control signal, and a PLC unit connected to a PLC unit, An inverter unit connected to the control panel unit and operating the water gate opening and closing device and the pump and controlling the inverter, a hardware system unit connected to the inverter unit, and a control unit connected to the control panel unit, And a monitoring unit for monitoring or controlling the control status of the watercraft; The PLC unit includes a power source unit for managing the control power source, an analog detection unit for detecting the level information, the temperature and the rainfall amount, the calculation unit for performing various calculations of the PLC unit according to the program, A control signal input / output unit for outputting a control signal; The control panel unit includes a manual automatic control unit for selecting a manual automatic control of the control panel, a system control unit for switching to an automatic operation mode of the system when automatically selected, and a data display unit for displaying control results; The inverter section includes a hydrologic gate opening / closing device operation section for shifting the water gate opening / closing device, a pump operation section for shifting the pump, and an inverter control section for controlling the inverter; The hardware system section includes a pump gate 1, a pump gate 2, a pump 1, a pump 2, and an emergency generator for supplying emergency power during a power failure.

Another characteristic of the smart pump integrated type water canister of the present invention is that the pump number problem fisher is a water level sensing unit for collecting data on the suction and discharge water passages of the rainfall sensing unit and the drain pump station and the inside and outside water level of the pump water inlet, (L1 and L2) at two points above and below the lower section (Hi0) of the pump stoppage level (LWL) are continuously measured to obtain a measurement ascending velocity (Vd) reaching between the two points, If the measured elevation speed Vd is higher than the set elevation speed Ve, the number of problematic fishers instructs the pump to rapidly close the sluice gate in the preliminary corresponding operation. When the measured elevation speed Vd is higher than the set rising speed Ve, So as to implement the water level steepest descent control in response to the sudden rise in the water level of the lagoons due to heavy rain.

Another characteristic of the smart pump integrated type water pump of the present invention is that the hunting control unit analyzes the data of the water level inflow amount data logger and calculates the water level in the interval Hi1 between the pump driving water level PSL and the pump water level LWL (Q) and the head H of the pump are controlled by controlling the speed of rotation of the pump by controlling the speed of the pump to be interlocked with each other, in the case where the flow rate Q is lower than the hunting occurrence water level Hhd And the head H are controlled so as to prevent hunting caused by sudden fluctuation of the water level in the liner when the pump is driven.

Another characteristic of the smart pump integrated type water canister of the present invention is that the cavitation control unit analyzes the data of the water level inflow amount data logger and calculates the water level in the interval Hi1 between the pump driving water level PSL and the pump water level LWL The pump control section 2 controls the flow rate Q of the internal water and the head H in accordance with the speed change of the pump by controlling the speed of rotation of the pump. (Q) and the head (H), thereby preventing cavitation caused by low-level driving in the liner when the pump is driven.

According to another aspect of the present invention, there is provided a method for driving a smart pump integrated type water gate as set forth in claim 1, comprising the steps of: (S1) initializing a pump number problem fisher; (S10) of detecting the internal water level in the internal water level sensing unit for measuring the water level and the measurement times (T1, T2) at the lower two points (L1, L2) of the LWL, (S30) of calculating an internal water level increasing speed based on information sensed by the speed measuring unit, a step (S30) of estimating an inflow amount flowing into the liquefied water by an inflow volume predicting unit (S30) (S50) of data from the water level inflow data logger storing information sensed by the predictor in real time, and comparing the elevation speed (Vd) of the L1 and L2 level of the liquefied water with the set elevation speed (Ve) Vd) is fast (S60) of rapidly changing the closing start point of the pump water gate (25) of the right-hand side problematic fisherman and rapidly controlling the speed; And a water level rise control drive corresponding to the water level rise in advance.

In order to achieve the same object as mentioned above, the smart pump integrated type hydrologic drive method of the present invention includes the steps of initializing (S1) a pump number problem fisher, a water level of two lower points (L1 and L2) (S10) of sensing the level of the water level in the water level sensing unit for measuring the measurement times (T1, T2), (S30) of estimating the inflow amount flowing into the liquefied water by the inflow rate predicting unit (S50) of data from the water level inflow data logger storing the rainfall amount information and the information detected by the inflow amount predicting unit in real time; and a step S50 of measuring the flow rate of the domestic water when the measured water level Hid of the water lily is lower than the hunting occurrence water level A step S70 of controlling the flow rate Q and the head H by an organic speed change control in a pump control section 2 for controlling the speed of rotation of the pump by controlling the speed of rotation of the pump by controlling the speed of the pump Q and the head H, The pump is connected to the pump operating portion (Deceleration) of step S80; And hunting prevention driving caused by sudden fluctuation of the water level in the liner is made possible.

