KR101306166B1 - Power division and control system for water supply pump - Google Patents

Abstract

PURPOSE: A power division and control system of a feed pump is provided to secure the operation of an inverter with an alternative inverter even though the inverter in charge of the operation of the inverter. CONSTITUTION: A power division and control system of a feed pump includes a power division system and a central control unit (400). The power division system includes an inverter connected to a power source unit (100); a first switch group (210) composed of a first inverter switch (210I) connected to the inverter and a first pump live operation switch (210p) connected to the power source unit; a second switch group (220) composed of a second pump inverter switch (220I) connected to the inverter and a second pump live operation switch (220P); a first pump (310) connected to the first pump inverter switch and the first pump live operation switch of the first switch group; and a second pump (320) connected to the second pump inverter switch and the second pump live operation switch. The central control unit is composed of an inverter control unit (410) for controlling the inverter and operating the first and second inverter switches; and a live operation power source control unit (430) and a live operation switch control unit (420) for controlling and operating the first and second pump live operation switches. [Reference numerals] (AA) Water supply outlet unit; (BB) Water supply inhaling unit

Description

Power division and control system for water supply pump

The present invention relates to a power supply and control system of a feedwater pump, and more particularly, a plurality of inverters are used to guarantee the inverter operation of the pump through another inverter even when the inverter is malfunctioning, and to directly operate the other pumps. The present invention relates to a power distribution and control system of a feed water pump which enables a stable and precise water supply.

In general, a plurality of water supply pumps must be used for water supply in a multi-use building including an apartment. Indirect operation of fully operating a given water supply pump does not precisely set the desired water supply and damages the piping due to high pressure. It is possible to supply the desired amount of water supply by using the inverter operation. The conventional water supply pump control system, which is currently used in general, has a method of operating a plurality of inverters by connecting one inverter to one pump.

1 is a power system diagram illustrating a water supply pump control system using a plurality of conventional inverters as described above. In FIG. 1, the main power supply 10 is connected to the A inverter 11, the B inverter 12, the C inverter 13, and the D inverter 14, which control the speed of each pump motor, respectively. Is connected one-to-one with A pump 21, B pump 22, C pump 23, D pump 24, and each inverter is also controlled by the power supply controller 30. In the conventional system configured as described above, if the A inverter 11 operates and the A pump 21 performs inverter startup, the remaining B pump 22, C pump 23, and D pump 24 are It is operated by direct start operation.

However, in the case of a water supply pump control system using a plurality of inverters as described above, one inverter is required for each pump, so it is uneconomical and when the power control unit 30 that controls the inverter is broken, all the systems are stopped to operate the pump. You cannot use it. In addition, when one inverter of the plurality of inverters malfunctions, a device capable of operating the pump with another power source is not configured, and thus the pump connected to the failed inverter cannot be used. For example, when the A inverter 11 of FIG. 1 fails, the A pump 21 connected to the A inverter 11 cannot be used.

In another conventional method, there is a method of connecting and operating one inverter to a plurality of pumps, which is a method of operating a water supply pump control system by operating one inverter 51 as shown in FIG. 2.

In FIG. 2, the main power supply 50 is connected to the control inverter 51, and the control inverter 51 is the A pump 61, the B pump 62, the C pump 63, and the D in the pump unit 60, respectively. Both are connected to the pump 64. In addition, between the control inverter 51 and the A pump 61, an A pump switch group 71 composed of an inverter switch 71I and a direct-input start switch 71P is provided. Similarly, the B pump 62 and the C pump (63), between the D pump 64 and the control inverter 51, the B pump switch group 72, the C pump switch group 73, and the D pump switch composed of a pair of switches of the inverter switch and the direct start switch. A group 74 is installed to form the control inverter power supply group 70. Inverter switches 71I to 74I in the control inverter power supply group 70 are connected to the control inverter 51 and direct-input start switches 71P to 74P are directly connected to the main power source 50. The control inverter 51 and the control inverter power supply group 70 are controlled by the central controller 80. The central control unit 80 includes an inverter control unit 81 that controls the control inverter 51, a direct start control unit 82 and a direct control that control the indirect start switches 71P to 74P of the control inverter power supply group 70. It is composed of a manual start manual control unit 83 for manually controlling the direct start in the event of failure of the input start control unit 82.

However, in the case of a water supply pump control system using one inverter 51 as described above, when the control inverter 51 fails, all the pumps of the pump unit 60 should be operated by direct operation. There is a risk of failure of water supply equipment due to high pressure and inaccurate adjustment of the desired amount of water supply, and problems of smooth water supply.

