KR101539333B1 - Generator test system - Google Patents

Abstract

The present invention relates to a generator test system. The generator test system comprises: a terminal body; a touch panel installed on the terminal body; and a main control unit (MCU) mounted on an interior of the terminal body to control the touch panel. The touch panel comprises: a set part screen, into which product terminal information is input; a control part screen, into which each critical value of a cooling pan screen, a load screen, and a governor screen is input by the MCU embedded in the terminal body; a measuring part screen further precisely measuring various power values of the generator; and a monitoring part screen for checking a load applied when a generator is used. The present invention is divided into a method of sequentially injecting a load in a driving manner and a method for simultaneously injecting a load. A time period, which is required for each load after the load is injected, is stored, and stored information is used to operate the load.

Description

[0001] GENERATOR TEST CONTROL SYSTEM [0002]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a generator test control system, and more particularly, to a system and a load tester for controlling an EX bank (commonly referred to as a load meter, called a load bank).

Generally, a load bank is a device designed to provide electrical loads for testing a power source such as a generator or an uninterruptible power supply (UPS), as described in the background of EP-A-10-1202782, Test of uninterruptible power supply, battery system test, and turbine factory test.

That is, the load bank is a device for testing a power generation device such as a generator, a fuel cell, a solar cell, a wind turbine, etc., a power conversion device such as a battery, a UPS, an inverter, a transformer, Equipment.

The load bank generally has a combination of a resistor and an REACTOR and is manufactured by combining a resistor and a reactor in a case of testing a pure rated output only with a resistor and a case testing a power factor load, .

As a prior art, a load bank parallel control system of Patent Registration No. 10-1202782 has a plurality of load banks, each of which is composed of a heater array and a reactor array as a load, and which is composed of parallel circuits; A main PLC or a main microprocessor which controls the load banks independently or group-controlled by a parallel circuit configuration of the load banks, and which inputs or blocks heaters and reactors by comparing a load set value with a heater capacity and a reactor capacity; A power meter for measuring the current, the voltage, the power factor, and the power value of each of the load banks and transmitting the current to the main PLC or the main microprocessor; And a main HMI for inputting an execution command to the front load bank or outputting the measured values of all the power meters and inputting or separately dividing the active power and the power factor to be controlled for each load bank independently, Control system.

As another prior art, according to the load control method of a load bank parallel control system of Patent Registration No. 10-1286747, a plurality of load banks, each of which is composed of a heater array and a reactor array as a load, is constituted by a parallel circuit; A main PLC or a main microprocessor which controls the load banks independently or group-controlled by a parallel circuit configuration of the load banks, and which inputs or blocks heaters and reactors by comparing a load set value with a heater capacity and a reactor capacity; A power meter for measuring the current, the voltage, the power factor, and the power value of each of the load banks and transmitting the current to the main PLC or the main microprocessor; And a main HMI for inputting an execution command to the front load bank or outputting measured values of all power meters, independently inputting or evenly distributing the active power and power factor to be controlled for each load bank, In a parallel control system, a method of controlling the load input of a load bank having a heater array composed of a plurality of heaters having different capacitances (A1, A2, ..., AN) A first step of electrically connecting the heater having the largest heater value when the largest heater value is smaller than the set load value by comparing the set load value with the set load value, If the second larger heater value (A2) is compared with the set load value and the second larger heater value is smaller than the set load value, the heater with the second larger heater value is electrically opened (X-A1 = X1) obtained by subtracting the second largest heater value (A2) from the set load value and the largest heater value when the heater having the largest heater value is put in the second step A third step of electrically connecting the heater having the second largest heater value when the second larger heater value is smaller than the value X1 obtained by subtracting the largest heater value from the set load value; If the value is not smaller than the set load value, the third larger heater value is compared with the set load value. If the third larger heater value is smaller than the set load value, the heater having the third largest heater value is electrically connected (X1-A2 = X2) obtained by subtracting the third larger heater value (A3) from the first larger heater value in the case where the heater having the second larger heater value is input, If A3 is less than X2, the heater with the third largest heater value is electrically And a step of repeating the fourth step and the fifth step by the electric connection of the heater having the smallest heater value (AN) until the load of the load bank parallel control system Control method.

