JP2000295896A - Governor testing device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To provide a governor testing device, by which connection of an equipment, the analysis of data and the data reduction of a test result can be conducted easily in a short time, labor and a time can be reduced while an error on the reading of a measured data can be lowered and levelling for input conversion is made unnecessary. SOLUTION: A signal (a sensor signal) displaying the information of a generator input to an input section 1a is stored in a memory 1b. The waveform of the signal displaying the information of the generator stored in the memory 1b is indicated on a liquid-crystal panel 1c. An analytic indication is inputted by a key input section 1d, a keyboard 2 and a mouse 3 to the waveform of the signal displaying the information of the generator indicated on the liquid- crystal panel 1c. A CPU 1e analyzes the signal displaying the information of the generator according to the analytic indication inputted by the key input section 1d, the keyboard 2 and the mouse 3, and a governor adjusting the rotational speed of the generator is tested.

Description

DETAILED DESCRIPTION OF THE INVENTION

[0001]

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a governor test apparatus used for a load shedding test of a governor for adjusting the rotation speed of a generator.

[0002]

2. Description of the Related Art Conventionally, in a load shedding test of a governor of a hydroelectric generator, a generator voltage, a generator current, a rotation speed, a water pressure in a water channel, a guide vane opening, and the like are detected by a detector. After the recorded data is recorded on the recorder, a person reads the data (input conversion value, etc.) of each measurement element from the record of the recorder, calculates the fluctuation rate of the measurement element based on the read data, and controls the speed. Analyze the operating conditions and characteristics of the machine. Then, the recorder records and test results are arranged and a report in a predetermined format is created.

[0003]

By the way, in the above load rejection test, the signal from the detector is connected to the recorder via many devices (level converters, etc.), and the recording and test results of the recorder are organized. And it takes a lot of effort and time to prepare a report. Also,
Reading data of a measurement element required for analysis from a recorder record requires skill and there is a problem that a reading error is large depending on a person. Furthermore, in order to calculate the input conversion value from the amplitude of the recording waveform of the recorder, a calibration signal with a signal level divided into several stages before the test is input, and the offset and gain of the input device (level converter, etc.) are input. Adjust
Since the swing width of the recorder is adjusted, there is a problem that it takes time and effort.

SUMMARY OF THE INVENTION It is an object of the present invention to quickly and easily connect devices, analyze measurement data and arrange test results, reduce labor and time, and reduce measurement data reading errors. It is an object of the present invention to provide a governor test apparatus which does not require level adjustment for input conversion.

[0005]

According to a first aspect of the present invention, there is provided a speed governor test apparatus for testing a speed governor for adjusting a rotating speed of a generator,
An input unit to which a signal representing information on the generator is input, a storage unit for storing a signal representing information on the generator input to the input unit, and information on the generator stored in the storage unit A display unit that displays a waveform of a signal representing the information, an analysis instruction input unit in which an analysis instruction is input for a waveform of the signal that indicates information of the generator displayed on the display unit, and an analysis instruction input unit. An analysis unit that analyzes a signal representing information on the generator in accordance with the input analysis instruction.

According to the governor test apparatus of the first aspect,
For example, a signal representing information on the generator such as a generator voltage, a generator current, a rotation speed, a water pressure, and a guide vane opening of the hydroelectric generator is input to the input unit. The signal representing the information of the generator input to the input section is stored in the storage section, and the waveform of the signal representing the information of the generator stored in the storage section is displayed on the display section. An analysis item and an analysis point are designated by the analysis instruction input unit with respect to the waveform displayed on the display unit, and the analysis unit analyzes the maximum value, the minimum value, various times, and the change rate of the measured data. By doing so, a test of a governor that adjusts the rotation speed of the generator is performed. Therefore, conventionally, signals from the detector were connected to the recorder via many devices, but by directly inputting the signal indicating the information of the generator to the input unit, the connection of the equipment was simplified. In addition, since the data can be analyzed in a short time and easily, labor and time can be reduced. Further, since the analysis unit analyzes the measured data instead of reading the printed waveform data, a reading error of the data can be reduced. It should be noted that, of course, the analysis contents whose contents are determined in advance and are not changed may be automatically analyzed as needed without an analysis instruction from the analysis instruction input unit.

According to a second aspect of the present invention, there is provided a speed governor test apparatus according to the first aspect, wherein the signal representing the information of the generator input to the input section is a start condition for starting recording. And a signal delay unit that delays a signal representing the information of the generator input to the input unit, and the storage unit includes the start condition determination unit. Is characterized in that when it is determined that the signal representing the information on the generator satisfies the starting condition, the signal representing the information on the generator delayed by the signal delay unit is stored for a predetermined time.

[0008] According to the governor test apparatus of the second aspect,
The starting condition determining unit determines whether a signal representing the information of the generator input to the input unit satisfies a starting condition for starting acquisition. Then, when the starting condition determining unit determines that the signal indicating the information of the generator satisfies the starting condition, the signal indicating the information of the generator delayed by the signal delay unit is stored in the storage unit. Remember time. In addition, as the starting condition for starting the above-mentioned acquisition, for example, the determination of the level of the generator current and the determination of ON or OFF of the on / off input are conditioned. In this way, it is possible to store a signal representing information on the generator, which indicates the state before the start point retroactively from the point in time when the predetermined start condition is satisfied.

According to a third aspect of the present invention, there is provided a speed governor test apparatus according to the second aspect, wherein the starting condition determining unit outputs the signal indicating the information of the generator input to the input unit. It is characterized by including a start signal output unit for outputting a start signal indicating start of recording when it is determined that the start condition is satisfied.

[0010] According to the governor test apparatus of the third aspect,
By using the start signal from the start signal output unit to indicate the start of recording for starting another test apparatus or measuring instrument, the speed governor test apparatus and the other apparatus can be operated simultaneously.

