KR100827827B1 - Field test kit for fault pressure rapid relay - Google Patents

Abstract

A field test kit for a fault pressure rapid relay is provided to maintain a uniform pressure and exhaust air by mounting a ball valve. A field test kit for a fault pressure rapid relay(10) includes a cross connector(20), a pressure device(30), a ball valve(200), and a digital test device(100). The cross connector is installed on a test pressure port installed on a housing cap of the fault pressure rapid relay. The pressure device is installed on a port of one side of the cross connector and presses air inside the fault pressure rapid relay. The ball valve is installed on a port of the other side of the cross connector and closes the port in pressing the air and rapidly exhausts the pressed air by a user's control after a predetermined time above the predetermined pressure. The digital test device is installed on a port of an upper end of the cross connector. The digital test device checks and digitally displays a pressure, automatically controls a pressing display and a standby display, and displays a normal operation by checking a fault pressure detection signal from an output connector of the fault pressure rapid relay.

Description

Field Test Kit for Fault Pressure Rapid Relay < RTI ID = 0.0 >

1 is a block diagram of a test apparatus for an impact hydraulic relay according to the prior art;

2 is a block diagram of a test apparatus for an impact hydraulic relay according to the present invention.

3 is a flowchart of a test apparatus for an impact hydraulic relay according to the present invention.

4 is an explanatory diagram of a rate of pressure change per unit time of the test apparatus for an impact hydraulic relay according to the present invention.

Description of the Related Art

10: Impact hydraulic relay 10a: Test pressure port

11: Output connector 20: Cross connector

30: pressure application device 100: digital test device

110: pressure sensor 120: A / D converter

130: Switch detecting unit 140: Microcomputer

150: LCD indicator 161: Power button

162: reset button 163: pressure indicator

164: Standby indicator 170: Power source

200: Ball valve

The present invention relates to an apparatus for testing an impact resistance relay (FPR) for an electric power transformer, and more particularly, to a test apparatus and a control method for an impact shock relay using a digital indicator, .

There are various protection devices and safety devices in the power transformer. Among them, Impulse Hydraulic Relay (FPR) is used as a device for detecting a sudden increase in the pressure of the insulating oil in the transformer (impact hydraulic pressure).

The impact hydraulic relay detects the pressure of the insulating oil of the transformer and does not operate at a gentle rise. When the oil pressure suddenly rises, the microswitch is activated to detect the shock hydraulic state.

It is necessary to be able to diagnose the change of characteristics or the abnormality in the state that the above impact hydraulic relay is installed in the transformer. For this diagnosis, a test apparatus for an impact hydraulic relay is used.

1 is a block diagram of a test apparatus for an impact hydraulic relay according to the prior art.

As shown in the figure, a cross connector 20 is provided on the test pressure port 10a of the impact hydraulic relay 10, and a pressure device (a squeeze valve And a pressure gauge 50 is installed at an upper end port of the cross connector 20. The connector 11 of the impact hydraulic relay 10 is connected to two of the test apparatuses 40 And the terminal 42 of the test apparatus is connected.

The test apparatus 40 includes a battery 41 inside the body, a light emitting display 43 at the front end of the body, and two terminals 43 connected to the rear end of the body. In the drawing, reference numeral 12 denotes a bleed valve which is a valve which is closed during a test or transformer operation and is intended to discharge air above the insulating oil at the time of initial installation.

In the apparatus for testing an impact hydraulic relay having the above configuration, the pressure device 30 is operated in a state in which a finger is put on the other port of the cross connector 20, that is, the open port in the figure, The pressure is increased and the pressure gauge 30 is observed while the pressurizing device 30 is operated. When the pressure gauge 30 reaches the predetermined pressure, the pressure is maintained for a predetermined time (for example, 30 seconds) So that the air is discharged at a high speed.

At this time, whether or not the indicator 43 installed at the end of the test apparatus 40 is turned on is checked to see whether the impact hydraulic relay operates normally.

However, in the case of testing the impact hydraulic relay in the above-described manner, it is necessary to close the open port of the cross connector with a finger to pressurize the pressure and remove it after a predetermined time to perform high-speed exhaust. Because of the difference of the pressure change depending on the degree of fingering or pressing the finger, the test pressure may not be maintained properly, and it is necessary to wait for 30 seconds and then to remove the finger. However, It is inconvenient and the open port of the cross connector must be blocked directly by the finger, so that it is very cold in the outside environment in winter, and the tester is very inconvenient.

SUMMARY OF THE INVENTION Accordingly, an object of the present invention is to provide a shock pressure hydraulic relay testing apparatus in which a ball valve is mounted as a means for maintaining a pressurized pressure and a rise to a predetermined pressure, a waiting time and an open time are automatically checked and displayed using a microcomputer , And a test device for an impact hydraulic relay capable of performing a very simple and reliable test by displaying whether the test result is normal through the LCD.

