KR20160072461A - Deepwater Pump Multi-Function Controller - Google Patents

Abstract

The present invention relates to a multifunctional deep-well pump controller to control a vertical type deep-well pump to supply underground water to the ground. The multifunctional deep-well pump controller protects a motor by blocking application of overcurrent caused by overload, prevents idling of the pump in a case of a low-water level, and controls the pump to be turned on or off by measuring a current amount during the idling of the pump when there is a shortage of the underground water.

Description

Deepwater Pump Multi-Function Controller}

The present invention relates to a multifunctional heart pump controller for controlling a vertical heart pump for supplying groundwater to the ground, and more particularly, to a motor control device for protecting a motor by cutting off the application of an overcurrent due to an overload, The present invention relates to a multifunctional heart pump controller capable of controlling the ON / OFF of a pump by measuring the amount of current at idling of the pump when the groundwater is insufficient.

Groundwater is widely used for agricultural water for domestic use, cleaning, etc., agriculture for agricultural fields such as rice paddy fields, industrial use for factory facilities, drinking water such as drinking water, liquor and beverage, agricultural water for all- And water for river maintenance using effluent water.

Such groundwater is drilled at a deep depth below the ground surface, and the groundwater flowing into the drilling hole is pumped to the ground and stored in a water tank provided on the ground. At this time, a vertical pump, which is a vertical turbine pump, is used to pump groundwater to the ground. The heart pump is turned ON / OFF according to the water level of the ground water or the water tank installed on the ground, and a controller for controlling the water pump must be provided.

The above-mentioned conventional heart pump controller is connected to an electrode-level sensor provided in the groundwater tank to detect the presence of groundwater and controls the operation of the heart pump, or receives a signal from a measurement sensor that senses the water level of the water tank, . In addition, the controller is provided with an LED display device that can recognize the operation of the pump by the user, and is provided with an alarm device capable of visually presenting the groundwater level, the water level inside the water tank, and the operation of the pump.

In the conventional controller, when the pump driving motor is continuously operated in the absence of water, the motor is not cooled by water, so that the motor can easily fail due to overheating of the motor, and the electrode sensor is eroded by the ground water, And when the wire connecting the water level sensor and the controller is disconnected, the pump can not be operated.

Therefore, it is necessary to develop a multifunctional heart pump controller that does not require corrosion or replacement of the electrode level sensor for measuring the level of groundwater, and prevents malfunction of the pump driving motor and damage due to overcurrent.

1. Korean Patent Laid-Open No. 10-2011-0070254 'Pump Operation Control Device' (Published on June 24, 2011) 2. Korean Patent Laid-Open No. 10-2010-0100168 'Digital Pump Automatic Control System' (Published on September 15, 2010) 3. Korean Patent Laid-Open Publication No. 10-2000-0036351 'Wireless automatic level control system' (Published on July 2, 2000)

SUMMARY OF THE INVENTION The present invention has been conceived in order to solve the above-described problems, and it is an object of the present invention to eliminate the groundwater level sensor and to provide an overcurrent protection function due to overload, and to prevent idling of the driving motor at low water level, Which can detect the presence or absence of ground water by measuring the pressure of the groundwater.

The multifunctional heart pump controller of the present invention comprises a main body 100 for controlling the operation of a pump 30 that receives power from a drive motor 10 and transfers a fluid positioned under the fluid to a storage unit 20, The controller 100 includes a first controller 200 and a second controller 300. The first controller 200 senses the level of the fluid received in the storage unit 20, A water level sensor unit 210 for transmitting to the main body 100; A function unit 220 for inputting a set value arbitrarily set for activating the first control unit 200 and the second control unit 300 and operating to store the input set value; When a current is supplied to operate the driving motor 10, the current is detected when the driving motor 10 is driven and the data is measured. When the measured value is detected to be less than the set value, The second control unit 300 controls the operation of the driving motor 10 by turning on / off a current for driving the pump 30 An electromagnetic contactor 310; And a starting capacitor 320 for supplying a predetermined amount of forward current to the driving motor 10 when the driving motor 10 is driven so that the driving motor 10 can be operated from the OFF state to the ON state .

In the present invention, when the level of the fluid is idling lower than the range of motion of the pump 30, the current amount measurement data value of the driving motor 10, measured by the motor current sensing unit 230, The electromagnetic contactor 310 is turned off and the operation of the pump 30 is stopped.