Further, the speed governor test apparatus according to claim 4 is the same as the speed governor test apparatus according to any one of claims 1 to 3,
An analysis result by the analysis unit is displayed on the display unit.

According to the governor test apparatus of the fourth aspect,
By displaying the analysis result by the analysis unit on the display unit, the analysis can be instructed by the analysis instruction input unit and the analysis unit can perform the analysis while confirming the analysis result. Obtainable.

[0013] Further, a speed governor test apparatus according to claim 5 is the speed governor test apparatus according to any one of claims 1 to 4, wherein
A printing unit for printing at least one of a waveform of a signal representing information of the generator stored in the storage unit and an analysis result by the analysis unit in a predetermined format is provided.

According to the governor test apparatus of the fifth aspect,
The printing unit prints, in a predetermined format, a waveform of a signal representing the information of the generator stored in the storage unit, and prints an analysis result by the analysis unit in a predetermined format (for example, a form). Therefore, by setting the printing format of the printing section to a format such as a report in advance, there is no need to paste a waveform print into the report or to transcribe the analysis data into the report. Can be easily arranged in a short time.

According to a sixth aspect of the present invention, there is provided a speed governor test apparatus according to the fifth aspect, wherein the display section displays a display position or swing of a waveform of a signal representing the displayed information of the generator. At least one of the widths can be changed, and the printing section displays the waveform of the signal representing the information of the generator at the display position and the swing width of the waveform of the signal representing the information of the generator displayed on the display section. Is printed.

According to the governor test apparatus of the sixth aspect,
The waveform of the signal representing the information of the generator, which is displayed on the display unit, is changed to a display position and an appropriate swing width which are easy to see and analyze, and the waveform of the signal representing the information of the generator is printed on the printing unit. Also changes according to the display position and the shake width of the display unit, so that the degree of freedom of display and print contents is increased.

[0017] Further, the speed governor test apparatus according to claim 7 is the speed governor test apparatus according to any one of claims 1 to 6, wherein
The signals representing the information of the generator input to the input unit are at least a voltage signal of a generator for speed detection for detecting a rotation speed of the generator and a synchronization signal of a synchronization signal generator for the generator. A signal selection unit that selects one of a voltage signal of the speed detection generator and a synchronization signal of the synchronization signal generator input to the input unit,
A rotation speed detection unit that detects a rotation speed of the generator based on one of a voltage signal of the speed detection generator selected by the signal selection unit and a synchronization signal of the synchronization signal generator. It is characterized by having.

According to the speed governor test apparatus of claim 7,
In the load shedding test, a voltage signal of a speed detection generator for detecting the rotation speed of the generator is selected by the signal selection unit, and the rotation speed detection unit is selected based on the voltage signal of the speed detection generator. While detecting the generator rotation speed,
In an emergency stop test such as when the voltage signal of the speed detection generator becomes zero, a sudden stop test, a slow stop test, and the like, a synchronization signal of the synchronization signal generator for the generator is selected by the signal selection unit, Based on the synchronization signal of the synchronization signal generator, the rotation speed detector detects the rotation speed of the generator. Therefore, it is possible to detect the number of revolutions in another test in which the voltage signal of the speed detection generator becomes zero other than the load shedding test.

According to a eighth aspect of the present invention, there is provided a speed governor test apparatus according to any one of the first to seventh aspects.
The analysis instruction input unit indicates two measurement points for one input element of the waveform of the signal indicating the information of the generator displayed on the display unit, or Each of the two input elements of the displayed waveform of the signal representing the information of the generator indicates a measurement point, and the analysis unit determines a time between the measurement points indicated by the analysis instruction input unit. Is measured.

[0020] According to the governor test apparatus of the eighth aspect,
The analysis instruction input unit indicates two measurement points for one input element of the waveform of the signal indicating the information of the generator displayed on the display unit, and the analysis unit indicates The time between the measurement points specified by the analysis instruction input unit is measured. In addition, a measurement point is designated for each of two input elements of the waveform of the signal indicating the information of the generator displayed on the display unit,
The analysis unit measures the time between the measurement points specified by the analysis instruction input unit. Therefore,
Time measurement can be performed with an arbitrary input element, and necessary time measurement data can be freely obtained according to a test purpose.

According to a ninth aspect of the present invention, there is provided a governor test apparatus according to any one of the first to eighth aspects.
The input unit is capable of inputting a signal representing information on two or more generators.

According to the governor test apparatus of the ninth aspect,
By using two or more input elements for the generator voltage, the generator current and the number of revolutions as the signals representing the information of the generator, for example, the signals representing the information of the two or more generators are simultaneously measured and tested. It is possible to do.

According to a tenth aspect of the present invention, there is provided the governor test apparatus according to any one of the first to ninth aspects, wherein the data of the signal representing the information of the generator stored in the storage unit is stored. , And a data storage unit capable of reading data of a signal representing information of the stored generator into the storage unit.

According to the governor test apparatus of the tenth aspect, signal data representing the information of the generator stored in the storage section is stored in the data storage section for each test, and the data is stored in the data storage section. The data of the signal indicating the information of the generator is read out to the storage unit again, and the data of the signal indicating the information of the generator read out to the storage unit is displayed on the display unit. Analysis.

According to an eleventh aspect of the present invention, there is provided a speed governor test apparatus according to any one of the first to tenth aspects, wherein the signal representing the information of the generator input to the input section or the signal representing the information of the generator is provided. An input conversion value calculation unit that calculates an input conversion value based on a signal representing information on the generator stored in the storage unit is provided.

According to the governor test apparatus of the eleventh aspect, based on the signal representing the information of the generator input to the input section or the signal representing the information of the generator stored in the storage section. Then, the input conversion value is calculated by the input conversion value calculation unit. Therefore, it is not necessary to adjust the offset and gain of the input device (such as a level converter) in order to adjust the swing of the recorder as in the related art, and the level adjustment for input conversion becomes unnecessary.