According to another aspect of the present invention, there is provided a method for driving a smart pump integrated type water gate as set forth in claim 1, comprising the steps of: (S1) initializing a pump number problem fisher; (S10) of detecting the internal water level in the internal water level sensing unit for measuring the water level and the measurement times (T1, T2) of the lower two points (L1, L2) of the LWL, (S50) of data from a water level inflow data logger for storing in real time the rainfall amount information detected by the rainfall amount sensing unit and the information sensed by the inflow amount prediction unit (S50) The pump control unit 2 performs the shift control of the flow rate Q of the internal water and the head H of the pump 40 by controlling the speed of rotation of the pump 40 when the flow rate Q is lower than the cavitation occurrence water level Hcd, (Q) and head (H) And a step (S70) which comprises the step (S80) for driving the pump to the speed change (deceleration) drive unit operating the pump portion in the pump control unit 2; And is configured to be capable of driving to prevent cavitation caused by driving of the pump in the low water level in the liner.

According to another aspect of the present invention, there is provided a smart pump integrated type hydrologic drive method for driving a smart pump integrated type hydrologic gate as set forth in claim 1, comprising the steps of: (S1) initializing a pump number problem fisher (S10) of detecting the internal water level in the internal water level sensing unit for measuring the water level and the measurement times (T1, T2) of the two lower portions (L1, L2) of the pump stop water level (LWL) (S50) of data in a water level inflow data logger for storing in real time the information detected by the rainfall amount sensing section and the information sensed by the inflow volume predicting section (S50) A step S90 of controlling the pump operation mode control unit to drive the entire pump disposed at the drive water level PSL2 or higher than the drive water level PSL2, a step S100 of detecting that the water level in the drainage tank reaches the maximum water level HiL, Wow , Controlling the flow rate Q and the head H by organic incremental control in a pump control 2 section for controlling the flow rate Q and the head H of the internal water by controlling the rotation speed R of the pump by intermittently controlling the speed of rotation of the pump (S80) of driving the pump in the pump control part (2) of the pump operation part of the inverter part (step S80); And the capacity of the entire pump is increased in the high water level in the ladle so that the flooding can be prevented.

The present invention as described above includes: 1) a water level detection unit for collecting data on a water channel and a water level of a drainage pumping station where a pump-integrated type water gate is disposed, a water level inflow data logger collected by the water level detection unit, And a controller for analyzing the data and controlling the pump operation mode and the pump controller to configure the pump number problem fisher to smartly drive the pump even when the low water level of the pump is operated. Therefore, it provides safe and economical effect to prevent the loss of lives and property of the people by preventing the flood of the watershed where the pump is installed by controlling the driving of the pump, making preventive operation of the water gate in advance.

(2) The present invention is also applicable to a case in which, even if the drainage pond of a drainage pumping station having a built-in pump-integrated water gate and the drainage area are difficult to secure the site due to the urbanization and advancement of the surrounding low- Providing hunting prevention means that optimizes the pump start and stop times while meeting the design criteria, the water level (Hid) of the ladle. Therefore, it prevents sudden change of the water level in unstable lakes, prevents frequent start and stop of the pump, prevents the motor from malfunction, enables stable operation of the drainage pumping station, and provides safety and economical effect to prevent disaster caused by flooding .

3) The present invention is characterized in that even if the drainage pond of a drainage pumping station having a built-in pump-integrated water gate and the drainage area are difficult to secure land due to the urbanization and upgrading of the surrounding low- The pump control unit is configured to control the discharge amount Q of the pump when the cavitation occurs due to the variation of the discharge amount Q and the head H by predicting the occurrence of the real time cavitation while satisfying the design criteria, And the like. Therefore, by preventing cavitation of the pump, it is possible to eliminate the cause of the biggest failure of the pump, to enable the operation of the drain pump station stably, and to provide safety and economical effect to prevent disaster caused by flooding.

4) Even if the drainage pumping station is set to discharge the amount Q and head H of the pump suitable for the pump, it is necessary to change the pump speed to cope with the increased capacity of the pump due to short- (Speed increase) control to increase the discharge amount (Q). Accordingly, it becomes possible to operate the water level elevation due to transient heavy rainfall, thereby providing safety and economical effect to prevent disaster caused by flooding.

5) The present invention has the safety and economical effect of enabling the monitoring and control operation of the drainage pumping station in the monitoring unit and preventing disaster caused by flooding.

1 is a side view of a smart pump integrated type water purifier according to the present invention,
2 is a plan view and a front view showing a first embodiment of a smart pump integrated type water softener according to the present invention
FIG. 3 is a block diagram of a pump number problem control unit for a smart pump integrated type water pump according to the present invention.
4 is a block diagram showing the control flow of the pump number problem fisher unit of the smart pump integrated type water pump according to the present invention
5 is a block diagram showing a control detailed flow of the pump number problem fisher unit of the smart pump integrated type water pump according to the present invention
6 is an explanatory view showing the inside / outside water level of the smart pump integrated type water pump, the starting and stopping positions of the respective pumps according to the present invention,
7 is a control flowchart showing the water level rise control in the smart pump integrated type watercraft according to the present invention.
8 is a control flowchart showing the hunting control of the smart pump integrated type water pump according to the present invention.
9 is a control flowchart showing cavitation control of the smart pump integrated type water pump according to the present invention.
FIG. 10 is a control flow chart showing the maximum water level control at the time of heavy rain in the smart pump integrated type watercraft according to the present invention

A construction method of the smart pump integrated type water can be described as follows.