However, the conventional system as described above is not divided into a method of sequentially charging the load and a method of simultaneously charging the load, and there is a disadvantage that the use time can not be stored in each load after the load is applied.

SUMMARY OF THE INVENTION Accordingly, the present invention has been made to solve the above-mentioned problems, and it is an object of the present invention to provide a generator test control system capable of controlling a generator of various capacities to reach a maximum approximate value of a target load setting value.

The present invention relates to a generator test control system, and more particularly, to a generator test control system comprising a terminal body, a touch panel installed in the terminal body, and an MCU mounted inside the terminal body to control the touch panel, The touch panel includes a setting screen on which product terminal information of the generator is input, a control screen on which a threshold value of a cooling fan screen, a load screen, and a governer screen is set by an MCU built in the terminal body, And a monitoring unit screen for confirming a load applied when the generator is used.

The present invention is divided into a method of charging the load sequentially and a method of charging the load at the same time. The time used for each load after the load is applied is stored, and the stored data is stored in a remarkable It is effective.

1 is a photograph of a terminal of a generator test control system;
2 is a detailed view of the main screen of the generator test control system.
FIG. 3 is a detailed view of the setting section of the generator test control system. FIG.
4 is a detailed view showing a dial pad on the setting sub-screen of the generator test control system.
Figure 5 is a set-up screen algorithm of the generator test control system.
6 is a detailed view of a cooling fan control portion of the generator test control system.
7 is an algorithm diagram of a coolant-fan control screen of a generator test control system.
8 is a detailed view of the load control section screen of the generator test control system.
Fig. 9 is an algorithm of a load control section screen of a generator test control system; Fig.
10 is a detailed view of the governor control section of the generator test control system.
11 is a detailed view showing the dial pad on the governor control screen of the generator test control system.
12 is an algorithm view of the governor control screen of the generator test control system.
13 is a detailed view of the measuring section of the generator test control system.
Fig. 14 is a diagram of a measurement sub-screen of the generator test control system. Fig.
15 is a detail view of the monitoring section of the generator test control system.
16 is a monitoring sub-screen algorithm of the generator test control system.
17 is an algorithm diagram of an error occurrence of a generator test control system;
Figure 18 is an overall algorithmic view of a generator test control system.
19 is an input load algorithm in operation of a generator test control system.

The present invention relates to a generator test control system and includes a terminal body 10, a touch panel 20 installed in the terminal body 10, The touch panel 20 includes a setting setting surface 21 on which product terminal information of the generator is inputted and a setting surface 21 on which the MCU built in the terminal body 10 cools A control unit screen 22 for setting a threshold value on a pan screen, a load screen, and a governer screen, a measurement screen 23 for measuring various power values of the generator more precisely, and a load And a monitoring unit screen (24) capable of displaying a plurality of images.

In addition, the cooling fan icons of the divided cooling fan icons are displayed in green on the cooling fan screen of the control unit screen 22, When an error occurs in the cooling fan, the divided cooling fan icons displayed on the cooling fan screen are turned off in red.

Also, if the Gabor icon of the control unit screen 22 is touched, the screen is switched to the Gabor test mode, and the Gabor test mode can confirm the actual values of the reactive power, the effective power, and the power factor .

BRIEF DESCRIPTION OF THE DRAWINGS FIG.

Fig. 2 is a detailed view of the main screen of the generator test control system. Fig. 3 is a detail view of the setting screen of the generator test control system. Fig. 4 is a view showing the setting screen of the generator test control system Fig. 6 is a detailed view of the cooling fan control section of the generator test control system, Fig. 7 is a flowchart of the coolant fan control section screen algorithm of the generator test control system, Fig. Fig. 10 is a detailed view of the governor control section of the generator test control system. Fig. 11 is a view showing the details of the generator test control of the generator test control system. Fig. 12 is a detailed view showing the dial pad on the governor control section screen of the system. Fig. Fig. 14 is a detailed block diagram of the measuring section of the generator test control system, Fig. 14 is a block diagram of the measuring section screen of the generator test control system, Fig. 15 is a detail view of the monitoring section of the generator test control system, Fig. 17 is a diagram showing the algorithm of the generator test control system when an error occurs. Fig. 18 is a diagram showing the entire algorithm of the generator test control system. Fig. 19 is a diagram showing the operation of the generator test control system The load algorithm is also a drawing.