[0027]

BRIEF DESCRIPTION OF THE DRAWINGS FIG. 1 is a block diagram showing a governor testing apparatus according to the present invention.

FIG. 1 is a schematic structural view of a speed governor test apparatus according to an embodiment of the present invention, wherein 1 is a test apparatus main body, 2 is a keyboard connected to the test apparatus main body 1, and 3 is a test apparatus. A mouse connected to the main body 1, a ZIP drive 4 connected to the test apparatus main body 1 and recording measurement data, and a printer 5 connected to the test apparatus main body 1
(Using long paper). The above-mentioned test device main body 1, keyboard 2, mouse 3, ZIP drive 4 and printer 5 constitute a governor test device. The test apparatus main body 1 includes:
An input unit 1a to which a sensor signal representing information of a generator from various sensors is input, a memory 1b as a storage unit for storing the sensor signal input to the input unit 1a, and a sensor stored in the memory 1b A liquid crystal panel 1c as a display unit for displaying signal waveforms and the like, a key input unit 1d having a plurality of keys (not shown), and a CPU (central processing unit) 1e as an analysis unit for analyzing the sensor signals. have. The key input unit 1d, the keyboard 2 and the mouse 3 constitute an analysis instruction input unit.

FIG. 2 is a block diagram for explaining the details of the main part on the input side of the test apparatus main body 1, and FIG. 3 is a block diagram for explaining the details of the main part on the control side of the test apparatus main body 1. Is shown.

As shown in FIG. 2, an input unit 1a (shown in FIG. 1) of the test apparatus main body 1 is a PMG (speed detection generator).
An input circuit 21 to which a generator voltage signal is input via a PT, a shunt resistor 22 to which a generator current signal is input via a clamp CT, and an input range to which a guide vane opening detection signal is input A switching circuit 23, an output signal from the insulation input circuit 21, the shunt resistor 22, and the input range switching circuit 23, and a pressure sensor 4 for detecting water pressure.
The level conversion circuit 24 to which the water pressure detection signal from 1 and the generator speed signal from the SSG (synchronous signal generator) are input.
A filter circuit 25 for removing unnecessary noise from an output signal from the level conversion circuit 24, an analog multiplexer 26 for sequentially selecting an output signal from the filter circuit 25 and outputting an analog signal, and an on / off input signal And a digital input / output circuit 29 to which an output signal of the insulation input circuit 28 is inputted and which includes a start signal output section for outputting a start signal.
And an A / D converter 36 (shown in FIG. 3) for A / D (analog / digital) conversion of an analog signal from the analog multiplexer 26.

The input range switching circuit 23 sets the range to 500, 1000, 200 according to the type of the displacement detector 42.
It can be switched to four ways of 0.5000 mm (stroke). Further, the filter circuit 25 can switch the filter characteristic to any one of the cutoff frequencies of 10, 30, 50, 100 Hz or no cutoff.

The test apparatus main body 1 is provided with a changeover switch SW2 as a signal selection section for selecting either the generator voltage signal or the generator rotation speed signal from the level conversion circuit 24, and the changeover switch SW2. A counter circuit 2 as a rotation speed detecting unit for counting either the selected generator voltage signal or the generator rotation speed signal
7 is provided.

As shown in FIG. 3, the A / D converter 36 is connected to the CPU 1e via a bus.
U1e also operates as a start condition determining unit that determines a start condition for starting recording and an input conversion value calculation unit that calculates an input conversion value. The memory 1b is connected to the CPU 1e via a bus, and the memory 31 also operates as a delay unit. A liquid crystal panel 1c, a key input unit 1d, and a hard disk 34 as a data storage unit are connected to the CPU 1e, and a counter circuit 27 and a digital input / output circuit 29 (shown in FIG. 2) are connected via a bus. Further, a keyboard 2, a mouse 3,
The ZIP drive 4 and the printer 5 are connected.
Further, an AC / DC power supply unit 35 that converts an AC voltage (100 V AC) input from the uninterruptible power supply device 10 via the power switch SW <b> 1 to a DC voltage supplies power to each unit in the test apparatus main body 1.

The details of the input elements connected to the test apparatus main body 1 are as follows (1) to (6).

(1) Voltage input 2 circuits A voltage signal of an AC voltage of 0 to 200 V which is input via a PT from a PMG (speed detection generator). (2) Current input 2 circuit A current signal of an alternating current of 0 to 10 A input via the clamp CT. (3) Revolution input 2 Revolution signals of DC voltage 0-5V from SSG (synchronous signal generator). (4) Displacement detector input 4 circuits A detection signal of a DC voltage of 0 to 5 V from a displacement detector 42 for detecting a displacement such as a guide vane (or runner vane, pressure suppressor, nozzle, deflector) opening degree. (5) Pressure sensor input 4 circuits DC current 4 to 20 from pressure sensor 41 for detecting water pressure
mA detection signal. (6) ON / OFF input 6 circuits Contact input signals from various devices. In this governor testing device, the input elements (1) to (3)
By using a circuit, it is possible to perform a test by simultaneously measuring signals from two generators.

In the speed governor test apparatus having the above configuration, FIG.
As shown in Fig. 7, after the input elements of the generator voltage, the generator current, the water pressure, the guide vane opening, the generator speed, and the on / off are connected to the test apparatus main body 1, the key input section 1d is operated by a key operation to enter a standby state. Then, the signals of the input elements other than the on / off input are sequentially selected by the analog multiplexer 26, and the measurement data analog / digital converted by the A / D converter 36 is stored in the memory 31 together with the on / off input data.
And this sampling process is repeated every sampling clock cycle.

Next, the memory 31 is started by manual start or by start (trigger) judgment.
The input data is stored for a set time. At this time, the measurement data sampled in advance is held in the memory 31 when the acquisition is started by the trigger determination, so that the measurement data is acquired from the measurement data a predetermined time (1 second) before the trigger point. The trigger determination is performed when at least one of the measured data of the generator current (two elements) becomes equal to or less than a predetermined value, or when one of the on / off inputs (six elements) is turned on (or off). Is determined by determining that the start condition for starting the operation is satisfied.