BRIEF DESCRIPTION OF THE DRAWINGS The advantages and features of the present invention, and how to accomplish it, will become apparent with reference to the embodiments described in detail below with reference to the accompanying drawings.

However, the present invention is not limited to the embodiments described below, but may be implemented in various other forms, and these embodiments are not intended to be exhaustive or to limit the invention to the precise forms disclosed, Is provided to fully convey the scope of the invention to those skilled in the art, and the invention is only defined by the definition of the claims.

In the following description, well-known functions or constructions are not described in detail to avoid obscuring the subject matter of the present invention.

2 is a plan view and a front view showing a first embodiment of a smart pump integrated type water pump according to the present invention, and FIG. 3 is a cross-sectional view of a smart pump integrated type water pump according to a first embodiment of the present invention. Fig. 7 is a block diagram of a pump number problem control unit for a smart pump integrated type water pump according to the present invention.

FIG. 4 is a block diagram showing a control flow of the pump number problem fisher unit of the smart pump integrated type water pump according to the present invention, FIG. 5 is a block diagram showing a detailed flow of control of the pump number problem water pump unit of the smart pump integrated type water pump according to the present invention And FIG. 6 is an explanatory view showing the internal and external water levels of the first embodiment of the smart pump integrated type water pump according to the present invention, the starting and stopping positions of the respective pumps, and FIG. Fig.

FIG. 9 is a control flowchart showing cavitation control of a smart pump integrated type water pump according to the present invention, and FIG. 10 is a flowchart showing a control flow of a smart pump integrated type pump according to the present invention, This is a control flowchart showing the maximum water level control at the time of heavy rain of the watercraft.

1 to 3, the smart pump integrated type water gate of the present invention is installed between the door frames 15 of the hydrological structure 14 which distinguishes between the water channel 10 and the outer water channel 12, A plurality of openings 16 passing through the front and rear faces of the hydrology main body for controlling the level of the domestic water and preventing the inflow of external water by opening and closing the door frame 15 are formed by the water gate opening and closing device 24, The pump 40 for forcedly draining the domestic water to the outside water is flange-coupled to the transverse shaft or the vertical shaft. A flap valve 22 for shutting off the reverse flow to the inside water side of the outside water is connected to the outside water side of the pump 40 and the flap valve 23 is connected to the water gate opening / closing device 24 And the opening / The internal structure of the hydrological structure 14 is provided with a rainfall gauge 30, a domestic water level meter 31 and an external water level meter 32 to send an internal and external water level sensing signal to the pump water questioner 100, Is configured to organically control the water gate opening / closing device 24 and the pump 40 as shown in Fig.

The pump-integrated sluice gate 20 comprises a pump sluice 25, a pump 40, a sluice gate 24, and a flap valve 22.

The pump gate 25 is composed of a thin plate element such that the water gate body formed to control the water level of the domestic water and to prevent the foreign water from flowing into the internal water side is vertically raised and lowered along the door frame 15 to open and close. This hydrologic main body has a smaller rigidity (k) or mass (m) than the pump 40 and reflects the frequency of the pump 40 and the load of the pump as a concentrated load, Resonance occurs when the natural frequency? N and the difference in the frequency of the pump 40 occurring when the pump 40 integrated with the hydrologic main body are close to each other are close to each other in the (first to fifth) modes. Therefore, it is desirable to arrange and arrange the hydrograph body member so as to have rigidity and rigidity of the hydrograph body so that such resonance does not occur.

1 to 2, the pump 40 may be mounted on the pump gate 25 in a horizontal axis or on a not shown axis, and may be installed in a pump control unit 120 It is preferable to configure the pump so as to be able to control the number of driven pumps, the flow rate or the head by the number of pump revolutions.

The water gate opening and closing device 24 preferably includes a driving unit, a decelerating unit, a self-weighting lower unit, an automatic converting unit, a manual driving unit, and a double spindle unit. In particular, it is preferable that the transmission portion is configured to be capable of driving the opening / closing speed of the pump water gate 25 at an increased speed or a normal speed double at the water problem portion 110 described later.

In the first embodiment, the pump-integrated type of the water gate 20 includes pump gates 25, G1, G2 and G3, pumps 40, P1, P2 and P3, a water gate switching device 24, A1, A2 and A3, 1 and Fig. 2, the present invention is not limited to this arrangement, and a pump pump 25 may be installed in each pump water gate 25, (Hereinafter referred to as the second embodiment), or a plurality of the pump sluices 25 may be provided, and the number of the pump sluices 25 is preferably also configured according to the discharge amount of the pump 40 to be discharged.