A touch panel 20 mounted on the terminal body 10 and a touch panel 20 mounted on the terminal body 10 to control the touch panel 20, The generator test control system includes a setting setting screen 21 in which product terminal information of a generator is input and a cooling fan screen, a load screen, and a Governer screen are controlled by an MCU built in the terminal body 10 A control unit screen 22, a measurement unit screen 23 for measuring various power values of the power generator, and a monitoring unit screen 24 for monitoring a load applied when the generator is used.

When the terminal body is booted, a main screen is displayed on the touch panel.

The touch panel is connected to an MCU provided in the terminal body to exchange data, and each setting sub-screen, a control sub-screen, a measurement sub-screen, and a surveillance sub-screen controlled in accordance with information inputted by the user is displayed on the touch panel .

That is, when the user touches each of the setting sub-screens, the control unit screen, the measurement sub-screen, and the monitor sub-screen displayed on the main screen, the data selected by the user is input to the MCU and processed, Is displayed on the touch panel.

Accordingly, when the user touches the setting sub screen icon on the main screen, the setting sub screen is displayed and displayed on the touch panel by the input data.

The setting sub screen is a screen for inputting basic information of a generator to be tested.

In other words, icons of the generator capacity, the generator frequency, the generator voltage, the load capacity, the load power, and the load power factor of the generator to be tested are arranged and displayed on the setting screen.

On the right side of each icon displayed on the setting sub screen, a numeric window for inputting basic information of the generator is displayed.

1, an OP key is formed on the left side of the touch panel as shown in FIG. 1, and when the OP key is touched and a desired number window displayed on the touch panel is touched, a numeric dial pad appears on the setting screen do.

If you enter the basic information value of the generator you want to test into the dialpad, it will become the basic information of the generator you want to test.

In addition, each of the control unit screen, the measurement unit screen, the monitor screen, and the main screen tab is configured at the bottom of the setting screen, and the icon of the desired screen is displayed on the touch panel.

On the other hand, when the user touches the control unit screen icon on the main screen or touches the control unit screen icon on the setting unit screen, the control unit screen is displayed on the touch panel according to the input data.

On the lower part of the control screen, tabs are displayed, each of which includes a cooling fan, a load, a governor, and main screen icons.

When the user touches the cooling fan icon, the fan operation state and operation state of the generator are displayed on the cooling fan screen of the control unit screen.

That is, the fan operation icon and the stop icon are displayed on the upper left of the touch panel on the cooling fan screen of the control unit screen, and the cooling fan stop time can be set and displayed on the touch panel so that the remaining time of the cooling fan can be known.

In the central portion of the cooling fan screen of the control unit screen, icons indicating the twelve kinds of fan operation states of FAN1 to FAN12 are displayed on the touch panel.

In addition, the cooling fan screen icons on the control unit screen are displayed in green during operation, red in stop mode, and flashing in red when an error or alarm occurs.

That is, the operating states of the cooling fans from FAN1 to FAN12 can be confirmed on the cooling fan screen of the control unit screen.

On the other hand, when an error or an alarm is generated in the cooling fan of the control unit screen, red flashing is displayed, and the alarm type is composed of a fan alarm, a reactor alarm, a heater alarm, and an emergency stop alarm icon.

When the fan of the generator is not operated, the fan alarm is transmitted to the MCU by inputting an input signal to the MCU built in the main body of the fan, and the input signal is processed by the MCU. The data is output and the fan alarm icon flashes red.

When the reactor alarm is measured by the temperature sensor at a temperature higher than the set temperature of the reactor during the operation of the generator, the measured data is transmitted to the MCU built in the terminal body and processed, and the processed input signal is transmitted to the controller screen Data is output and the reactor alarm icon flashes red.

When the heater alarm is measured by the temperature sensor at a temperature higher than the set temperature of the heater during the operation of the generator, the measured data is transmitted to the MCU built in the terminal body and processed, and the processed input signal is transmitted to the controller screen Data is output and the reactor alarm icon flashes red.

