KR101370026B1 - Inverter booster pump system - Google Patents

Abstract

The prevent invention relates to an inverter booster pump system wherein each inverter is connected to a serial communication device and pushing and holding the stop button of an inverter sets the inverter′s turn in the group of inverters. In an inverter booster system, wherein multiple pumps (P1, P2, P3, P4) are arranged in a row between a supply pipe (10) and an incoming pipe (20); each pipe (P1, P2, P3, P4) corresponds to each inverter (IVM, IV1, IV2, IV3); and a controller (30) controls the inverters (IVM, IV1, IV2, IV3), each inverter (IVM, IV1, IV2, IV3) is connected to a serial communication device (40) and is able to transceive. Out of the multiple inverters (IVM, IV1, IV2, IV3), one inverter (IVM) is connected to a pressure censor (50) and recognizes itself as the master while the remaining inverters (IV1, IV2, IV3) recognize themselves as a slave and their turns are set in the order of having their own step button being pushed. [Reference numerals] (30) Controller; (50) Pressure sensor; (AA) Pressure tank; (BB) Supply pipe; (CC) Incoming pipe; (IV3,IV2,VI1,VIM) Inverter

Description

Inverter Booster Pump System {INVERTER BOOSTER PUMP SYSTEM}

The present invention relates to an inverter booster pump system in which each inverter is connected to a serial communication device, and when a stop button of the inverter is pressed for a long time, a number is automatically set to the corresponding inverter.

Korean Patent No. 10-1183907 (registered on September 12, 2012) introduces an "inverter booster pump system and a control method of an inverter booster pump system using the same".

The inverter booster pump system includes a pressure sensor for measuring a pressure in a supply pipe, a pump unit in which a plurality of pumps are connected in parallel to provide a ground output to the supply pipe, and a driving frequency of each pump constituting the pump unit. And a control unit including an inverter for varying the controller and a controller for controlling the pump unit, wherein the control unit includes: i) if the measured pressure measured by the pressure sensor has an error with the set pressure; Increase the drive frequency of the at least one pump being operated, additionally activate the idle pump, or ii) reduce the drive frequency of the at least one pump already in operation, or stop the operation of any one pump The control unit is connected to at least one pump being operated in the same output The things to control.

However, setting the sequence number of the inverter is not introduced in the inverter booster pump system.

Therefore, an object of the present invention is that each inverter is connected to the RS-485 communication module, by pressing and holding the stop button of the inverter, the number is automatically assigned to the inverter, after establishing a pump system, and manually into the menu of the inverter There is no need to set the inverter number on the sub-menu so as to provide an inverter booster pump system that can easily set the number of the inverter without causing an error in the inverter sequence setting.

In the inverter booster pump system according to the present invention for achieving the above object, a plurality of pumps are arranged in parallel between the supply pipe and the inlet pipe, each inverter corresponds one-to-one to each pump, each inverter is a controller In the inverter booster pump system controlled by each inverter, each inverter is connected to the serial communication device, each inverter can transmit and receive, any one of the plurality of inverters are connected to the pressure sensor, the pressure sensor is connected The inverter recognizes itself as a master, the rest of the inverter recognizes itself as a slab, it is characterized in that the order of the slab inverter is determined in the order that the first stop button signal of the slab inverter is input long first.

The slab inverter checks the setting number of the neighboring slab inverter through the serial communication device when the signal of the stop button is long among the plurality of setting buttons, recognizes and stores it as its own setting number by adding 1 to the inspected setting number. Characterized in that.

If it is necessary to reset the setting number of the inverter due to external environmental factors during use, press and hold the stop button of all slab inverters to switch to manual mode, the inverter connected to the pressure sensor automatically recognizes itself as the master, and the other inverters. Recognizes itself as a slab, characterized in that each slab inverter sequence number is determined in the order in which their stop button signal is long input among the slab inverters.

In this way, the inverter booster pump system according to the present invention does not need to manually enter the menu of the inverter and set the inverter number on the submenu after the pump system is constructed, so that no error occurs in the inverter sequence setting, and This has the effect of setting the number of the inverter.

1 is a schematic view showing an inverter booster pump system according to the present invention
2 is a front photograph showing a slab inverter

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

1, in the inverter booster pump system according to the present invention, a plurality of pumps P1, P2, P3, and P4 are arranged in parallel between the supply pipe 10 and the inflow pipe 20, and each pump ( Each inverter IVM, IV1, IV2, IV3 corresponds to P1, P2, P3, P4 one-to-one, and each inverter IVM, IV1, IV2, IV3 is controlled by the controller 30.