3 to 10, the pump number problematic unit 100 includes a PLC unit 300, a control panel unit 400, and an inverter unit 500, And a pump controller 120 for controlling the pump 40 and the pump controller 120, respectively.

The PLC unit 300 of the pump number problem unit 100 includes a power unit 310 that manages power of the PLC unit 300 and supplies power to the pump number problem unit 100, 31, and an arithmetic processing unit 330 for performing arithmetic processing by a program, and a control signal input / output unit 340 for inputting and outputting a control signal.

The control panel unit 400 includes a manual automatic control unit 410 that directly controls the operation or selects an operation automatically, a system operation unit 420 that operates the system, and a data display unit 430 that displays various data do. The inverter unit 500 includes a water gate opening and closing device operation unit 510 for operating the shift of the water gate opening and closing device 24 and a pump operation for operating the speed change (deceleration or speed increase) Unit 520, and an inverter control unit 530 for controlling the inverter. The information for analyzing and controlling the system is transmitted to the remote site through the monitoring unit 700 and controls the pump gates 1 and 2 610 and 620 and the pumps 1 and 2 630 and 640, It is preferable to configure the emergency generator 650 to operate when the power source of the emergency generator 650 is not available.

As shown in FIGS. 3 to 6, the water level determining unit 110 determines the water level (Hod, Hid) sensed by the internal and external water level sensing units 160 and 165, the water level control level Hgc, (Hod> Hid or Hod> Hgc) and open (Hod <Hid or Hod <Hgo) according to the outside and outside water conditions by comparing the water level (Hgo).

The pump control unit 120 includes a pump control unit 121, a pump control unit 122 and a pump operation mode control unit 190. As shown in FIGS. 4 and 10, 31 and 32 are switched by the internal and external water level sensing units 160 and 165 as digital signals. The measurement start time T1 of the lower portion L1 of the lagoon 13 of the lagoon 13 and the measurement end time T2 of the upper portion L2 of the L1 are detected in real time and the internal level measurement rise speed Vd is calculated by the internal level measurement unit 170 by the following equation (Formula 1), compares the calculated value Vd with the set ascending speed Ve, and sends it to the inflow amount predicting unit 180. [

(식 1)

(Equation 1)

L2 is the water level at the lower point of the lagoon LWL, m is the water level at the lower point L2 of the lagoon LWL. M is the time at which L2 is reached.

On the other hand, the inflow amount predicting unit 180 calculates the measured inflow amount Qd by the equation (2), compares the calculated value Qd with the set inflow amount Qe, .

(식2)

(Equation 2)

Here, A: area (B x L) of the ladle 13, and m²

The digital rainfall amount information of the rainfall amount sensing unit 140 is transmitted to the water level inflow amount data logger 150 and is configured to be stored as data of the water level inflow amount determination of the water level 13.

The set inflow amount Qe can be estimated by setting the inflow amount Qe in the same manner as in the above equation 2 and setting the water level rise speed to the predicted ascent speed at the time of design.

Therefore, the water problem determining unit 110 analyzes the data of the internal and external water level sensing units 160 and 165 and the water level inflow data logger 150 to determine whether the internal water level rise speed Vd is higher than the set rising speed Ve Upon receipt of the speed information, the water question processor 110 instructs the pump number question processor 100 to perform the corresponding operation at a high speed at the closing speed of the water gate opening / closing device 24, The problem fisher 110 is configured so as to correspond to the pump number problem fisher 100 in a double manner so as to normally drive the closing speed of the water gate opening / closing device 24. [

Further, the pump operation mode control unit 190 of the pump control unit 120 collects the water level and flow rate information of the water level inflow data logger 150 and the water gate close information of the water questioning unit 110 and calculates the operation mode of the pump 40 The relationship between the flow rate (Q), the number of revolutions (R), and the head (H) of the pump is determined based on the pump control 1 part 121 for controlling the number of driven pumps (N = 1,2,3 ... n) The pump control unit 122 is configured to control the pump control unit 122 to adjust the pump control unit 122 such that the pump control unit 122 is raised or lowered using a known similar rule as shown in the following equation (Formula 3) .

- (식3)

- (Equation 3)

Here, Q2 and Q1 are the discharge amounts of the pump m3 / min, R2 and R1 are the rotational speeds of the pump rpm, H2 and H1 are the head, m, and subscript 1 indicates the flow rate Q1, And the subscript 2 is the flow rate Q2, the number of revolutions R2, and the head H2 of the state to be controlled.

Accordingly, in order to increase or decrease the flow rate Q, the rotation speed R or the head H of the pump may be adjusted, and the flow rate Q or the rotation speed R may be adjusted to adjust the head H .

The pump operation mode control unit 190 determines that the pump operation mode control unit 190 has already determined that the pump water level 25 has already reached the water level problem unit 110 because the measurement outside water level Hod is higher than the measured domestic water level Hid or higher than the water level close water level Hgc, As shown in FIG.

