KR20220081834A - Smart deepwater pump control system - Google Patents

Abstract

According to a feature of the present invention, the deep well pump 110 is installed in the deep well 10 and pressurizes the water flowing into the suction port 111 during the pumping operation and discharges it to the discharge port 112 to which the drain pipe 20 is connected; a discharge flow rate sensing unit 120 installed in the drain pipe 20 and outputting discharge flow rate sensing data for detecting water flowing therein; a water storage quantity detection unit 130 installed at the bottom of the heart chamber 10 and outputting water storage quantity detection data sensing the stored water; Control module 140 for controlling the discharge flow rate while driving and controlling the deep heart pump 110 in an inverter control method according to an operation input signal or a programmed item, and transmitting the received discharge flow rate detection data and low water quantity detection data through a communication network (140) ; a management server unit 150 for collecting and storing discharge flow rate detection data and low water quantity detection data received by being connected to a network through the communication network for each control module 140; And by receiving the detection data and the storage amount detection data for each control module 140 collected from the management server unit 150, and displaying it on the screen window 162 so that the discharge flow rate and the storage amount of each heart chamber 10 can be monitored A smart cardiac pump control system including a manager terminal 160 is provided.

Description

Smart deep pump control system {SMART DEEPWATER PUMP CONTROL SYSTEM}

The present invention relates to a smart heart pump control system, and more particularly, it is possible to adjust the discharge flow rate of water discharged to the outside by controlling the drive control of the deep heart pump installed in the heart well, and an administrator or user located in a remote place can control the discharge flow rate and stored water volume of the heart well. It relates to a smart cardiac pump control system that can be monitored.

In general, the deep well pump control system is installed inside the deep well and sucks stored water during pumping operation and discharges it to the drain pipe. It consists of a control module that drives and controls the pump.

However, in the conventional deep well pump control system, it is inconvenient to read the discharge flow rate gauge or water level gauge displayed on the control module in order to check the flow rate discharged from the heart well or to check the water level of the heart well. In addition, in government offices that have to manage each heart in an integrated way, it is necessary to maintain the current status by checking the data such as the discharge flow rate or water storage through the manager of each heart, and there is a problem in that it is difficult to check the amount of change in real time.

Registered Patent Publication No. 10-1800972 (2017.11.17), water intake pump control system.

The present invention was created to solve the above problems, and an object of the present invention is to control the driving control of the deep well pump installed in the deep well to control the discharge flow rate of water discharged to the outside, and an administrator or user located in a remote place can control the discharge flow rate of the deep well. And to provide a smart cardiac pump control system that can monitor the amount of water.

In addition, another object of the present invention is to provide a smart heart pump control system that can monitor incidental data such as message usage, ambient humidity and temperature, wind direction, etc. it is in

According to a feature of the present invention, the deep well pump 110 is installed in the deep well 10 and pressurizes the water flowing into the suction port 111 during the pumping operation and discharges it to the discharge port 112 to which the drain pipe 20 is connected; a discharge flow rate sensing unit 120 installed in the drain pipe 20 and outputting discharge flow rate sensing data for detecting water flowing therein; a water storage quantity detection unit 130 installed at the bottom of the heart chamber 10 and outputting water storage quantity detection data sensing the stored water; Control module 140 for controlling the discharge flow rate while driving and controlling the deep heart pump 110 in an inverter control method according to an operation input signal or a programmed item, and transmitting the received discharge flow rate detection data and low water quantity detection data through a communication network (140) ; a management server unit 150 for collecting and storing discharge flow rate detection data and low water quantity detection data received by being connected to a network through the communication network for each control module 140; And by receiving the detection data and the storage amount detection data for each control module 140 collected from the management server unit 150, and displaying it on the screen window 162 so that the discharge flow rate and the storage amount of each heart chamber 10 can be monitored A smart cardiac pump control system including a manager terminal 160 is provided.

According to another feature of the present invention, the manager terminal 160 transmits an operation input signal for adjusting the setting state or operation state of the cardiac pump 110 to the control module 140 through the management server unit 150, and , the control module 140 provides a smart cardiac pump control system, characterized in that it drives and controls the cardiac pump 110 to operate according to a manipulation input signal received from the manager terminal 160 .