Then, after the end of the recording, as shown in FIG.
The waveform of the measurement data is displayed on the liquid crystal display panel 32 (shown in FIG. 3). In FIG. 8, the vertical axis represents the swing width of each input element (excluding the contact point), and the horizontal axis represents the time axis. Also, set the time axis to 0.
The waveform is divided into five every 5 seconds, and the waveform from the left side in the figure is the waveform before activation for one second, and the waveform after activation is 1.5 seconds. Further, based on the collected measurement data, the following change rates {V, {N,}
Calculate P, and ΔV = ((maximum voltage−voltage before cutoff) / rated voltage) × 10
0 [%] △ N = ((maximum rotation speed-rotation speed before cutoff) / rated rotation speed)
× 100 [%] △ P = ((maximum water pressure-static water pressure at stop) / static head difference at stop)
× 100 [%] However, voltage before cut-off = voltage before fixed time from trigger point Number of revolutions before cut-off = number of revolutions before fixed time from trigger point Maximum water pressure = input value + water turbine specified position ± pressure head mounting position Static when stopped Water pressure = Reservoir water level-Water turbine designated position Static head difference at stop = Reservoir water level-Floodway water level Calculated rate of change △ V (2 elements), △ N (2 elements), △ P (4
) Are displayed together with the waveform (shown in the upper left of FIG. 8). Further, the maximum value of each input element is obtained based on the collected measurement data, and the maximum value is displayed together with the waveform (shown on the right side of FIG. 8).

Further, with respect to the collected measurement data,
After performing time measurement and the like to be described later, a waveform (see FIGS. 11 and 12) is printed, and a report is printed in a predetermined format (see FIG. 13) with the analysis results and the like put together.

Thereafter, if necessary, the measurement data stored in the memory 1b is stored as a file in the hard disk 34, and if necessary, the file stored in the hard disk 34 is read out to the memory 1b and displayed again on the liquid crystal panel 1c. Analysis and printing.

FIGS. 4 to 7 are flowcharts showing the general flow, the standby state processing, the waveform processing, and the setting processing of the governor testing apparatus, respectively. Hereinafter, the operation of the governor test apparatus will be described with reference to FIGS.

First, the processing shown in FIG. 4 is started, and a menu screen is displayed on the liquid crystal panel 32 in step S1.

Next, the process proceeds to step S2, where it is determined whether or not there is a key input. If it is determined that there is a key input, the process proceeds to steps S3 to S8 corresponding to the input key, while there is no key input. , The step S2 is repeated. That is, the key input in step S2 is "F
In the case of "1", the process proceeds to step S3, where a standby state is set,
If the input key is "F2", the flow advances to step S4 to perform waveform processing. If the key input in step S2 is "F3", the flow advances to step S5 to perform the processing of the millisecond counter. If the key input is "F4", the flow advances to step S6 to perform the setting processing. Do. further,
If the key input in step S2 is "F5", the flow advances to step S7 to perform reference waveform processing, and if the input key is "F7", the flow advances to step S8 to perform form printing processing. . If the key input in step S2 is "F8", the display of the menu screen is terminated.

In the processing of the millisecond meter in step S5, the time from the start of the first element (or manual) of the on / off input to the change of another element of the on / off input is measured. In the processing of the reference waveform in step S7, the layout of the waveform display screen is determined in advance before recording. That is, the display position and the swing width of the waveform are set by the waveform movement and the scale setting. In the form printing process of step S8, the collected measurement data is stored in a form (FIG. 13).
And print it.

In the standby state processing, it is determined in step S11 shown in FIG. 5 whether or not there is a key input. If there is a key input, the process proceeds to step S21. Proceed to. In this standby state, the CPU 1e calculates an input conversion value based on the sampled measurement data of each input element, and displays the calculated input conversion value and the on / off input state on the liquid crystal panel 3.
2 and memory 3 for each sampling period.
1 sequentially stores measurement data and on / off input data.

Next, in step S12, it is determined whether or not automatic recording is performed, that is, whether or not to perform recording is determined by a trigger determination. Then, if it is determined in step S12 that the automatic operation is performed, the process proceeds to step S13. If it is determined that the automatic operation is not performed, the process returns to step S11.

Next, it is determined in step S13 whether or not there is a trigger. If there is a trigger, the process proceeds to step S14, while if there is no trigger, the process returns to step S11.

Next, after the recording is started in step S14, the process proceeds to step S15, where it is determined whether or not the stop (F2) is performed. If the stop is determined, the step S16 is skipped. The process proceeds to collect a set time (for example, any one of 5, 10, 20, 40, and 60 seconds).

Then, the flow advances to step S17 to end the recording, and the flow advances to step S32 shown in FIG.

On the other hand, in step S21, it is determined whether or not the start (F1). If the start is determined, the process proceeds to step S14. If the start is not determined, the process proceeds to steps S22 to S24 (and the steps in FIG. Proceed to S1).

That is, if the key input at step S11 is "F5", the process proceeds to step S22, where the hydraulic pressure m
A switching processing is performed, and when the input key is “F6”, the process proceeds to step S23, and processing of calibration value measurement is performed.
Further, when the key input in step S11 is "F7", the process proceeds to step S24, where the fully closed / fully opened process is performed. When the input key is "F8", the process returns to step S1 in FIG. .

In the process of switching the hydraulic pressure mA in step S22, the numerical value of the hydraulic pressure value is switched to m units or mA units. In the calibration value measurement processing in step S23, the calibration values of the voltage, the number of revolutions, and the hydraulic pressure input are measured.
The measured calibration values can be displayed and printed. Further, the fully closed /
In the fully open process, the fully closed value of the displacement input when the guide vane or the like is fully closed and the fully open value of the displacement input when the guide vane is fully opened are measured.