A driving method of the smart pump integrated type water can be described as follows.

 First, as shown in Figs. 1, 6 and 7, in the case of the second embodiment of the installation of one pump, the set value is reset so as to organically control the pump integrated type water gate 20 in the pump number problem fishery 100 (S1). Then, when the water level information generated at the pump stop water level LWL or less of the water level 13 is obtained and the water level rises rapidly, the analogue detection unit 320 detects the water level of the water level L1 and the water level L2 of the water level 13 , The water level sensing unit 160 senses L1, L2, T1, and T2 as a digital signal (S10). The flow rate measuring unit 180 measures the inflow rate Qd of the inflow ladle 13 by measuring the inflow rate Qd of the inflow ladle 13 by measuring the inflow rate Qd After the information of the inflow amount measuring step S30 and the water level and inflow amount information of the lagoon 13 reflecting the rainfall amount sensed by the rainfall sensing unit 140 are stored in the water level inflow data logger 150 at step S50, The information on the overall water level and the inflow amount is calculated by the operation processing unit 330 of the PLC unit 300 to determine whether the water level in the water lane 13 is rapidly rising or not. When it is determined that the water level is rapidly rising, (S60) in which the water gate opening / closing operation part 510 is operated in proportion to the rising speed.

2 and 6, in the case of the first embodiment of the installation of three pumps, since the measured internal level Hid is higher than PSL3, the water levels L1, L2, and L3 sensed by the internal water level sensing unit 160, Since the pump sluices 25 and G1 are already closed and the pump sluices 25 and G1 have already been ascertained as in the second embodiment and the pump sluices 25 and G1 are closed, The process is skipped and is in a closed state.

Next, as shown in Figs. 1, 6 and 8, in the case of the second embodiment in which one pump is installed, the pump-integrated siphon door 20 in the siphon 13 is moved from the pump sophisticated questioner 100 to the siphon 13 The inflow amount measurement step S30 for measuring the inflow amount Qd in the inflow amount measurement unit 180 and the inflow amount information for the inflow point 13 reflecting the rainfall amount sensed by the rainfall amount sensing unit 140 The total level and the inflow amount information are calculated by the calculation processing unit 330 of the PLC unit 300 in the step S50 of storing the water level inflow amount in the data logger 150 and the water level Hid in the measurement of the water level 13 is Hi1 and (H), a hunting occurrence water level Hhd is determined in the water level range of Hi2, and when the hunting water level Hhd is determined to be the hunting occurrence water level Hhd, the relationship (Q), the rotation number R, To the inverter unit 500 in accordance with the control signal of the step S80 of requesting the pump control unit 122 to perform the shift control in the step S80, Thereby shift the pump operating unit 520. Thus, the rotation speed R of the pump is decelerated to reduce the head H change. When the pump 40 is driven by the behavior of the liquefied paper 13 at the time of driving the pump, the water level of the liquefied paper 13 rises sharply irregularly when a large amount of domestic water is discharged through the pump 40 at a time. The water level meter 31 sensing the water level in such a state senses the sudden drop of the water level below the pump stop level LWL1 to stop the pump 40 or P1, The water level in the unstable water tank 13 rises rapidly and the pump 40 or P1 is driven again by detecting the pump driving water level PSL so that the hunting phenomenon, It is possible to prevent the irregular behavior of the water level by decelerating the number of rotations R of the flow paths 40 and P1 to induce a change in the flow amount Q and the head H level.

 On the other hand, as shown in Figs. 2, 6, and 8, in the first embodiment of installing three pumps, since the measured internal water level Hid is higher than PSL3, All the pumps 40, P1, P2, and P3 do not generate hunting even when driven by a full load.

1, 6 and 8, in the case of the second embodiment of the installation of one pump, the pump-integrated siphon door 20 in the siphon 13 is connected from the pump sophisticated questioner 100 to the siphon 13 The information on the inflow amount measurement step S30 for measuring the inflow amount Qd in the inflow amount predicting unit 180 and the information on the level and inflow amount information on the lane level 13 reflecting the rainfall amount sensed by the rainfall amount sensing unit 140 And storing the water level inflow amount in the data logger 150 (S50). In this step 150, the information of the overall water level and inflow amount is calculated by the operation processing unit 330 of the PLC unit 300. [ When the water level Hid in the measurement of the ladle 13 is judged to be the cavitation occurrence water level Hcd by judging the cavitation water level Hcd in the water level range of Hi1 and Hi2 shown in Fig. 6, In accordance with the control signal of the step S80 to request the shift control of the pump control unit 122 in the relationship S70 of the flow Q, the rotation speed R and the head H, The pump operation section 520 of the inverter section 500 shifts the speed of rotation R.

By reducing the number of revolutions R of the pump 40, P1 to reduce the change of the flow rate Q and the head H, the driving water level PSL1 of the pump 40, P1 at the low level areas Hi1 & The stop level LWL1 can be stably maintained and the pump 40 or P1 can be stably driven at the low level Hcd at which cavitation occurs.