Further, the present invention is to provide a control method for controlling the test operation and determining normal and failure by control of the microcomputer of the digital test apparatus.

In order to accomplish the above object, the present invention provides a shock pressure hydraulic relay comprising: a cross connector installed on a test pressure port provided on a housing cap of an impact hydraulic relay;

A pressure device installed at one side port of the cross connector for pressurizing air into the impact hydraulic relay;

A ball valve provided at the other port of the cross connector to close the port at the time of pressurization and to rapidly exhaust the air pressurized by a user operation after a predetermined time elapses at a predetermined pressure or more;

A pressure display and a standby display are automatically controlled and displayed, and an impact oil pressure detection signal is checked from an output connector of the impact oil pressure relay to check whether the normal operation And a digital test apparatus for displaying a test pattern for the impact hydraulic relay.

The digital test apparatus includes:

A pressure sensor closing the upper port of the cross connector to check the pressure;

An A / D converter for converting a detection signal of the pressure sensor into a digital signal;

An indicator for pressurization indication and waiting indication, an LCD indicator for displaying the detection pressure, waiting time and test result;

A switch detecting unit for detecting an output signal from an output connector of the shock hydraulic relay;

And a control unit for controlling the pressure display and the standby display to check the detection signal of the switch detecting unit and to control the pressure change from the pressurized pressure to the switch signal detection point by a pressure change rate per unit time And a microcomputer for determining whether the pressure change rate per unit time falls within a predetermined range to determine whether the impulse hydraulic pressure relay is normal or faulty, and displaying the determined result.

The digital test apparatus includes a power button and a reset button, and includes a power unit for supplying operating power to each unit using a battery power source.

In the test apparatus of the present invention,

A first step of displaying a pressure indication when the power is turned on, and detecting and displaying a pressure when the user presses the pressure device through the pressure device;

A second step of resetting the pressure display to stop the pressure when the pressure detected in the first step becomes equal to or higher than a predetermined pressure, and performing a waiting display;

A third step of resetting the standby display and displaying the rapid evacuation when the waiting time has elapsed for a predetermined time determined in the second step;

A fourth step of detecting a pressure at an impact oil pressure detecting point by checking an impact oil pressure detection signal of the impact oil pressure relay when the user operates the ball valve and expedites rapid exhaustion in the third step of the exhaust display;

If the impact oil pressure detection signal is input in the fourth step, the difference between the initial pressure at the exhaust time point and the end pressure at the time of inputting the impact oil pressure detection signal is obtained in the third step and divided by the time varying from the initial pressure to the end pressure A fifth step of obtaining a pressure change rate per unit time;

A sixth step of determining that the pressure change rate per unit time obtained in the fifth step is equal to or greater than a predetermined pressure change rate per unit time, .

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

2 is a block diagram of a test apparatus for an impact hydraulic relay according to the present invention.

As shown therein, the present invention for achieving the object of the present invention comprises a cross connector (20) installed on a test pressure port (10a) provided in a housing cap of an impact hydraulic relay (10); A pressure device 30 installed at one side port of the cross connector 20 to pressurize air into the impact hydraulic relay 10; A ball valve (200) installed at the other port of the cross connector (20) for closing the port at the time of pressurization and for rapidly evacuating the pressurized air by a user operation after a predetermined time elapses at a predetermined pressure or more; A pressure display and a standby display are automatically controlled and displayed, and an output from the output connector (11) of the impact hydraulic relay (10) is displayed on the upper port of the cross connector (20) The pressure change rate per unit time is calculated by using the pressure at the exhaust point as the initial pressure and the pressure at the detection point as the termination pressure to determine whether the pressure change rate per unit time is within the predetermined reference range, And a digital test apparatus 100 for indicating whether or not the test apparatus 100 is operating.

Here, the ball valve 200 is a valve that can be selectively locked or unlocked by manual operation. In the initial pressurized state, the port of the cross connector 20 is closed to allow pressure to be applied. When the pressure exceeds a predetermined pressure, So as to perform rapid evacuation.

The digital test apparatus (100)

A pressure sensor 110 for closing the upper port of the cross connector 20 and checking the pressure; An A / D converter 120 for converting a detection signal of the pressure sensor 110 into a digital signal; Indicators 163 and 164 for pressurization display and standby display; An LCD display 150 for displaying a detection pressure, a waiting time, and a test result; A switch detecting unit 130 for detecting an output signal from the output connector 11 of the shock hydraulic relay 10; D converter 120 to control the pressure display and the standby display to check the detection signal of the switch detecting unit 130, and to detect the pressure from the pressure to the switch signal detection point And a microcomputer 140 for determining whether the pressure change rate per unit time falls within a predetermined range, determining whether the shock / pressure relay is normal / faulty, and displaying the determined result.