In the present invention, when the predetermined time has elapsed after the operation of the pump 30 is stopped, the first controller 200 changes the electromagnetic contactor 310 to the ON state, And a re-operation unit 240 for transmitting a specific signal to the electromagnetic contactor 310 so as to be performed.

In the present invention, when the motor current sensing unit 230 continuously senses a current equal to or greater than a predetermined value for a predetermined period of time, the first controller 200 turns off the electromagnetic contactor 310, And an overcurrent sensing unit 250 for preventing breakdown.

The overcurrent sensing unit 250 changes the state of the electromagnetic contactor 310 to the ON state after a predetermined time elapses after turning off the electromagnetic contactor 310 so that the driving of the pump 30 And transmits a specific signal to the electromagnetic contactor 310 so as to be performed.

The present invention does not include a water level sensor for sensing the level of groundwater, so that it is easy to maintain and repair due to no need for corrosion of the sensor or replacement of sensor during long-time use, and the wiring for connecting the water level sensor and the controller is not provided, Lt; / RTI >

Further, since the water level of the groundwater can be detected by measuring the difference between the normal operation of the pump and the amount of electric power used in idling, it is possible to prevent the pump drive motor from overheating, and when the drive motor is stopped, There is an advantage that an automatic return function for operating the rear drive motor is mounted and no separate management is required.

BRIEF DESCRIPTION OF THE DRAWINGS Figure 1 is a schematic diagram showing the overall system of a multifunctional heart pump controller of the present invention.
2 is a schematic view showing a main configuration of a first control unit and a second control unit of the multifunctional heart pump controller of the present invention.
3 is a flow chart showing an operational embodiment of the present invention;
FIG. 4 is a flow chart showing an operation example when the groundwater level is lowered according to the present invention. FIG.
5 is a flowchart showing an operation example when an overcurrent occurs in the drive motor and the pump of the present invention.
6 is a flowchart showing an operation example of a drive motor and a pump according to a water level of a storage part of the present invention.
7 is a circuit diagram showing a circuit of a first control section of the present invention.
8 is a circuit diagram showing a circuit of a second control section of the present invention.

Hereinafter, an embodiment of the present invention will be described in detail with reference to the drawings.

FIG. 1 is a schematic diagram showing an overall system of a multifunctional heart pump controller of the present invention. FIG. 2 is a schematic diagram showing the main configuration of a first controller and a second controller of the multifunctional heart pump controller of the present invention. 5 is a flowchart showing an operation example when an overcurrent occurs in the driving motor and the pump of the present invention, and Fig. 6 is a flowchart showing the operation of the present invention. Fig. FIG. 7 is a circuit diagram showing a circuit of a first control section of the present invention, and FIG. 8 is a circuit diagram showing a circuit of a second control section of the present invention.

Referring to FIG. 1, the multifunctional heart pump controller of the present invention has a main body 100. The main body 100 includes a first control unit 200 and a second control unit 300. The main body 100 controls the operation of the pump 30, which is inserted into the pipeline in which the groundwater is stored, and the drive motor 10, which receives the power from the outside and operates the pump 30. When the fluid (ground water) is pumped from the pump 30, the pumped fluid is transferred to and stored in the storage unit 20 provided on the ground.

Referring to FIG. 2, the main body 100 includes a first control unit 200 and a second control unit 300. The first control unit 200 includes a water level sensor unit 210, a functional unit 220 and a motor current sensing unit 230 as an MCU (Micro Controller Unit).

The water level sensor unit 210 is installed in the storage unit 20 and is installed to sense the level of the fluid contained in the storage unit 20. That is, when the fluid contained in the storage unit 20 reaches a predetermined amount, The controller 210 senses this and transmits a specific signal to the main body 100 and stops the operation of the pump 30 to prevent the fluid from being accommodated in the reservoir 20 in an excessive amount.

The function unit 220 operates the first control unit 200 and the second control unit 300 and inputs and stores a set value arbitrarily through a motor current sensing unit 230 or the like to be described later. Is used as a means for storing the data. The function unit 220 may also include a display unit 221 such as an LED or an LCD for outputting a set value set by the current user and a current value sensed through the motor current sensing unit 230. [

The function unit 220 includes a SET button that can display a set value currently input to the display unit 221 every time the button is pressed, an UP button that raises or lowers a set value, a DOWN button, an UP button, and a DOWN button And a STORE button for storing an arbitrary set value in the memory.