On the other hand, as shown in Figs. 2, 6 and 8, in the first embodiment of installing three pumps, since the measured internal water level (Hid) is PSL3, it is in the upper part of Hi1 and Hi2 ranges Cavitation does not occur even if the pumps 40, P1, P2, and P3 are driven by a full load.

5 to 8, in the case of the second embodiment of the installation of one pump and the second embodiment of the installation of three pumps, hunting and cavitation are carried out only when the measured internal level (Hid) is lower than Hi1 & Hi2 Occurs. In this case, all the pumps 40, P1, P2, and P3 are driven by full load.

As shown in Figs. 2, 6 and 10, in the case of the second embodiment in which one pump is installed or the first embodiment in which three pumps are installed, if the measured internal level Hid is within Hi3, (40, P1, P2, P3) are driven by a full load. If the measured level Hid reaches HiL, the pump control unit 122 is set to the relationship (S70) between the flow rate Q, the number of revolutions R, and the head H in accordance with the above equation (Formula 3) The speed R of the pumps 40, P1, P2, and P3 is shifted (increased) by the pump operating section 520 of the inverter section 500 in accordance with the control signal of step S80, It is possible to discharge the increased flow Q by the concentrated rain.

10: Domestic waterway 12: Outside waterway
13: lagoons 14: hydrological structures
15: door frame 16: opening
20: Pump integrated type
22: flap valve 23: spindle
24: Water gate opening / closing device 25: Pump gate
30: Rainfall 31: Domestic water level
32: External gauge 40: Pump
100: Pump number problem Fisher 110: Water problem fisher
120: Pump control part 122: Pump control part 1
123: Pump control part 2 140: Rainfall amount sensing part
150: Water level inflow data logger 160: Internal water level sensing unit
1 65: external water level sensing unit 170: internal water level measuring unit
180: Inflow Prediction Unit 190: Pump Operation Mode Control Unit
200: Hunting control unit 210: Cavitation control unit
300: PLC unit 310: Power unit
320: Analog detecting unit 330:
340: Control signal input / output unit 400: Control panel unit
410: manual automatic control unit 420: system control unit
430: Data display unit 500: Inverter unit
510: Water gate opening and closing device operating part 520:
530: inverter control unit 600: hardware system unit
610: Pump hydrology 1 620: Pump hydrology 2
630: Pump 1 640: Pump 2
650: Emergency generator 700: Monitoring section
Hod: water level outside measurement Hid: water level inside measurement
HiL: Inner maximum water level Hgc: Water level
Hgo: Water level opening set level Hi1: Section (PSL1-LWL1)
Hi2: interval (PSL1-PSL2) Hi3: interval (PSL2-PSL3)
LWL: pump stop level LWL1: P1 pump stop level
LWL2: P2 pump stop level LWL3: P3 pump stop level
PSL: pump start level PSL1: P1 pump start level
PSL2: P2 pump start level PSL3: P3 pump start level
L1: Water level at the L1 point of the lagoons L2: Level at the L2 point of the lagoons
T1: L1 level measurement time T2: L1 level measurement time

Claims (9)