The digital test apparatus 100 includes a power button 161 and a reset button 162 and includes a power supply unit 170 for supplying operation power to the battery.

The present invention configured as above can test the operation state of the impact hydraulic relay 10 semi-automatically using the digital test apparatus 100 and the ball valve 200. [

3 is a control flowchart of a test apparatus for an impact hydraulic relay according to the present invention. The test method using the test apparatus of the present invention will be described with reference to this.

The test apparatus 100 of the present invention opens the test pressure port 10a provided on the upper surface of the impact hydraulic relay 10 and couples the cross connector 20 having the four-way port. And then pressurizing device 30 is coupled to one port. It can be configured as an electric pressure device, which can be configured as an electric pressure device such as a conventional blood pressure check device, and in the embodiment of the present invention, a squeeze valve as a manual pressure device is used as an example. A ball valve (200) is provided at the other port of the cross connector (20). The ball valve 200 is configured to close the port when the valve is locked and open the port when the valve is open, so that the ball valve 200 can be controlled by a manual operation and can also be constructed using an electric ball valve. When an electric ball valve or an electric pressure device is used, the microcomputer 140 of the digital test apparatus 100 automatically controls the pressurization, the atmospheric air, and the rapid evacuation.

The pressure sensor 110 of the digital test apparatus 100 is installed at the upper port of the cross connector 20. This is achieved by providing a pressure sensor inside a coupling connector (not shown) of the digital test apparatus 100 so as to be connected only to the upper port of the cross connector 20, and the output signal of the pressure sensor inside the coupling connector D converter 120 in the digital test apparatus 100 to configure the digital test apparatus 100. [

When the test preparation is completed in this manner, the test is started by pressing the power button 161 of the digital test apparatus 100. When the test is started, the test is proceeded semi-automatically by the control of the microcomputer 140 as shown in the control flow shown in FIG.

First, when the power is turned on, the pressure indicator 163 is turned on to indicate that it is in a pressurized state. When the user presses the pressure device 30 through the pressure device 30, the pressure is detected to display the current pressure on the LCD display 150 (S10).

If the pressure detected in the first step S10 becomes equal to or higher than a predetermined pressure, a second step (S20) is performed in which the pressure display LED is flickered to indicate that the pressurization is to be stopped and the standby indicator 164 is lit, . Here, the predetermined pressure is set in advance by experiment as a pressure for performing the operation test of the impact hydraulic relay 10. [

If the waiting time elapses for a predetermined time (e.g., 30 seconds) predetermined in the second step S20, a standby step LED is blinked to perform a third step (S30) to display rapid exhaustion. The indication of the rapid evacuation can be indicated by using the waiting indicator 164 to indicate rapid evacuation as a flashing indication.

If the user operates the ball valve 200 to see the exhaust display of the third step S30 and performs rapid exhaustion, the impact oil pressure detection signal of the impact oil pressure relay 10 is checked to detect the pressure at the shock oil pressure detection point (Step S40). Since the control bellows and the actuator bellows are moved in the same manner at the gentle pressure change, the actuator does not operate. If a rapid pressure difference occurs, the control bellows restricts the flow of the internal silicone hydraulic fluid due to the influence of the control orifice. Therefore, the actuator bellows is operated first to rotate the actuator, and the micro-switch is operated by the rotation of the actuator to detect the impact oil pressure, and the signal of the micro switch is output to the control panel through the output connector 11, And take protective measures based on the detection of the hydraulic pressure.

Therefore, in the test apparatus of the present invention, the switch detecting unit 130 detects that the microswitch is actuated by rapid evacuation after pressurization.

When the switch detecting unit 130 detects an impact oil pressure detection signal of the impact hydraulic relay 10, the microcomputer 140 detects the current pressure at that point.

When the impact oil pressure detection signal is inputted in the fourth step S40, the pressure at the time of exhausting is set as the initial pressure in the third step S30, and the pressure at the input point of the impact oil pressure detection signal is set as the end pressure, A fifth step (S50) of obtaining the pressure change rate per unit time by dividing the difference between the pressure and the termination pressure by the time taken to vary the initial pressure to the termination pressure is performed.

If the pressure change rate per unit time obtained in the fifth step S50 is equal to or greater than a predetermined pressure change rate per unit time, a sixth step S60 is performed. do.

4 is a characteristic diagram for explaining the pressure change rate per unit time of the digital test apparatus according to the present invention.