According to another feature of the present invention, a plurality of control modules 140 are grouped for each set zone to form a local group (LG1 to LG4), and the management server unit 150 is, within each local group (LG1 to LG4). The included local management server 151 that collects discharge flow rate detection data and low water amount detection data output from each control module 140, and each control module 140 collected by signal connection with each local management server 151 and a central management server 152 for receiving and storing the discharge flow rate detection data and the low water amount detection data, wherein the manager terminal 160 is connected to the central management server 152 and each local group (LG1 to LG4) (10) There is provided a smart deep pump control system, characterized in that monitoring the discharge flow rate and the stored water amount.

According to another feature of the present invention, it is mounted on the deep heart pump 110, the deep heart pump 110 is a sensor unit 170 including a vibration sensor for detecting the vibration generated when the pumping operation; further comprising , the control module 140 stores the failure prediction reference data prepared based on the vibration detection state that appears when a failure occurs, and compares the failure prediction reference data with the vibration detection data received from the vibration detection sensor to the deep heart pump 110 There is provided a smart cardiac pump control system, characterized in that predicting the possible failure of the display unit 142 and the manager terminal 160 to act as a notification.

According to another feature of the present invention, a plurality of sprinklers arranged to be spaced apart in a set fire possible place to spray the supplied water to the surroundings (182); a branch pipe 183 connected between the drain pipe 20 and each sprinkler 182 to transport water for sprinkling; and a solenoid valve 184 installed for each branch pipe 183 to open and close a pipeline according to a control signal from the control module 140; the control module 140 is received from the water storage sensor 130 The solenoid valve ( 184) is provided with a smart cardiac pump control system, characterized in that driving control.

According to another feature of the present invention, the water storage quantity detecting unit 130 is a water pressure sensor disposed at the bottom of the heart 10 and outputting an electrical detection signal according to a change in water pressure, and the control module 140 is a low water quantity detecting unit A smart deep well pump control system is provided, characterized in that the low water quantity determination reference value data for each water pressure sensing data of 130 is stored, and the low water quantity detection data stored in the heart well 10 is calculated based on the currently received water pressure sensing data.

According to another feature of the present invention, the lateral water flow generated as water is sucked into the suction port 111 of the deep well pump 110 by being placed upright in the form of enclosing the low water quantity sensing unit 130 in the deep well 10 . The downwater flow generated by the water flowing into the deep well 10 is horizontally arranged in the upper center of the tube body 191 and the upper center of the tube body 191, which blocks the The first downward water flow blocking plate 193 blocking the sensor 130 from being applied, and the inner wall 192 of the tube portion 191 extending laterally from the inner wall 192 of the tube portion 191 toward the center of the horizontal The second downward water flow blocking plate is disposed to block the downward water flow generated by the water flowing into the deep well 10 from being applied to the water storage volume detecting unit 130, and a plurality of second downward water flow blocking plates are vertically spaced along the inner wall 192. There is provided a smart cardiac pump control system, characterized in that it further comprises; a water flow blocking unit 190 including (195).

According to another feature of the present invention, the tube body 191 is provided such that the height (h1) of the upper end is relatively higher than the height (h2) of the suction port 111 of the deep heart pump 110 (h1 > h2) At the ends of the first downflow blocking plate 193 and the second downflow blocking plate 195, guide bending portions 194 and 196 for guiding the downward water flow by bending upward in a rounded shape are formed, respectively. A smart cardiac pump control system is provided.

According to another feature of the present invention, the water flow blocking unit 190 is horizontal between the second downward water flow blocking plate 195 disposed at the lowest end in the tubular body 191 and the water storage volume detecting unit 130 . There is provided a smart cardiac pump control system, which is arranged and made of a porous material and further comprises a micro-water flow blocking unit 197 for blocking the micro-water flow passing through the second down-flow blocking plate 195 .

As described above, according to the present invention,

First, the deep well pump 110 is installed in the deep well 10 and pressurizes water flowing into the suction port 111 while pumping, and discharges it to the discharge port 112 to which the drain pipe 20 is connected, and the discharge flow rate detection unit 120 is installed in the drain pipe 20 and outputs discharge flow rate sensing data that senses water flowing therein, and the water storage quantity detection unit 130 is installed at the bottom of the deep well 10 and detects stored water storage data output, and the control module 140 controls the discharge flow rate while driving and controlling the deep heart pump 110 in an inverter control method according to an operation input signal or a programmed matter, and transmits the received discharge flow rate detection data and low water quantity detection data to the communication network. and the management server unit 150 collects and stores the discharge flow rate detection data and the low water amount detection data received by network connection with a plurality of control modules 140 through the communication network for each control module 140, The manager terminal 160 receives the detection data for each control module 140 and the low water amount detection data collected from the management server unit 150, and a screen window ( 162), the discharge flow rate of water discharged to the outside can be controlled by driving and controlling the deep well pump installed in the heart well, and an administrator or user located in a remote place can monitor the discharge flow rate and water storage of the heart well.