In the waveform processing shown in FIG. 6, after the file is read in step S31, the process proceeds to step S32, where the waveform is displayed on the liquid crystal panel 32.

Next, the process proceeds to step S33, where it is determined whether or not there is a key input. If there is a key input, steps S34 to S40 corresponding to the input key (and FIG.
If there is no key input, step S33 is repeated. That is, if the key input in step S33 is "F1", the process proceeds to step S34, and the maximum value is changed. If the input key is "F2", the process proceeds to step S35 to perform enlargement / reduction. . If the key input in step S33 is "F3", the flow proceeds to step S36 to perform time measurement, and if the input key is "F4", the flow proceeds to step S37 to perform waveform movement. Further, if the key input in step S33 is "F5", the flow proceeds to step S38 to perform level measurement. If the input key is "F6", the flow proceeds to step S39 to perform waveform printing and input. If the pressed key is "F7", the process proceeds to step S40, where the data is stored. If the key input in step S33 is "F8", the process returns to step S1 in FIG.

The change of the maximum value in step S34 is performed by moving the cursor L1 to the point of the maximum value of the designated input element ("voltage 1" in FIG. 9) as shown in FIG.
The position specified by the cursor L1 is updated as the maximum value.
The enlargement / reduction in step S35 is performed by changing the display width of the waveform displayed on the liquid crystal display panel 32 to 2.5, 5, 10, 20,
By selecting from 40 and 60 seconds, the waveform is displayed with the selected display width. Further, as shown in FIG. 10, the time measurement in step S36 includes two cursors L2 and L3.
Is moved right and left, and two measurement points are designated by the cursors L2 and L3 to measure the time between the measurement points. For example, as shown in FIG. 14, for the guide vane, the immobility time τ, the first closing time T1, the second
The closing time T2 and the equivalent closing time TC, the immobility time τ and the equivalent closing time TC for the runner vane / nozzle / deflector, and the immobilization time τ, the opening time and the closing time for the pressure suppressor are measured. At this time, the time of the on / off signal (relay operation time or the like) can also be measured based on the display waveform of the on / off input. Then, the measured various times are stored in the hard disk 34.

In this time measurement, as shown in the example of FIG. 15, auxiliary lines L4 to L6 can be drawn on the displayed waveform. Specifically, an arbitrary point on the waveform screen is determined as a reference point using the mouse 3 (shown in FIG. 1).
When the position of the second point is determined, a line segment connecting the reference point and the second point is drawn. Vertical lines, horizontal lines, and oblique lines can be drawn on the drawn line segments as needed, and the drawn line segments can be moved. Further, the waveform movement in step S37 is performed by selecting an input element name on the screen on which the waveform is displayed, and
By instructing the vertical movement, the waveform of the selected input element moves in the vertical direction, and the scale of the waveform of the selected input element, that is, the swing width is set in the range of 0 to 200 mm. In this case, the input conversion value does not change even if the waveform is moved or the scale is changed.

In the level measurement in step S38, the level at the cursor position of the waveform of each input element is displayed. In the waveform printing in step S39, as shown in FIGS. 11 and 12, the waveform is printed, and the maximum value, the minimum value, and the change rate of each input element are printed on the last page. Also,
In storing the data in step S40, the measurement data stored in the memory 1b is stored in the hard disk 34 together with the maximum value, the minimum value, the rate of change, and the like.

In the setting process of FIG. 7, it is determined whether or not there is a key input in step S41, and if there is a key input, steps S42 to S42 corresponding to the input key are performed.
While proceeding to S45 (and step S1 shown in FIG. 4), if there is no key input, step S41 is repeated. That is, if the key input in step S41 is "F1", the flow proceeds to step S42, and the generator is set. If the input key is "F2", the flow proceeds to step S43 to set the function. . If the key input in step S41 is "F3", the flow advances to step S44 to calibrate the apparatus. If the input key is "F7",
Proceeding to step S45, the setting items are printed. If the key input in step S41 is "F8", the process returns to step S1 in FIG.

In the setting of the generator in step S42,
The name of the place where the generator is installed, the equipment number, the date of inspection, the rating of the generator, the guaranteed value, the PT ratio, the CT ratio, etc. are set. Also,
In the function setting of step S43, the type of the turbine, the trigger setting, and the like are set. In the calibration of the apparatus in step S44, the head value for each pressure sensor 41 is set to 5, 10, 20, 30,
Select from 35, 50 kgf / cm ² and set the sensor calibration data. For example, if the head value is 50 kgf /
cm ² , calibration data (in units of mA) of the pressure sensor 41 at three points of 0, 20, 50 kgf / cm ² is set, and the detection signal of the pressure sensor 41 is set based on the set calibration data. A pressure (kgf / cm ² unit) which is an input conversion value for (0 to 40 mA) is obtained. In the printing of the setting items in step S45, each set item is printed by the printer 5 (shown in FIG. 1).

As described above, according to the speed governor test apparatus, the signal is directly connected to the test apparatus main body 1 without connecting the signal from the detector to the recorder via many devices. The connection operation can be simplified, and the data can be analyzed in a short time and easily. Therefore, labor and time can be reduced. Also, instead of the printed waveform data being read by a person, analysis items and analysis points are specified for the waveform on the display screen by an analysis instruction input unit (key input unit 1d, keyboard 2 and mouse 3). Since the measurement data is analyzed by the unit (CPU 1e), data reading errors can be reduced.

Further, from the point in time when the trigger condition for starting the above-mentioned acquisition (determination of the level of the generator current at a predetermined current value or determination of ON or OFF of the on / off input) is satisfied, the information of the generator is obtained from the state before starting. Can be stored, and the rate of change of the measurement data before and after the trigger point (ΔV, ΔN,
ΔP) is obtained.