In order to solve the above problems, Patent No. 10-0165723 has provided a water supply device which discloses that the inverter is started using the remaining inverters when the inverters using two inverters fail. However, there is a disadvantage in that the patent does not use the remaining pumps that are not controlled by the inverter.

The present invention is to solve the problems of the prior art as described above, by operating a plurality of inverters in a manner of connecting one inverter per two or more pumps to ensure precise water supply through the inverter control pump not receiving inverter control The purpose is to provide a power division and control system of a redundant feedwater pump that can be configured to enable direct start-up and supply water accurately and stably.

The present invention to achieve the object of the present invention as described above,

A first switch group comprising an inverter connected to a power supply unit, a first inverter switch connected to the inverter and a first pump switch connected to the power supply unit, a second inverter switch connected to the inverter and a second pump connected to the power supply unit A second switch group having a position, a first pump connected with the first inverter switch and the first pump switch of the first switch group, and connected with the second inverter switch and the second pump switch of the second switch group Multiple power division systems are provided to be configured as a second pump so that even if the inverter in one system fails, the inverters of the other power division system can be operated and the rest of the systems can be operated by direct start to ensure stable and accurate water supply.

In the present invention, two or more switch groups may be connected to the inverter.

In addition, in the present invention, the inverter control unit for controlling the inverter and operating the first and second inverter switch, the direct start power supply control unit and the direct start switch control unit for controlling and operating the first and second pump switch It is preferable to install the central control unit is configured to operate the system according to the control of the central control unit.

In addition, it is preferable to install more than one power classification system in the above.

In addition, the power classification system may ensure a stable system operation by installing one or more replacement control unit that can replace the central control unit when a malfunction occurs.

In addition, the power division system may be provided with a pressure signal sensor for ensuring the inverter start of the pump when the central control unit and all the alternative control unit malfunctions to ensure a minimum inverter start even when all of the control unit failure. In this case, one or more pressure signal sensors may be installed so that one alternative pressure sensor may be used when one pressure signal sensor fails.

According to the present invention, even if the inverter responsible for starting the inverter fails, the inverter can be guaranteed through an alternative inverter, and the remaining pump can be driven by indirect starting other than the pump that performs the inverter starting, so that it is easy to supply a desired quantity. It can reduce unnecessary power consumption and enable stable and precise water supply through a plurality of controllers and pressure sensors.

1 is a power system diagram illustrating a water supply pump control system operating by a plurality of inverters in the related art.
2 is a power system diagram illustrating a water supply pump control system operating a conventional single inverter.
3 is a power system diagram illustrating a power supply pump power classification and control system of the present invention;

Hereinafter, with reference to the accompanying drawings will be described the present invention in more detail. The following description is to aid the understanding and practice of the present invention, but not to limit the present invention thereto. Those skilled in the art will appreciate that various modifications and changes can be made within the spirit of the invention as set forth in the claims below.

First, referring to FIG. 3, in the system 1000 of the present invention, the power supply unit 100 is connected to the first inverter 110 and the second inverter 120, respectively. In addition, a first pump switch group 210 is installed between the first inverter 110 and the first pump 310 to control the starting of the first pump 310, and likewise between the second pump 320 and the second pump 320. Two pump switch group 220 is installed, the second inverter 120 and the third pump 330. A third pump switch group 230 and a fourth pump switch group 240 are installed between the fourth pumps 340 to control the start of each pump. The first pump switch group 210 includes a first pump inverter switch 210I and a first pump direct start switch 210P, and the first pump inverter switch 210I is connected to the first inverter 110. Located between the first pump 310 to control the inverter start of the first pump 310, the first pump direct start switch 210P is located between the main power source 100 and the first pump 310 Control the direct inlet start of the first pump (310). The second pump switch group 220 for controlling the second pump 320 also has the same configuration as that of the first pump switch group 210 and has the same role. In addition, the third and fourth pump switch groups 230 and 240, which are connected to the second inverter 120 and control the third pump 330 and the fourth pump 340, respectively, are also connected to the first pump switch group 210. ) And configuration and role are the same.

The inverter and pump switch group are automatically controlled by the central control unit 400. The central control unit 400 is an inverter control unit 410 for controlling the first to fourth pump inverter switches 210I to 240I and the first to second inverters 110 and 120, and the first to fourth pump direct start switch 210P. Direct start switch control unit 420 for controlling the ~ 240P), direct start power supply control unit 430 for controlling whether or not the direct injection of each pump.