Second, the manager terminal 160 transmits an operation input signal for adjusting the setting state or operation state of the cardiac pump 110 to the control module 140 through the management server unit 150, and the control module 140 ) controls the operation of the deep heart pump 110 according to the operation input signal received from the manager terminal 160, so that the manager can easily adjust the operation and setting state of the heart pump even if the manager is located in a remote place separated from the heart location. have.

Third, a plurality of control modules 140 for each set zone are grouped to form a local group (LG1 to LG4), and the management server unit 150 is included in each local group (LG1 to LG4) to form each control module 140 . ), the local management server 151 that collects the discharge flow rate detection data and the low water amount detection data output from the ), and the discharge flow rate detection data and the low water amount detection for each control module 140 that are signal-connected to each local management server 151 and collected and a central management server 152 for receiving and storing data, wherein the manager terminal 160 is connected to the central management server 152 to determine the discharge flow rate and By monitoring the water storage volume, there is an advantage in that it is possible to check the location or real-time changes of the heart in real time in a government office that has to manage each heart in an integrated way.

Fourth, the deep heart pump 110 is mounted on the heart pump 110, the sensor unit 170 including a vibration sensor for detecting the vibration generated when the pumping operation; further comprising, the control module 140 The failure prediction reference data prepared based on the vibration detection state that appears when a failure occurs is stored, and the failure prediction data is compared with the vibration detection data received from the vibration detection sensor to predict the possibility of failure in the deep heart pump 110, By the notification operation on the display unit 142 and the manager terminal 160, it is possible to replace and maintain the deep heart pump with time before the failure occurs, so that the convenience of the manager can be promoted.

Fifth, a plurality of sprinklers 182 are arranged to be spaced apart in a set fire possible place to spray supplied water, and a branch pipe 183 is connected between the drain pipe 20 and each sprinkler 182 to spray water. The solenoid valve 184 is installed for each branch pipe 183 to open and close the pipeline according to the control signal of the control module 140, and the control module 140 is The solenoid valve so that the water is sprayed from each sprinkler 182 at the set watering time when the current stored water amount of the hearth 10 is determined using the received water storage detection data, and the currently determined water storage amount exceeds the set surplus standard water storage amount value By driving control 184, it is possible to prevent a fire in advance by periodically spraying a place where a fire can occur during a dry period, and there is an advantage that it can be used as a means of supplying fire water in case of a fire.

Sixth, the low water amount detection unit 130 is a water pressure sensor that is disposed at the bottom of the heart 10 and outputs an electrical detection signal according to a change in water pressure, and the control module 140 is a water pressure detection data of the low water amount detection unit 130 . In comparison with detecting the water level with a conventional sensor that detects and operates by buoyancy, foreign substances are detected by calculating the low water amount detection data stored in the heart chamber 10 based on the water pressure detection data currently received by storing the water level determination standard data for each star. It is possible to prevent a detection error or non-operation while being caught in a part (moving part) in advance, and reliable detection data can be secured.

Seventh, the water flow blocking unit 190 is disposed upright in the form of enclosing the low water quantity sensing unit 130 in the deep well 10 , and is generated while water is sucked into the suction port 111 of the deep well pump 110 . The pipe unit 191 that blocks the water flow from being applied to the water storage sensor 130, and the pipe unit 191 is horizontally disposed in the upper center of the pipe unit 191, and the downward water flow generated by the water flowing into the deep well 10 is A first downward water flow blocking plate 193 blocking the water storage volume detection unit 130 from being applied, and a form extending laterally from the inner wall 192 of the tube body 191 toward the center of the tube body 191 It is horizontally arranged and blocks the downward water flow generated by the water flowing into the deep well 10 from being applied to the water storage sensor 130, and blocks the second downward water flow in which a plurality of them are vertically spaced apart along the inner wall 192. By including the plate 195, it is possible to prevent an error in water pressure sensing due to the water flow occurring in the heart well 10, thereby providing more reliable sensing data.