A pump water gate 25 installed in the water channel 10 to open the water channel 10 to naturally flow and close the water to the outside water to block the reverse flow of the outside water and a pump water gate 25 integrally coupled to the pump water gate 25, In the pump-integrated water gate (20) comprising the pump (40) for forced drainage,
The pump number problem fisher 100 is provided to enable the pump gate 25 to be proactively operated when the water level rises, to prevent unstable operation and failure due to hunting and cavitation, and to drive even when the water level reaches a maximum water level ;
Pump Number Problem The fisher 100,
A rainfall sensing unit 140 installed at a drain pump station where the pump integrated type sluice gate 20 is disposed to sense a rainfall amount,
An internal and external water level sensing unit (160, 165) installed at the drainage pump station for collecting data on the suction and discharge water passages of the drainage pump station and the inside and outside water level of the pump water gate (25)
A water quality controller 110 connected to the external and external water level sensing units 160 and 165 to analyze the data transmitted from the internal and external water level sensing units 160 and 165 to control the opening and closing times and the opening and closing speeds of the pump water gate 25,
A water level inflow data logger 150 connected to the water level sensing unit 160 and the rainfall sensing unit 140 to store the water level and inflow data collected by the internal level sensing unit 160 and the rainfall sensing unit 140,
The control unit 150 is connected to the water level inflow data logger 150 and the water question processor 110 to collect the water level and inflow volume information of the water level inflow data logger 150 and the water door close information of the water question block 110, The pump control section 121 for determining the mode and controlling the number of drives of the pump 40 and the flow rate Q and the head H of the internal water of the ladle 13 to the speed R of the pump 40 A pump operation mode control unit 190 including a pump control unit 122 for controlling the pump operation mode and controlling the operation of the pump operation mode,
A hunting control unit 200 for preventing hunting caused by abrupt water level fluctuation of the liner 13 due to low-level driving of the pump 40 by the organic shift control of the pump control unit 122,
A cavitation controller 210 for preventing cavitation caused by a sudden drop in the level of the ladle 13 due to low-level driving of the pump 40 by the organic shift control of the pump controller 2,
A PLC unit 300 for supplying power from the power unit 310 and detecting and processing an analog signal and for inputting / outputting a control signal; and a controller 300 connected to the PLC unit 300, An inverter unit 500 connected to the control panel unit 400 and controlling the inverter by operating the gate control unit 24 and the pump 40, A hardware system unit 600 and a monitoring unit 700 connected to the control panel unit 400 to monitor or control the control status of the pump integrated type sluice 20 at a remote place;
The inverter unit 500 includes a water gate opening / closing operation unit 510 for shifting the water gate opening and closing device 24, a pump operation unit 520 for shifting the pump 40, and an inverter control unit 530);
The pump operation mode control unit 190 and the pump control unit 120 by analyzing the data of the internal and external water level sensing units 160 and 165 and the water level inflow data logger 150,
When the water level reaches a set water level in a state where the water gate main body is closed by integrating the pump into the square plate type water gate main body, the water problem portion 110 is organically controlled so as to automatically open and close the water gate and drive and stop the pump;
The inverter unit 500, the inverter control unit 530, and the pump operation unit 520;
The cavitation occurrence water level Hcd is judged in the water level range of the cavitation occurrence water level section Hi1 and Hi2 in the water level 13 measured by the water level 13 and it is judged that the cavitation water level Hcd is generated, The rotation speed R of the pump 40 or P1 is controlled by the pump operation of the inverter unit 500 according to the control signal for controlling the speed of the pump control unit 122 in the relationship of the rotation speed R, (520). &Lt; / RTI &gt;
Equation :