Further, a start signal indicating the start of recording from the digital input / output circuit 29 as the start signal output unit is used to start another test apparatus or measuring instrument, so that this speed governor test apparatus can be connected to another apparatus. Can be operated simultaneously.

The analysis result by the CPU 1e as the analysis unit is displayed on the liquid crystal panel 32 as the display unit, whereby the analysis result and the analysis point are designated while confirming the analysis result, and the analysis is performed by the CPU 1e. This makes it possible to appropriately obtain necessary analysis data according to the purpose of the test.

Since the printer 5 prints the waveform of the measurement data stored in the memory 31 in a predetermined format and prints the test data (analysis result and the like) in a predetermined format (for example, a form). The organization of test results can be performed easily in a short time.

In addition to changing the display position or shake width of the waveform displayed on the liquid crystal panel 1c to a display position or an appropriate shake width that makes it easy to see the waveform, the waveform printed on the printer 5 according to the display position or shake width. Since the print position and swing width of the image change, the degree of freedom of display and print contents is increased.

In the load shedding test, a voltage signal of a speed detection generator (PSG) for detecting the rotation speed of the generator is selected by the changeover switch SW2, and based on the voltage signal of the speed detection generator. In the emergency stop test, the sudden stop test, the slow stop test, etc., in which the voltage signal of the generator for speed detection becomes zero while the rotation speed of the generator is detected by the counter circuit 27, the synchronous signal generator is operated by the changeover switch SW2. (SSG) synchronization signal is selected, and the counter circuit 27 detects the number of revolutions of the generator based on the synchronization signal. Therefore, it is possible to detect the rotation speed at the time of another test in which the voltage signal of the speed detection generator becomes zero.

In the waveform processing screen shown in FIG. 10, the measurement points are designated by the cursors L1 and L2, and the time between the measurement points is measured. Therefore, the time measurement between one input element or an arbitrary input element is performed. And the required time measurement data can be obtained freely. Although the cursors L1 and L2 indicate the measurement points of all the input elements at the same time, the measurement points may be indicated for each input element.

Also, by using two circuits for the input elements of the generator voltage, the generator current, and the number of revolutions, it is possible to perform a test by simultaneously measuring signals representing information of the two generators. is there.

The measurement data stored in the memory 1b is stored in the hard disk 34 for each test, the measurement data is read out from the hard disk 34 again into the memory 1b, and the measurement data read out into the memory 1b is stored in the liquid crystal panel. 1c or can be analyzed by the CPU 1e, and a plurality of measurement data can be managed.

Further, since the input conversion value is calculated by the CPU 1e based on the signal input to the input section or the measurement data stored in the memory 1b, it is necessary to adjust the swing width of the recorder as in the prior art. There is no need to adjust the offset and gain of the input device (such as a level converter), and the level adjustment for input conversion becomes unnecessary.

In the above embodiment, the printer 5 which is separate from the test apparatus main body 1 is used as the print section. However, the test apparatus main body may be provided with a print section, and a keyboard as an analysis instruction input section may be used. At least one of the mice may be provided in the test apparatus main body.

In the above embodiment, the generator voltage,
Equipped with two input circuits for the generator current and the number of revolutions, respectively.
Although the description has been given of the governor testing apparatus capable of coping with the simultaneous testing of the governors of two generators, the input circuit is provided so as to be able to cope with the testing of the governor of one or more generators. May be used.

Further, in the above-described embodiment, the governor testing device for testing the governor for adjusting the rotation speed of the hydraulic power generator has been described. The present invention may be applied to a governor test device that tests a governor that adjusts speed.

[0074]

As is apparent from the above description, the speed governor test apparatus according to the first aspect of the present invention provides a power generator for a hydraulic power generator such as a generator voltage, a generator current, a rotation speed, a water pressure, and a guide vane opening. The signal representing the information of the generator is input to the input section, the signal representing the information of the generator input to the input section is stored in the storage section, and the waveform of the signal representing the information of the generator stored in the storage section is represented by In addition to displaying on the display unit, the analysis item and the analysis point are specified by the analysis instruction input unit for the waveform displayed on the display unit, and the maximum and minimum values of measurement data, various times, and the change rate A test of a governor that adjusts the rotation speed of the generator is performed by analyzing the above.

Therefore, according to the governor test apparatus of the first aspect of the present invention, by directly inputting the signal representing the information of the generator to the input section, the connection of the equipment can be simplified and the input is performed. By analyzing the signal waveform by the analysis unit in accordance with the analysis content specified for the waveform displayed on the display unit, data analysis can be performed quickly and easily, and labor and time can be reduced. Can be. In addition, since the analysis unit analyzes the measured data instead of reading the printed waveform data, a data reading error can be significantly reduced.

According to a second aspect of the present invention, in the speed governor test apparatus according to the first aspect, the starting condition determining unit activates the signal indicating the information of the generator input to the input unit. When it is determined that the condition is satisfied, the signal representing the information of the generator delayed by the signal delay unit is stored in the storage unit for a predetermined time. A signal representing machine information can be stored, and the rate of change of the signal waveform before and after the start point can be obtained.

According to a third aspect of the present invention, there is provided a speed governor test apparatus according to the second aspect, wherein the starting condition determining unit inputs the signal indicating the information of the generator input to the input unit. If it is determined that the above-mentioned start conditions are satisfied, a start signal indicating the start of recording is output from the start signal output unit.
By using the start signal indicating the start of the recording for starting other test apparatuses and measuring instruments, the governor test apparatus and the other apparatus can be operated simultaneously.

According to a fourth aspect of the present invention, in the speed governor test apparatus according to any one of the first to third aspects, the analysis result by the analysis section is displayed on the display section. The analysis can be instructed by the analysis instruction input unit while the analysis result is being checked, and the analysis can be performed by the analysis unit, and necessary analysis data can be appropriately obtained according to the test purpose.