Eighth, the tubular part 191 is provided such that the height (h1) of the upper end is relatively higher (h1 > h2) than the height (h2) of the suction port 111 of the deep heart pump 110 . Even if a lateral water flow occurs while water is sucked into the suction port 111, it is possible to minimize the water flow applied to the upper end of the tube body 191, and the first downflow blocking plate 193 and the second downflow blocking plate ( 195) has guide bent portions 194 and 196 bent upward in a rounded shape, respectively, to guide the downward water flow upward, thereby greatly reducing the downward water flow applied to the water storage sensor 130 .

Ninth, the water flow blocking unit 190 is horizontally disposed between the second downward water flow blocking plate 195 disposed at the bottom of the tube body 191 and the low water quantity sensing unit 130 and is made of a porous material. By disposing the water flow blocking unit 197 , it is possible to block the fine water flow passing through the second downward water flow blocking plate 195 , thereby preventing a detection error due to the downward water flow.

1 is a schematic diagram showing a state in which a cardiac pump and a control module are connected according to a preferred embodiment of the present invention;
2 is a schematic diagram showing the configuration of a smart cardiac pump control system according to a preferred embodiment of the present invention;
3 is a schematic diagram showing a state in which the management server unit is signal-connected to each control module according to a preferred embodiment of the present invention;
4 is a schematic diagram showing a configuration of a management server unit comprising a local management server and a central management server according to a preferred embodiment of the present invention;
5 is a block diagram for explaining a failure prediction method of a cardiac pump according to a preferred embodiment of the present invention;
6 is a schematic diagram for explaining a fire prevention function through a smart deep pump control system according to a preferred embodiment of the present invention;
7 is a side view showing a state in which a water flow blocking unit is installed inside the heart chamber according to a preferred embodiment of the present invention;
8 is a side view showing the configuration of a water flow blocking unit according to a preferred embodiment of the present invention;
9 is a side view for explaining the operating principle of blocking the downward water flow through the first downflow blocking plate and the second downflow blocking plate according to a preferred embodiment of the present invention;
10 is a side view showing another configuration of a second downflow blocking plate according to a preferred embodiment of the present invention.

The objects, features and advantages of the present invention described above will become more apparent through the following detailed description. Hereinafter, preferred embodiments of the present invention will be described based on the accompanying drawings.

The smart heart pump control system according to a preferred embodiment of the present invention can control the discharge flow rate of water discharged to the outside by driving and controlling the heart pump 110 installed in the heart well 10, and an administrator or user located in a remote place can discharge the heart As a system capable of monitoring the flow rate and the stored water amount, as shown in FIGS. 1 and 2 , the deep heart pump 110 , the discharge flow rate detection unit 120 , the storage water quantity detection unit 130 , the control module 140 , the management server It includes a unit 150 and a manager terminal 160 .

First, the deep well pump 110 is installed in the deep well 10 as a means for pulling up water stored in the deep well 10 and providing a water pressure necessary to supply it to the outside, and is pumped according to the control signal of the control module 140 . While operating, the water flowing into the suction port 111 is pressurized and discharged through the discharge port 112 to which the drain pipe 20 is connected.

The discharge flow rate detection unit 120 is installed in the drain pipe 20 as a means for detecting the flow rate of water discharged to the drain pipe 20 by the deep well pump 110 and detects the discharge flow rate sensing the water flowing therein. Data is generated and output to the control module 140 . As the discharge flow rate sensing unit 120 , the flow meter 121 may be used, the water pressure meter 122 may be used, or the flow meter 121 and the water pressure meter 122 may be used together. The discharge flow rate detection unit 120 is signal-connected to the control module 140 in a wired or wireless communication method to transmit the detected discharge flow rate detection data, and this discharge flow rate detection data is necessary for driving control of the cardiac pump 110 . used as basic data.

In addition, the discharge flow rate detection unit 120 may output discharge flow rate data calculated using an electrical detection signal that a voltage value is divided according to a change in the flow rate of discharged water and a diameter value of the drain pipe 20 , and the electrical It is also possible to output only the voltage value of the detection signal. That is, the discharge flow rate detection data may be discharge flow rate data or voltage value data. In the case of the voltage value data, the control module 140 uses the received voltage value data and the diameter value of the drain pipe 20 to determine the discharge flow rate. Value data can also be calculated.