Q2 and Q1 are the discharge amounts of the pump, m3 / min,
R2 and R1 are the rpm of the pump,
H2, H1 is the head, m
The pump number problematic unit (100) according to claim 1,
A PLC unit 300 for supplying power from the power unit 310 and detecting and processing an analog signal and for inputting / outputting a control signal; and a controller 300 connected to the PLC unit 300, An inverter unit 500 connected to the control panel unit 400 and controlling the inverter by operating the gate control unit 24 and the pump 40, A hardware system unit 600 and a monitoring unit 700 connected to the control panel unit 400 to monitor or control the control status of the pump integrated type sluice 20 at a remote place;
The PLC unit 300 includes a power supply unit 310 for managing the control power supply, an analog detection unit 320 for detecting the level information, the temperature, the amount of rainfall, and the like, A processing unit 330, and a control signal input / output unit 340 for processing input and output (I / O) control signals;
The control panel unit 400 includes a manual automatic operation unit 410 for selecting manual automatic operation of the control panel, a system operation unit 420 for switching to the automatic operation mode of the system when automatically selected, And a data display unit (430)
The inverter unit 500 includes a water gate opening / closing operation unit 510 for shifting the water gate opening and closing device 24, a pump operation unit 520 for shifting the pump 40, and an inverter control unit 530);
The hardware system unit 600 includes a pump gate 1 610, a pump gate 2 620, a pump 1 630, a pump 2 640 and an emergency generator 650 for supplying an emergency power source during a power failure Features a smart pump integrated water gate.
The pump number problematic unit (100) according to claim 1,
The water level sensing units 160 and 165 collect data on the intake and discharge water passages of the rainfall sensing unit 140 and the drain pump station and the inside and outside water level of the pump water gate 25, And the measured elevation velocities Vd reaching between the two points are compared with the set elevation velocities Ve to determine the measured elevation velocities When the water level Vd of the pump 40 is higher than the set rising speed Ve, the number question processor 110 instructs the pump water gate 25 to be quickly closed by a preliminary corresponding operation, , And the control means is configured to be driven at a water level as low as the water level so as to realize the water level steepness control in advance in response to the sudden rise in the water level of the drainage paper (13) due to heavy rain.
The hunting control unit (200) according to claim 1,
The data of the water level inflow data logger 150 is analyzed and if the measured water level Hid is lower than the hunting water level Hhd in the interval Hi1 between the pump operation level PSL and the pump water level LWL, The flow rate Q and the head H of the pump 40 are controlled by the pump control unit 122 for controlling the flow rate Q and the head H of the pump 40 by controlling the speed of rotation of the pump 40, To prevent hunting caused by rapid fluctuation of the water level in the liner (13) when the pump (40) is driven.
2. The apparatus according to claim 1, wherein the cavitation control unit (210)
When the measured internal level Hid is lower than the cavitation generated water level Hcd in the interval Hi1 between the pump operation level PSL and the pump stop level LWL by analyzing the data of the water level inflow data logger 150, The flow rate Q and the head H are controlled by the organic speed change control in the pump control 2 section 122 which controls the flow rate Q and head H of the pump 40 by controlling the speed of rotation of the pump 40, To thereby prevent cavitation caused by low-level driving in the lage (13) when the pump (40) is driven.
A method for driving a smart pump integral type gate of claim 1,
A step (S1) of initializing the number-of-pump-in question unit 100,
A step S10 of detecting the internal water level in the internal water level sensing unit 160 for measuring the water level and the measurement times T1 and T2 at the two lower portions L1 and L2 of the pump stop water level LWL of the water main body 13,
(S20) of calculating a water level rise speed based on the information sensed by the internal water level sensing unit (160) and the information sensed by the internal water level speed measuring unit (170)
A step S30 of predicting an inflow amount flowing into the ladle 13 by the inflow amount predicting unit 180,
(S50) of data in a water level inflow data logger (150) that stores in real time the rainfall information detected by the rainfall sensing unit (140) and the information sensed by the inflow prediction unit (180)
The L1 and L2 water level rise velocities Vd of the water lakes 13 are compared with the set rising velocities Ve and the start point of closing the pump water gates 25 of the number problem fishes 110 when the measured upward velocity Vd is fast (S60) of rapidly changing the speed of the vehicle;
And the water level rise control operation is made possible in advance in response to the water level rise.
A method for driving a smart pump integral type gate of claim 1,
A step (S1) of initializing the number-of-pump-in question unit 100,
A step S10 of detecting the internal water level in the internal water level sensing unit 160 for measuring the water level and the measurement times T1 and T2 at the two lower portions L1 and L2 of the pump stop water level LWL of the water main body 13,
A step S30 of predicting an inflow amount flowing into the ladle 13 by the inflow amount predicting unit 180,
(S50) of data in a water level inflow data logger (150) that stores in real time the rainfall information detected by the rainfall sensing unit (140) and the information sensed by the inflow prediction unit (180)
A pump for interlocking and controlling the flow rate Q and the head H of the internal water by controlling the speed of rotation R of the pump 40 when the measured water level Hid of the water level 13 is lower than the hunting occurrence water level Hhd, A step S70 of controlling the flow rate Q and the head H by the organic shift control in the control unit 122,
(S80) driving the pump (40) from the pump control 2 part (122) to the deceleration of the pump operating part (520) of the inverter part (500);
And the hunting prevention drive caused by sudden fluctuation of the water level in the liner (13) is made possible.
A method for driving a smart pump integral type gate of claim 1,
A step (S1) of initializing the number-of-pump-in question unit 100,
A step S10 of detecting the internal water level in the internal water level sensing unit 160 for measuring the water level and the measurement times T1 and T2 at the two lower portions L1 and L2 of the pump stop water level LWL of the water main body 13,
A step S30 of predicting an inflow amount flowing into the ladle 13 by the inflow amount predicting unit 180,
(S50) of data in a water level inflow data logger (150) that stores in real time the rainfall information detected by the rainfall sensing unit (140) and the information sensed by the inflow prediction unit (180)
The flow rate Q and the head H of the internal water are controlled to change the rotation speed R of the pump 40 so as to be interlocked with each other when the measured internal level Hid of the ladle 13 is lower than the cavitation generated water level Hcd A step S70 of controlling the flow rate Q and the head H by the organic shift control in the pump control unit 122,
(S80) driving the pump (40) from the pump control 2 part (122) to the deceleration of the pump operating part (520) of the inverter part (500);
And the pump (40) is driven in a low-water-level state in the ladle (13) so as to prevent cavitation caused by driving the pump (40).
A method for driving a smart pump integral type gate of claim 1,
A step (S1) of initializing the number-of-pump-in question unit 100,
A step S10 of detecting the internal water level in the internal water level sensing unit 160 for measuring the water level and the measurement times T1 and T2 at the two lower portions L1 and L2 of the pump stop water level LWL of the water main body 13,
A step S30 of predicting an inflow amount flowing into the ladle 13 by the inflow amount predicting unit 180,
(S50) of data in a water level inflow data logger (150) for storing in real time the rainfall information detected by the rainfall sensing section (140) and the information detected by the inflow prediction section (180)
A step S90 of controlling the pump operation mode control unit 190 to drive the entire pump 40 disposed at the pump water level PSL2 or higher than the pump water level PS3 in the water level 13,
A step S100 of detecting that the water level in the ladle 13 reaches the maximum water level HiL,
The pump control section 122 for controlling the flow rate Q of the domestic water and the head H so as to perform the speed change control of the rotation speed R of the pump 40 is controlled by the organic speed increasing control to control the flow rate Q and the head H (Step S70)
(S80) driving the pump (40) from the pump control 2 part (122) to the increased speed of the pump operating part (520) of the inverter part (500);
Wherein a capacity of the entire pump (40) is increased in a high level state in the ladle (13) so as to be able to drive to prevent flooding.

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