The motor current sensing unit 230 can detect the amount of current required for driving the driving motor 10 and convert it into data when the current is supplied to the driving motor 10 in order to operate the driving motor 10. [ When the measured value is compared with the set value input from the function unit 220 and the measured value is detected to be less than the preset value, the current supplied for the operation of the drive motor 10 is cut off, It can be stopped.

Referring to FIG. 2, the second controller 300 includes an electromagnetic contactor 310, a starting capacitor 320, and a current controller 330 for controlling an AC current. First, the electromagnetic contactor 310 has a purpose of controlling the operation of the drive motor 10 by turning on / off a current transmitted to the drive motor 10. [ The starting capacitor 320 has a purpose of supplying a leading current to the starting coil when the driving motor 10 is driven so that the driving motor 10 can be operated. That is, the driving motor 10 can be operated by operating the rotor of the driving motor 10 when the driving motor 10 is stopped and then restarted, so that a current of a predetermined amount or more can be transmitted to the driving motor 10. When the driving motor 10 is continuously operated, the leading current transmitted from the starting capacitor 320 to the starting coil is cut off.

The current control unit 330 is provided for the purpose of controlling the current delivered to the driving motor 10 through the starting capacitor 320. The current control unit 330 includes an auxiliary control unit 331 and may be turned on / off by the auxiliary control unit 311. That is, when the auxiliary control unit 331 is turned on, a current flows to operate the current control unit 330 to operate the starting capacitor 320. When the auxiliary control unit 331 is turned off, the current supplied to the current control unit 330 is shut off, The operation of the condenser 320 can be stopped.

Referring to FIG. 3, the initial start-up and restart of the drive motor 10 will be described in detail. First, when receiving an operation command of the pump 30 from the first controller 200, the controller 30 receives a current for driving the driving motor 10. Thereafter, when the auxiliary control unit 331 is turned ON and the current control unit 330 is operated, the start of the drive motor 10 is started. Thereafter, when the start of the drive motor 10 is started and a set time that has been set arbitrarily elapses, the current control unit 330 is turned OFF to complete the start-up of the drive motor 10. [

Referring to FIG. 4, when the level of the fluid is below the operating range of the pump 30 (when the level of the ground water is lowered), the pump 30 maintains the idling state. At this time, since the pump 30 is idling, the available current of the drive motor 10 is reduced. (A current of about 60 to 80% can be used for the amount of current available when idling the pump 30.) The motor current sensing unit 230 measures the amount of the reduced current. At this time, when the idle state of the pump 30 continues for a predetermined time or more and the measured amount of current drops below the set value, current is supplied to the output relay 231 connected to the electromagnetic contactor 310 and operated. Thereafter, the electromagnetic contactor 310 is turned off to cut off the electric current transmitted for the operation of the drive motor 10, thereby stopping the operation of the pump 30.

Referring to FIGS. 2 and 4, the first control unit 200 includes a restart operation unit 240. The restart operation unit 240 has a purpose of transmitting a specific signal to the electromagnetic contactor 310 to restart the pump 30 after a predetermined time has elapsed. More specifically, when the operation of the pump 30 is stopped, the current value measured by the motor current sensing unit 230 is transmitted to the display unit 221, and the restart operation unit 240 determines the stop state of the pump 30 Detection. When the pump 30 is stopped, the user sets the arbitrary time, and when the set time has elapsed, the operation of the output relay 231 is stopped and the electromagnetic contactor 310 is turned on and the pump 30 can be operated .

Referring to FIGS. 2 and 5, the first controller 200 may further include an overcurrent sensing unit 250. The overcurrent sensing unit 250 measures a current equal to or greater than a predetermined value in the motor current sensing unit 230. When the duration of the overcurrent sensed at a preset value or more elapses for a predetermined time or more, the output relay 231 is activated, The contactor 310 is turned OFF and the operation of the pump 30 is stopped. Therefore, an overcurrent greater than the allowable current is supplied to the drive motor 10, which prevents malfunction and damage of the drive motor 10.