The water storage detection unit 130 is installed in the bottom of the deep well 10 as a sensing means for providing basic data required to measure the water storage amount of the water stored in the deep well 10, and generates and controls the water storage amount detection data to detect the stored water. output to the module 140 .

Here, the water storage detection unit 130 may output an electrical detection signal in which a voltage value is divided according to the amount of stored water and a low water amount value data calculated using the diameter value of the heart 10, and the voltage of the electrical detection signal You can also print only values. That is, the low water quantity detection data may be low water quantity value data or voltage value data. In the case of the voltage value data, the control module 140 uses the received voltage value data and the diameter value of the heart 10 to transmit the low quantity value data. can also be calculated.

The control module 140 is a control means for driving and controlling the deep heart pump 110, and adjusts the discharge flow rate while driving and controlling the deep heart pump 110 in an inverter control method according to an operation input signal or a programmed matter, The received discharge flow rate detection data and low water quantity detection data are transmitted to the management server unit 150 through a communication network. The Internet control method is a method of controlling acceleration/deceleration by changing the inverter output voltage and frequency supplied to the pump motor 114 (refer to FIG. 5) provided in the deep heart pump 110, and it is possible to precisely control the discharge flow rate. .

The management server unit 150 collects and stores the discharge flow rate sensing data and the low water quantity sensing data received by network connection with a plurality of control modules 140 through a communication network to each control module 140 .

The manager terminal 160 receives the discharge flow rate detection data and the low water quantity detection data for each control module 140 collected from the management server unit 150 to monitor the discharge flow rate and the water storage amount of each heart chamber 10 . It is displayed in the window 162 .

The deep heart pump 110, discharge flow rate detection data, low water amount detection data, control module 140, management server unit 150, and manager terminal 160 drive and control the deep heart pump installed in the heart well through the combination of the external It is possible to control the discharge flow rate of water discharged to the system, and the administrator or user located in a remote location can monitor the discharge flow rate and stored water volume of the heart.

In addition, the manager terminal 160 transmits an operation input signal for adjusting the setting state or operation state of the cardiac pump 110 to the control module 140 through the management server unit 150, and the control module 140 ) controls the operation of the deep heart pump 110 according to the operation input signal received from the manager terminal 160, so that the manager can easily adjust the operation and setting state of the heart pump even if the manager is located in a remote place separated from the heart location. have.

On the other hand, as shown in FIG. 4 , a plurality of control modules 140 are grouped for each set zone to form local groups LG1 to LG4, and the management server unit 150 is located within each local group LG1 to LG4. The included local management server 151 that collects discharge flow rate detection data and low water amount detection data output from each control module 140, and each control module 140 collected by signal connection with each local management server 151 and a central management server 152 for receiving and storing the discharge flow rate detection data and the low water amount detection data, wherein the manager terminal 160 is connected to the central management server 152 and each local group (LG1 to LG4) By monitoring the discharge flow and water storage in (10), there is an advantage in that it is possible to check the location or real-time changes of the heart in real time in a government office that needs to manage each heart in an integrated way.

In addition, as shown in FIG. 5, it is mounted on the deep heart pump 110 and further includes a sensor unit 170 including a vibration sensor for detecting vibration generated when the deep heart pump 110 is pumped. The control module 140 stores the failure prediction reference data prepared based on the vibration detection state that appears when a failure occurs, and compares the vibration detection data received from the vibration detection sensor with the failure prediction reference data to the deep heart pump 110 By predicting the possibility of a failure and a notification operation using the display unit 142 and the manager terminal 160, replacement and maintenance are possible with time before the deep heart pump breaks down, so it is possible to increase the convenience of the manager.

In addition, as shown in FIG. 6 , a plurality of sprinklers 182 are spaced apart from each other in a set fire possible place to spray supplied water, and the branch pipe 183 is the drain pipe 20 and each sprinkler 182 ) to transfer water for sprinkling, solenoid valve 184 is installed for each branch pipe 183 to open and close the pipeline according to the control signal of the control module 140, and the control module 140 is The current water storage amount of the hearth 10 is determined using the water storage amount detection data received from the water storage amount detection unit 130, and when the currently determined water storage amount exceeds the set surplus standard water amount value, each sprinkler 182 at the set watering time By driving and controlling the solenoid valve 184 so that water is sprayed, it is possible to prevent a fire in advance by periodically spraying it to a place where a fire can occur during a dry period, and there is an advantage that it can be used as a means of supplying fire-fighting water in case of a fire.