According to a fifth aspect of the present invention, there is provided a speed governor test apparatus according to any one of the first to fourth aspects, wherein the signal representing the information of the generator stored in the storage section. At least one of the waveform of the above and the analysis result by the analysis unit is printed by the printing unit in a predetermined format. By setting the printing format to a format such as a report in advance, the test result can be converted into a report or the like. It is not necessary to transcribe and affix the test results to the test results, and the test results can be easily arranged in a short time.

In the speed governor testing apparatus according to the present invention, the display position or swing of the waveform of the signal representing the information of the generator displayed on the display section is provided. It is possible to change at least one of the widths and to print on the printing unit at the display position and the swing width of the signal waveform indicating the information of the generator displayed on the display unit, so that the degree of freedom of the display and the print content is reduced. spread.

According to a seventh aspect of the present invention, in the speed governor test apparatus according to any one of the first to sixth aspects, in the load shedding test, the rotation speed of the generator is controlled by a signal selector. A voltage signal of the speed detection generator for detecting the speed is selected, and based on the voltage signal of the speed detection generator, the rotation speed of the generator is detected by the rotation speed detection unit, while the speed detection generator is In an emergency stop test, a sudden stop test, a slow stop test, etc. in which the voltage signal of the generator becomes zero, the synchronizing signal of the synchronizing signal generator for the generator is selected by the signal selector, and the synchronizing of the synchronizing signal generator is performed. Since the rotation speed of the generator is detected by the rotation speed detection unit based on the signal, the rotation speed can be detected in another test in which the voltage signal of the speed detection generator becomes zero.

According to an eighth aspect of the present invention, there is provided the governor test apparatus according to any one of the first to seventh aspects, wherein the analysis instruction input section displays the display displayed on the display section. One of the waveforms of the signal representing the information of the generator
Two measurement points are respectively designated for one input element, or measurement points are designated for two input elements, respectively, and the analysis unit interposes between the measurement points designated by the analysis instruction input unit. Since time is measured, time can be measured with any input element, and necessary time measurement data can be obtained freely.

According to a ninth aspect of the present invention, there is provided a speed governor test apparatus according to any one of the first to eighth aspects, wherein the input section represents information of two or more generators. Since a signal can be input, a test can be performed by simultaneously measuring signals representing information of two or more generators.

According to a tenth aspect of the present invention, there is provided the governor test apparatus according to any one of the first to ninth aspects, wherein the signal representing the information of the generator stored in the storage unit is stored in the storage unit. The data is stored in the data storage unit for each test, the data of the signal representing the information of the generator is read from the data storage unit to the storage unit, and the signal representing the information of the generator read out to the storage unit is stored. Can be displayed again on the display unit or analyzed by the analysis unit.

According to an eleventh aspect of the present invention, there is provided the governor test apparatus according to any one of the first to tenth aspects, wherein the signal representing the information of the generator input to the input section is provided. Since the input conversion value is calculated by the input conversion value calculation unit based on the signal indicating the information of the generator stored in the storage unit, the input device (level) is used to adjust the swing width of the recorder as in the related art. Offset of converter, etc.)
There is no need to adjust the gain, and there is no need to adjust the level for input conversion.

[Brief description of the drawings]

FIG. 1 is a schematic configuration diagram of a governor test apparatus according to an embodiment of the present invention.

FIG. 2 is a block diagram showing details of a main part on an input side of the governor testing device.

FIG. 3 is a block diagram showing details of a main part on a control side of the governor testing apparatus.

FIG. 4 is a flowchart showing a general flow of the governor test apparatus.

FIG. 5 is a flowchart showing a process in a standby state of the governor testing device.

FIG. 6 is a flowchart showing waveform processing of the governor test apparatus.

FIG. 7 is a flowchart showing a setting process of the speed governor test apparatus.

FIG. 8 is a diagram showing a display screen of a waveform process of the governor test apparatus.

FIG. 9 is a view showing a display screen when a maximum value is changed in the waveform processing of the governor testing apparatus.

FIG. 10 is a view showing a display screen when time is measured in the waveform processing of the governor test apparatus.

FIG. 11 is a diagram illustrating an example of waveform printing.

FIG. 12 is a diagram illustrating an example of printing of the last page following FIG.

FIG. 13 is a diagram showing an example of a form printing form.

FIG. 14 is a diagram illustrating time measurement.

FIG. 15 is a diagram showing an example of a plot in the time measurement.

[Explanation of symbols]

DESCRIPTION OF SYMBOLS 1 ... Governor test apparatus, 1a ... Input part, 1b ... Memory, 1
c ... liquid crystal panel, 1d ... key input section, 1e ... CPU, 2 ...
Keyboard, 3 mouse, 4 ZIP drive, 5 printer, 10 uninterruptible power supply, 21, 28 isolated input circuit, 22 shunt resistor, 23 input range switching circuit,
24: Level conversion circuit, 25: Filter circuit, 26:
Analog multiplexer, 27 ... Counter circuit, 29 ...
Digital input / output circuit, 34 ... Hard disk, 35 ... A
C / DC power supply, 36 A / D converter, SW1 power switch, SW2 changeover switch.

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[Procedure amendment]

[Submission date] January 7, 2000 (2000.1.7)

[Procedure amendment 1]

[Document name to be amended] Statement

[Correction target item name] Claim 1

[Correction method] Change

[Correction contents]

[Procedure amendment 2]

[Document name to be amended] Statement

[Correction target item name] 0005

[Correction method] Change

[Correction contents]

[0005]

According to a first aspect of the present invention, there is provided a speed governor test apparatus for testing a speed governor for adjusting a rotating speed of a generator,
An input unit to which a signal representing information on the generator is input, a storage unit for storing a signal representing information on the generator input to the input unit, and information on the generator stored in the storage unit a display unit for displaying the signal waveform representing the, necessary for analyzing the analysis items and the analysis item with respect to the waveform of the signal representing the information of the generator which is displayed on the display unit
An analysis instruction input unit to which the analysis point of the waveform is input, and the analysis item input by the analysis instruction input unit
And an analysis unit for analyzing a signal representing the information of the generator according to the analysis point .