First, when the test is started and the pressurization is started, the pressure is gradually raised, and when the predetermined test pressure (for example, 3.2 psi) is reached, the pressurization is terminated and the standby mode is performed for a predetermined time . The reason for performing the standby mode in this way is that the pressure applied to the control bellows and the actuator bellows in the shock hydraulic relay wait for the time until equilibrium is established, and the waiting time is usually about 30 seconds. After the waiting time has elapsed as described above, the quick exhaust mode is performed. The pressure at this rapid evacuation point is set as the initial pressure, and the pressure at the time of evacuation is continuously checked.

Then, when an impact pressure detection signal is output from the impact pressure relay 10 and an impact pressure detection signal is detected by the switch detection unit 130, the pressure at this time is checked to be an end pressure, And the time taken until the detection point is obtained. Then, the differential pressure obtained by subtracting the end pressure from the initial pressure is divided by the time taken to calculate the rate of pressure change per unit time. If the calculated pressure per unit time is within the range of the pressure per unit time per predetermined time, it is judged as normal. If the pressure is out of the range, it is judged as a failure.

Therefore, in the past, only a certain pressure was applied to wait for the impact pressure relay to operate. However, in the present invention, it is possible to accurately determine whether the operation sensitivity is appropriate and to determine whether the shock / pressure failure is normal or faulty.

As described above in detail, the test apparatus for an impact-based hydraulic relay according to the present invention displays a digital display, a pressurization, an atmospheric, and an evacuation point. In addition, the present invention uses a ball valve as a means for rubbing pressure during pressurization and for rapid exhaust during exhaustion, so that it is possible for a user to maintain and exhaust the pressure stably and constantly without inconvenience. In addition, the present invention detects the operating point of the impact hydraulic relay and calculates the pressure change rate per unit time, determines whether the pressure change rate per unit time is within the normal range, and determines whether the pressure / And the operating sensitivity within the range can be tested and judged.

Claims (5)

A cross connector mounted on a test pressure port provided on a housing cap of the impact hydraulic relay; A pressure device installed at one side port of the cross connector for pressurizing air into the impact hydraulic relay; A ball valve provided at the other port of the cross connector to close the port at the time of pressurization and to rapidly exhaust the air pressurized by a user operation after a predetermined time elapses at a predetermined pressure or more; A pressure display and a standby display are automatically controlled and displayed, and an impact oil pressure detection signal is checked from an output connector of the impact oil pressure relay to check whether the normal operation And a digital test apparatus for displaying the test data. The digital test apparatus according to claim 1, A pressure sensor closing the upper port of the cross connector to check the pressure; An A / D converter for converting a detection signal of the pressure sensor into a digital signal; An indicator for pressurization indication and waiting indication, an LCD indicator for displaying the detection pressure, waiting time and test result; A switch detecting unit for detecting an output signal from an output connector of the shock hydraulic relay; And a control unit for controlling the pressure display and the standby display to check the detection signal of the switch detecting unit and to control the pressure change from the pressurized pressure to the switch signal detection point by a pressure change rate per unit time And a microcomputer for determining whether the pressure change rate per unit time falls within a predetermined range to determine whether the impact hydraulic relay is normal / faulty, and displaying the determined result. The digital test apparatus according to claim 1, And a power supply unit including a power button and a reset button and supplying operating power to the battery power source. 4. The method according to any one of claims 1 to 3, Wherein the ball valve and the pressure device comprise an electric ball valve and an electric pressure device that are automatically operated on / off controlled based on a control signal of the digital test device. A method for testing the operating state of an impact hydraulic relay for a power transformer by configuring a digital test apparatus using a microcomputer, A first step of displaying a pressure indication when the power is turned on, and detecting and displaying a pressure when the user presses the pressure device through the pressure device; A second step of displaying a standby state when the pressure detected in the first step is equal to or higher than a predetermined pressure and displaying the standby state; A third step of displaying the rapid evacuation when the waiting time has elapsed for a predetermined time predetermined in the second step; A fourth step of detecting a pressure at an impact oil pressure detecting point by checking an impact oil pressure detection signal of the impact oil pressure relay when the user operates the ball valve and expedites rapid exhaustion in the third step of the exhaust display; If the impact oil pressure detection signal is input in the fourth step, the difference between the initial pressure at the exhaust time point and the end pressure at the time of inputting the impact oil pressure detection signal is obtained in the third step and divided by the time varying from the initial pressure to the end pressure A fifth step of obtaining a pressure change rate per unit time; A sixth step of judging that the pressure change rate per unit time obtained in the fifth step is equal to or greater than a predetermined rate of pressure change per unit time, Control method of test equipment for impact hydraulic relays.

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