On the other hand, the low water amount detection unit 130 is a water pressure sensor that is disposed at the bottom of the heart 10 and outputs an electrical detection signal according to a change in water pressure, and the control module 140 is a water pressure detection data of the low water amount detection unit 130 . In comparison with detecting the water level with a conventional sensor that detects and operates by buoyancy, foreign substances are detected by calculating the low water amount detection data stored in the heart chamber 10 based on the currently received water pressure detection data by storing the water level determination standard data for each star. It is possible to prevent a detection error or non-operation while being caught in a part (moving part) in advance, and reliable detection data can be secured.

Here, as shown in FIGS. 7 to 9 , the water flow blocking unit 190 is disposed upright in the form of enclosing the low water quantity sensing unit 130 in the deep well 10 , and the suction port of the deep well pump 110 ( 111) to block the lateral water flow generated as water is sucked from being applied to the low water amount detection unit 130, and horizontally arranged in the upper center of the tubular body 191 to the inside of the deep well (10). The first downward water flow blocking plate 193 blocking the downward water flow generated by the inflow water from being applied to the low water amount detection unit 130, and the pipe body 191 from the inner wall 192 of the pipe body 191 It is horizontally arranged in a form extending laterally toward the center of the deep well 10 and blocks the downward water flow generated by the water flowing into the inside of the deep well 10 from being applied to the water storage sensor 130, and along the inner wall 192, a plurality of By including the second downward flow blocking plate 195 spaced up and down, it is possible to prevent an error in water pressure detection due to the water flow occurring within the heart well 10, thereby providing more reliable sensing data.

In addition, as shown in FIG. 8 , the tubular part 191 has a height h1 of the upper end relatively higher than a height h2 of the suction port 111 of the deep heart pump 110 (h1 > h2). Even when a lateral water flow occurs while water is sucked into the suction port 111 of the deep well pump 110, it is possible to minimize the water flow applied to the upper end of the tube body 191, and the first downward water flow blocking plate 193 and At the end of the second downflow blocking plate 195, guide bent portions 194 and 196 bent upward in a rounded shape are formed, respectively, to guide the downward water flow upward, thereby significantly reducing the application of the downward water flow to the low water quantity sensing unit 130. can be reduced

In addition, the water flow blocking unit 190 is horizontally disposed between the second downward water flow blocking plate 195 disposed at the lowest end in the tube body 191 and the low water quantity sensing unit 130 and is made of a porous material. By disposing the water flow blocking unit 197 , it is possible to block the fine water flow passing through the second downward water flow blocking plate 195 , thereby preventing a detection error due to the downward water flow.

In addition, a plurality of the second downflow blocking plates 195 are spaced up and down along the inner wall 192 of the tube body 191 as shown in FIG. 8 and may be alternately disposed at both positions, as shown in FIG. As described above, a plurality of pieces may be arranged in a ring shape along the circumference of the inner wall 192 so as to be spaced apart from each other up and down.

The present invention described above is not limited by the above-described embodiments and the accompanying drawings, and it is common in the art to which the present invention pertains that various substitutions, modifications and changes can be made within the scope without departing from the technical spirit of the present invention. It will be clear to those who have knowledge.

10...heart 20...drain pipe
110...Deep heart pump 111...Suction port
112...Discharge port 120...Discharge flow rate sensor
130...low water quantity detection unit 140...control module
150....Management Server Unit 151...Local Management Server
152...Central Management Server 160...Administrator Terminal
170...Sensor 182...Sprinkler
183... branch pipe 184... solenoid valve
190...water flow cutoff part 191...pipe body part
193...First downflow blocking plate 195...2nd downflow blocking plate
197...Microwater flow blocker