When the emergency stop switch is turned on, data on the switch state is transmitted to the MCU built in the terminal body and processed. When the emergency stop alarm is transmitted to the MCU, the processed data is output to the controller screen, Is blinking in red.

When the user touches the load icon, data on load and power factor are displayed on the load screen of the control unit screen.

In addition, the load can be set only when the terminal body is executed.

The method of setting the load and power factor of the load screen in the state where the terminal body is operated is as follows.

0.1%, 0.2%, 0.5%, 1.0%, 2.0% and 5.0% icons displayed in the load window of the load screen are selected and displayed in green.

After pressing the OP KET (30), you can change the load value by touching the arrow pointing to the upper part and the arrow pointing to the lower part displayed on the right side of the load icon.

Also, if the OP KET is touched and the load rate icon is touched, a dial pad composed of numbers is displayed on the screen for hatching, and the load rate is modified by touching the dial pad.

Also, when the generator is operated with the changed load and load factor values, using the TRIM function provided in the terminal body, the changed load and load factor values are reflected and the power factor value is measured in the MCU and displayed in the power factor window.

When an error occurs in the load screen, the corresponding alarm flickers. If the alarm flickers for a certain period of time, the MCU detects the alarm and LOAD-STOPs it.

Then, the MCU is put in a FAN-STOP mode.

On the other hand, if the user touches the governor icon on the control screen, the screen is switched to the governor test mode.

The governer test mode can confirm the actual values of reactive power, active power, and power factor.

That is, the actual values of the reactive power, the effective power, and the power factor are displayed on the screen.

Therefore, the actual values of the reactive power, the effective power, and the power factor for the corresponding load value can be confirmed.

In addition, when the measurement screen is touched on the main screen, the measurement screen is displayed on the touch panel, and various measurement values can be checked in more detail.

In addition, when the monitoring screen is touched on the main screen, a monitoring screen is displayed on the touch panel and displayed on the touch panel so that the actual resistance capacity and the load of the reactor capacity can be checked during operation of the generator.

?

On the other hand, the algorithm for the input load during generator operation is as follows.

As shown in FIG. 17, the load value to be injected is first confirmed.

Then, calculate the quotient and the remainder by dividing the largest value unit capacity by KW.

The remaining load is assigned to the share, the remaining KW is obtained, and the next capacity value is designated as the divisor.

If the remaining capacity is less than the minimum capacity, the calculated load is applied.

In addition, algorithm driving method for the input load during generator operation is load sequential driving and simultaneous load driving.

After the load is applied, the time used for each load is stored by the MCU, and the stored contents are used to operate the load.

10: terminal body 20: touch panel 21: setting sub screen
22: control section screen 23: measuring section screen 24: monitoring section screen
30: OP KEY

Claims (3)

A touch panel 20 mounted on the terminal body 10 and an MCU mounted inside the terminal body 10 for controlling the touch panel 20, In this case,
The touch panel 20 includes a setting setting screen 21 on which the product terminal information of the generator is input and a threshold value of a cooling fan screen, a load screen, and a governer screen by an MCU built in the terminal body 10, A monitoring section screen 23 for measuring various power values of the generator more precisely and a monitoring section screen 24 for confirming the load applied when the generator is used,
The operating states of the divided cooling fan icons are displayed on the cooling fan screen of the control unit screen 22. When the divided cooling fans operate normally, the cooling fan icons are displayed in green, When an error occurs, the divided cooling fan icons displayed on the cooling fan screen flash in red,
When the governor icon of the control unit screen 22 is touched, the display is switched to the governor test mode, and the governor test mode can check actual values of reactive power, active power and power factor,
In addition, the algorithm for the input load at the time of generator operation checks the load value to be input to the generator, calculates the quotient and the remainder by calculating the largest unit capacity by KW, and allocates the load corresponding to the quotient and the remainder The remaining KW is determined and the next capacity value is designated as a divisor. If the remaining capacity is less than the minimum capacity, the calculated load is inputted,
The algorithm driving method for the input load during the generator operation is divided into the load sequential drive and the load simultaneous drive method. The time used for each load after the load is loaded is stored by the MCU, and the stored contents are used for operating the load The generator test control system being characterized in that:
delete delete

Images