In addition, when the central control unit 400 malfunctions, an alternative control unit 500 may be installed to replace the system. When the central control unit 400 fails, the control unit may acquire the control right of the system 1000 and the system may operate normally. Make sure

In addition, in the present invention, when the central control unit 400 and the replacement control unit 500 are both malfunctioning, a pressure signal sensor 600 is installed to ensure the minimum inverter start of the first to fourth pumps 310 to 340. The pressure signal sensor 600 is a frequency and pressure value set by the user is input, when the central control unit 400 and the alternative control unit 500 both malfunction the pressure signal sensor 600 operates to operate the current inverter Input the set frequency to the running pump to perform the inverter start according to the frequency to ensure the inverter start of the pump.

Hereinafter will be described the operation and operation of the system 1000 of the present invention configured as described above.

First, when the first inverter 110 is operated under the control of the preset central controller 400, the first and second pumps 310 and 320 connected to the first inverter 110 are sequentially driven. In order to achieve this, first, the first pump inverter switch 210I in the first pump switch group 210 is operated to enable the first pump 310 to perform inverter startup, and direct initiation is required according to the water supply requirement. If the central control unit 400 determines, the second, third, and fourth pumps 320, 330, and 340 except for the first pump 310 performing the inverter start perform the direct start as necessary. Controlled by 400. If only some of the pumps other than the pump that performs the inverter start perform the direct start operation, one pump does not continuously carry out the direct start operation, but the direct start starts sequentially under the control of the central controller 400 to overheat the pump. Will be prevented.

In addition, after the inverter startup of the first pump 310 is performed for a predetermined time, the second pump inverter switch 220I in the second pump switch group 220 operates to operate the inverter of the second pump 320. The second pump 320 performs the inverter start, and similarly, the first, third, and fourth pumps 310, 330, and 340 except for the second pump 320 are sequentially operated by the control of the central controller as necessary. Start your mouth.

After the second pump 320 performs the inverter startup for a predetermined time, the first pump 310 is able to perform the inverter startup again. Alternatively, when it is determined that the first inverter 110 has been operated for a long time according to a pre-input control signal, the central controller 400 operates the second inverter 120 so that the third and fourth pumps 330 and 340 start the inverter. To do this.

In the case where the first inverter 110 that is in operation fails, the central control unit 400 detects this and operates the second inverter 120 so that the third and fourth pumps 330 and 340 perform the inverter start-up. In the same manner, when the second inverter 120 that is in operation fails, the central control unit 400 operates the first inverter 110 to allow the first and second pumps 310 and 320 to perform inverter startup.

Therefore, even if the inverter in operation fails, the inverter can be started by another inverter that can be replaced immediately, thereby ensuring stable inverter start-up of the pump, which enables accurate water supply. In addition, pumps other than the inverters that start the inverter can also be started directly if necessary, so that water can be supplied according to the water supply requirements.

In addition, when the central control unit 400 fails, the replacement control unit 500 controls the inverter and the pump switch group in place of the central control unit 400 to increase the reliability of the system. In addition, when the central control unit 400 and the alternative control unit 500 are broken while the first inverter 110 is operating, the first inverter 110 and the second inverter 120 operating by operating the pressure signal sensor 600. Inverter startup can be selectively performed by inputting a preset frequency to the inverter so that stability can be ensured by performing inverter startup in an emergency. Since the pressure signal sensor 600 inputs only a preset frequency to the inverter, precise pressure control of the inverter can be performed.

100: power supply
110: first inverter 120: second inverter
210 to 240: 1st to 4th pump switch group 210I to 240I: 1st to 4th pump inverter switch
210P ~ 240P: 1 ~ 4 Pump Direct Start Switch
310 ~ 340: 1st-4 pump 400: Central control part
410: inverter control unit 420: direct start switch control unit
430: direct power control unit 500: alternative control unit
600: pressure signal sensor 1000: the system of the present invention

Claims (5)

A first switch group comprising an inverter connected to a power supply unit, a first pump inverter switch connected to the inverter, and a first pump direct start switch connected to the power supply unit, and a second pump inverter switch connected to the inverter and a power supply unit A second pump group comprising a second pump direct start switch, a first pump connected with a first pump inverter switch of the first switch group and a first pump direct start switch, and the first switch of the second switch group A power discrimination system comprising a second pump inverter switch and a second pump connected to the second pump indirect start switch;
An inverter control unit for controlling the inverter and operating the first and second inverter switches, and a direct start power supply control unit and a direct start switch control unit for controlling and operating the first and second pump direct start switches. And a central control unit, wherein the power classification system is provided with at least one power classification and control system of a water supply pump. delete The method of claim 1,
The inverter includes two or more switch groups and may further include a pump connected to the switch group. The method of claim 1,
The power classification system further comprises at least one alternative control unit which can replace the central control unit in the event of a malfunction. The method of claim 1,
The power classification system further comprises at least one pressure signal sensor for ensuring that the central control unit and all the alternative control units operate the pump when the pump malfunctions.

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