Claims (7)

a deep well pump 110 that is installed in the deep well 10 and pressurizes water flowing into the suction port 111 while pumping and discharges it to the discharge port 112 to which the drain pipe 20 is connected;
a discharge flow rate sensing unit 120 installed in the drain pipe 20 and outputting discharge flow rate sensing data for detecting water flowing therein;
a water storage quantity detection unit 130 installed at the bottom of the heart chamber 10 and outputting water storage quantity detection data sensing the stored water;
Control module 140 for controlling the discharge flow rate while driving and controlling the deep heart pump 110 in an inverter control method according to an operation input signal or a programmed item, and transmitting the received discharge flow rate detection data and low water quantity detection data through a communication network (140) ;
a management server unit 150 for collecting and storing discharge flow rate sensing data and low water quantity sensing data received by being connected to a network through the communication network for each control module 140; and
The discharge flow rate detection data and the low water quantity detection data for each control module 140 collected from the management server unit 150 are received and displayed on the screen window 162 so that the discharge flow rate and the stored water amount of each hearth 10 can be monitored. A smart cardiac pump control system comprising; a manager terminal 160 to.
The method according to claim 1,
The manager terminal 160 transmits an operation input signal for adjusting the setting state or operation state of the cardiac pump 110 to the control module 140 through the management server unit 150,
The control module (140) is a smart cardiac pump control system, characterized in that the driving control so that the cardiac pump (110) is operated according to the operation input signal received from the manager terminal (160).
The method according to claim 1,
A plurality of control modules 140 are grouped for each set zone to form a local group (LG1 to LG4),
The management server unit 150,
A local management server 151 that is included in each local group (LG1 ~ LG4) and collects the discharge flow rate detection data and the low water amount detection data output from each control module 140, and;
It includes a central management server 152 for receiving and storing the discharge flow rate detection data and the low water amount detection data for each control module 140 collected by signal connection with each local management server 151,
The manager terminal 160 is connected to the central management server 152 to monitor the discharge flow rate and water storage amount of each heart well 10 for each local group (LG1 to LG4).
The method according to claim 1,
It is mounted on the deep heart pump 110, the deep heart pump 110, a sensor unit 170 including a vibration sensor for detecting the vibration generated when the pumping operation; further comprising,
The control module 140 stores the failure prediction reference data prepared based on the vibration detection state that appears when a failure occurs, and compares the vibration detection data received from the vibration detection sensor with the failure prediction reference data to the deep heart pump 110. A smart cardiac pump control system, characterized in that predicting the possibility of a failure and alerting the display unit 142 and the manager terminal 160 .
The method according to claim 1,
A plurality of sprinklers 182 that are arranged to be spaced apart in a set fire possible place and spray the supplied water to the periphery;
a branch pipe 183 connected between the drain pipe 20 and each sprinkler 182 to transport water for sprinkling; and
It further includes; solenoid valve 184 installed for each branch pipe 183 to open and close the pipe according to the control signal of the control module 140;
The control module 140 determines the current water storage amount of the heart 10 by using the water storage amount detection data received from the water storage amount detection unit 130, and when the currently determined water storage amount value exceeds the set surplus reference water quantity value, the set watering time Smart deep heart pump control system, characterized in that the driving control of the solenoid valve (184) so that each sprinkler (182) water is sprayed in the.
The method according to claim 1,
The low water amount detection unit 130 is a water pressure sensor that is disposed at the bottom of the heart 10 and outputs an electrical detection signal according to a change in water pressure,
The control module 140 stores the low water amount determination reference value data for each water pressure detection data of the water pressure detection unit 130, and calculates the low water amount detection data stored in the heart chamber 10 based on the currently received water pressure detection data, characterized in that Smart deep pump control system.
7. The method of claim 6,
It is placed upright in the form of enclosing the water storage volume detecting unit 130 in the deep well 10, and the lateral water flow generated when water is sucked into the suction port 111 of the deep well pump 110 is applied to the water level detecting unit 130. A tubular body portion 191 to block it from falling, and
A first downflow blocking plate 193 that is horizontally disposed in the upper center of the tube body 191 and blocks the downwater flow generated by the water flowing into the deep well 10 from being applied to the water storage sensor 130 . and,
The downward water flow generated by the water flowing into the heart chamber 10 is horizontally arranged in a form extending laterally from the inner wall 192 of the tube portion 191 toward the center of the tube portion 191 is a low water quantity detection unit ( 130), and a water flow blocking unit 190 including a second downward water flow blocking plate 195, a plurality of vertically spaced apart along the inner wall 192; Smart characterized in that it further comprises Deep heart pump control system.

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