[Procedure amendment 3]

[Document name to be amended] Statement

[Correction target item name]

[Correction method] Change

[Correction contents]

[0074]

As is apparent from the above description, the speed governor test apparatus according to the first aspect of the present invention provides a power generator for a hydraulic power generator such as a generator voltage, a generator current, a rotation speed, a water pressure, and a guide vane opening. The signal representing the information of the generator is input to the input section, the signal representing the information of the generator input to the input section is stored in the storage section, and the waveform of the signal representing the information of the generator stored in the storage section is represented by Displayed by the display unit and necessary to analyze the analysis items and their analysis items for the waveform displayed on the display unit
The analysis point of the above waveform is designated by the analysis instruction input unit, and the analysis unit analyzes the maximum value, the minimum value, various times, the rate of change, etc. of the measurement data to adjust the rotation speed of the generator. This is to test the speed machine.

[Procedure amendment 4]

[Document name to be amended] Statement

[Correction target item name] 0075

[Correction method] Change

[Correction contents]

Therefore, according to the governor test apparatus of the first aspect of the present invention, by directly inputting the signal representing the information of the generator to the input section, the connection of the equipment can be simplified and the input is performed. The waveform of the signal follows the analysis items and analysis points specified for the waveform displayed on the display unit.
By analyzing the analyzing unit I, short analysis of data within and can be easily, it is possible to reduce the labor and time. In addition, since the analysis unit analyzes the measured data instead of reading the printed waveform data, a data reading error can be significantly reduced.

 ──────────────────────────────────────────────────続 き Continuing on the front page (72) Inventor Hiroshi Kobayashi 1-22-17 Kamikita, Hirano-ku, Osaka-shi, Osaka Inside the Kyokei System Co., Ltd. (72) Eiji Nishikawa 1 Kamikita, Hirano-ku, Osaka-shi, Osaka No. 22-17, F-term in Kyokei System Co., Ltd. (reference) 5H590 AA09 AA22 CA11 EA05 EA07 FB01 GB05 HA02 HA04 HA17 HA26 HA27 HB02 HB03 JA02 JA19 JB01 JB02 JB04 JB15 JB16 JB18 KK03

Claims (11)

[Claims] 1. A governor test apparatus for testing a governor that adjusts a rotation speed of a generator, wherein: an input unit to which a signal representing information on the generator is input; A storage unit for storing a signal representing information on the generator, a display unit for displaying a waveform of a signal representing the information on the generator stored in the storage unit, and a display unit for the generator displayed on the display unit. An analysis instruction input unit for inputting an analysis instruction for a waveform of a signal representing information; and an analysis unit for analyzing a signal representing information on the generator in accordance with the analysis instruction input from the analysis instruction input unit. A governor testing device, comprising: 2. The speed governor test apparatus according to claim 1, wherein it is determined whether or not the signal indicating the information of the generator input to the input unit satisfies a start condition for starting the acquisition. An activation condition determination unit; and a signal delay unit that delays a signal representing the information of the generator input to the input unit. The storage unit stores a signal indicating that the activation condition determination unit represents the information of the generator. When the controller determines that the start condition is satisfied, a signal representing information of the generator delayed by the signal delay unit is stored for a predetermined time. 3. The speed governor test apparatus according to claim 2, wherein the starting condition determining unit determines that a signal representing the information of the generator input to the input unit satisfies the starting condition. A speed governor test apparatus comprising a start signal output unit for outputting a start signal indicating start of recording. 4. The speed governor test apparatus according to claim 1, wherein an analysis result by the analysis unit is displayed on the display unit. 5. The speed governor test apparatus according to claim 1, wherein a waveform of a signal representing information on the generator stored in the storage unit and a result of analysis by the analysis unit are provided. A speed governor test apparatus comprising a printing unit for printing at least one of them in a predetermined format. 6. The speed governor test apparatus according to claim 5, wherein the display unit is capable of changing at least one of a display position or a swing width of a waveform of a signal representing information of the generator displayed. The printing unit prints the waveform of the signal representing the information of the generator on the display position and the amplitude of the waveform of the signal representing the information of the generator displayed on the display unit. Speed test equipment. 7. The speed governor test apparatus according to claim 1, wherein the signal indicating the information of the generator input to the input unit includes at least a rotation speed of the generator. A voltage signal of the speed detecting generator to be detected and a synchronizing signal of the synchronizing signal generator for the generator, wherein the voltage signal of the speed detecting generator input to the input unit and the synchronizing signal generator A signal selection unit for selecting one of the synchronization signals, and a voltage signal of the speed detection generator selected by the signal selection unit and a synchronization signal of the synchronization signal generator. A speed detector for detecting the speed of the generator. 8. The speed governor test apparatus according to claim 1, wherein the analysis instruction input unit causes a waveform of a signal representing information of the generator displayed on the display unit. Either two measurement points are designated for one of the input elements, or two measurement points are designated for two of the waveforms of the signal indicating the information of the generator displayed on the display unit. Wherein the analysis unit measures the time between the measurement points specified by the analysis instruction input unit. 9. The speed governor test device according to claim 1, wherein the input unit is capable of inputting a signal representing information of two or more generators. Governor testing equipment. 10. The speed governor test apparatus according to claim 1, wherein a plurality of signal data representing information on the generator stored in the storage unit can be stored, and A speed governor test device, comprising: a data storage unit capable of reading stored data of a signal representing information on the generator into the storage unit. 11. The speed governor test apparatus according to claim 1, wherein a signal representing the information of the generator input to the input section or the power generation stored in the storage section. A speed governor test apparatus, comprising: an input conversion value calculation unit that calculates an input conversion value based on a signal representing machine information.