In the inverter booster pump system as described above, the present invention is that each inverter (IVM, IV1, IV2, IV3) is connected to the serial communication device 40 (for example, RS-485), each inverter (IVM, IV1, Inverters IVM and IV3 may transmit and receive, any one inverter IVM among the plurality of inverters IVM, IV1, IV2, and IV3 is connected to the pressure sensor 50, and the inverter IVM to which the pressure sensor 50 is connected. ) Recognizes itself as a master, the remaining inverters (IV1, IV2, IV3) recognizes itself as a slab, and its stop button signal among the slab inverters (IV1, IV2, IV3) is long (about 3 seconds). The order of the slab inverter is determined in the order of first input.

When the slab inverters IV1, IV2, and IV3 receive a long signal of the stop button 61 (see FIG. 2) among the plurality of setting buttons 60 for about 3 seconds, the slab inverters adjacent to the slab inverters through the serial communication device 40. Examine the setting number of, add 1 to the checked setting number and recognize and save it as your setting number. At this time, if there is no set number checked, it adds 1 to 0 to recognize and store itself as slab inverter number one.

The inverter is already known, so detailed description of the configuration and operation will be omitted.

For example, when a pump system is constructed and power is applied, the inverter IVM to which the pressure sensor 50 is connected recognizes itself as a master, and the remaining inverters IV1, IV2, and IV3 recognize themselves as slabs. Then, when the user presses the stop button 61 of any one of the inverters IV1, IV2, and IV3 for 3 seconds, the inverter whose stop button is pressed is set to the neighboring slab inverters through the serial communication device 40. Check if the number is set. If there is no setting number, recognize and save yourself as slab IV1. Thereafter, when the user presses the stop button of one of the other inverters for 3 seconds, the inverter pressed by the stop button searches whether the setting number is set to the other neighboring slab inverter through the serial communication device 40, and the first time. When the slab IV1 is found, it is recognized and stored as slab IV2. Thereafter, when the user presses the stop button of the last remaining inverter for 3 seconds, the inverter whose stop button is pressed is searched through the serial communication device 40 to determine whether a setting number has been set in the neighboring slab inverters. ) And slab IV2 are found and recognized as slab IV3.

Although four inverters are shown in FIG. 1, which is composed of one master and three slabs, the present invention is not limited thereto, and it is understood that the three or more inverters belong to the claims of the present invention. There will be.

In the inverter booster pump system according to the present invention, when the setting number of the inverter needs to be set again due to external environmental factors during use, by pressing and holding the stop button 61 of all slab inverters IV1, IV2, and IV3 for a manual operation. When switching to the mode, the inverter IVM to which the pressure sensor 50 is connected automatically recognizes itself as a master, and the remaining inverters recognize themselves as slabs IV1, IV2, and IV3, and the slab inverters IV1, IV2, Each of the slab inverters is re-determined in the order in which their stop button signal is input long (about 3 seconds).

The inverter booster pump system according to the present invention as described above does not need to manually enter the menu of the inverter and set the inverter number on the sub-menu after the pump system is built up, so that no error occurs in the inverter sequence setting, and the inverter can be easily The advantage is that you can set the number of.

10: supply piping 20: inflow piping
30: controller 40: serial communication device
50: pressure sensor
P1, P2, P3, P4: Pump IVM, IV1, IV2, IV3: Inverter

Claims (3)

A plurality of pumps P1, P2, P3, P4 are arranged in parallel between the supply pipe 10 and the inflow pipe 20, and each inverter IVM, which is connected to each of the pumps P1, P2, P3, and P4. In the inverter booster pump system in which IV1, IV2, IV3 correspond one-to-one and each inverter IVM, IV1, IV2, IV3 is controlled by the controller 30,
Each inverter IVM, IV1, IV2, IV3 is connected to the serial communication device 40 so that each inverter IVM, IV1, IV2, IV3 can transmit and receive, and a plurality of inverters IVM, IV1, IV2 One of the inverters IVM is connected to the pressure sensor 50, and the inverter IVM to which the pressure sensor 50 is connected recognizes itself as a master, and the other inverters IV1, IV2, and IV3 are connected to the pressure sensor 50. Recognizing itself as a slab, the inverter booster pump system, characterized in that the order of the slab inverter is determined in the order that the first stop button signal of the slab inverters (IV1, IV2, IV3) long input first.
The method of claim 1,
The slab inverters IV1, IV2, and IV3 check the setting numbers of neighboring slab inverters through the serial communication device 40 when a signal of the stop button 61 is long input among the plurality of setting buttons 60, Inverter booster pump system, characterized in that by recognizing and storing as its own set number by adding 1 to the set number inspected.
The method of claim 1,
If it is necessary to reset the setting number of the inverter due to external environmental factors during use, press and hold the stop button 61 of all slab inverters IV1, IV2 and IV3 to switch to manual mode, and the pressure sensor 50 is connected. The inverter IVM automatically recognizes itself as a master, and the remaining inverters recognize themselves as slabs IV1, IV2, and IV3, and their stop button signals among the slab inverters IV1, IV2, and IV3 are long input. Inverter booster pump system, characterized in that the order of each slab inverter is determined in order.

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