Referring to FIGS. 2 and 5, the overcurrent sensing unit 250 may output the overcurrent sensing unit 250 to the display unit 221 so that the user can recognize whether the overcurrent sensing unit 250 operates. At the same time, the electromagnetic contactor 310 is turned off. At this time, the time after the electromagnetic contactor 310 is turned off is counted, and when the time set by the user has elapsed, the electromagnetic contactor 310 is changed to the ON state. . Accordingly, the pump 30 can be driven, and even if the operation of the pump 30 is stopped by the overcurrent, the continuous operation of the pump 30 can be enabled due to the technical features of the overcurrent sensing unit 250 .

2 and 6, the water level sensor unit 210 may include a first sensor 211 installed at the upper end of the storage unit 20 and a second sensor 212 installed at the lower end. When the fluid comes into contact with the first sensor 211, the water level of the storage portion 20 reaches the maximum limit, and when the fluid comes into contact with the second sensor 212, the water level of the storage portion 20 reaches the minimum limit. A plurality of measurement sensors may be provided between the first sensor 211 and the second sensor 212 to display the water level of the storage unit 20 on the display unit 221. [ When a fluid is detected by the first sensor 211, a specific signal is transmitted from the first sensor 211 to the main body 100, and then the output relay 231 is operated and the electromagnetic contactor 310 is turned off And the operation of the pump 30 is stopped. On the contrary, when the fluid is not sensed in the second sensor 212, the output relay 231 stops operating and the electromagnetic contactor 310 is turned on, so that the pump 30 operates to supply the fluid to the storage part 20 Can supply.

The multifunctional heart pump controller according to the present invention having such a construction can provide an economical effect because it is not provided with a water level sensor for sensing the level of ground water, and can be easily used because of maintenance. In addition, the present invention can prevent overheating of the driving motor, and can stop and restart the driving motor automatically, so that there is no need to separately manage the driving motor.

10: drive motor 20:
30: Pump 100: Body
200: first control unit 210: water level sensor unit
220: Function part 230: Motor current sensing part
240: restart operation section 250: overcurrent detection section
300: second control unit 310: magnetic contactor
320: starting capacitor 330: current control unit

Claims (5)

A heart pump controller comprising a main body (100) for controlling the operation of a pump (30)
The main body 100 includes a first control unit 200 and a second control unit 300,
The first control unit 200
A water level sensor unit 210 for sensing the level of the fluid contained in the storage unit 20 storing the fluid supplied by the pump 30 and transmitting the sensed signal to the main body 100;
A function unit 220 for inputting a set value arbitrarily set for activating the first control unit 200 and the second control unit 300 and operating to store the input set value;
The amount of current required for driving the driving motor 10 is detected when a current required for driving the driving motor 10 for driving the pump 30 is transmitted and the detected amount of current is compared with the amount of current detected by the function unit 220 And a motor current sensing unit (230) for stopping the operation of the pump (30) when the measured value is less than a set value in comparison with a set value,
The second control unit 300
An electromagnetic contactor 310 for controlling the operation of the drive motor 10 by turning on / off a current transmitted to the pump 30;
A starting capacitor 320 for supplying a predetermined amount of forward current to the driving motor 10 when the driving motor 10 is driven so that the driving motor 10 can be operated from an OFF state to an ON state;
And a controller for controlling the multi-function heart pump controller. The method according to claim 1,
When the level of the fluid is idling lower than the range of movement of the pump 30, the current amount measurement data value of the driving motor 10 measured by the motor current sensing unit 230 is measured to be less than the set value And the electromagnetic contactor (310) is turned off to stop the operation of the pump (30) when the time is maintained. 3. The method of claim 2,
The first control unit 200
When the predetermined time has elapsed after the operation of the pump 30 is stopped, the electromagnetic contactor 310 is changed to the ON state and a specific signal is transmitted to the electromagnetic contactor 310 so that the pump 30 is driven And a re-start operation part (240) for re-operating the pump. The method according to claim 1,
The first control unit 200
The overcurrent sensing unit 250 for turning off the electromagnetic contactor 310 and preventing the drive motor 10 from being damaged when the current sensed by the motor current sensing unit 230 is continuously sensed for a predetermined period of time Wherein the multi-function heart pump controller comprises: 5. The method of claim 4,
The overcurrent sensing unit 250 changes the state of the electromagnetic contactor 310 to the ON state after a predetermined time elapses after turning off the electromagnetic contactor 310 so that the pump 30 is driven. (310). ≪ RTI ID = 0.0 > 31. < / RTI >

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