JP7247011B2 - Gate test controller - Google Patents

Description

Embodiments of the present invention relate to gate test controllers.

A dam management system that manages a dam remotely controls the opening and closing of dam gates. In the control of the dam gate, the administrator operates the gate control from the discharge operation device, and the gate panel drives the gate to control the opening and closing of the gate. To make an emergency stop of a gate when some abnormality occurs during gate control. 2. Description of the Related Art Conventionally, gate control tests are conducted to confirm that gates operate according to a normal sequence and an abnormal sequence in gate opening/closing control. The gate control test may be performed in the field environment or in the factory, but generally the test is performed in the factory. Since the gate board can only be constructed in the local environment, the factory test is conducted using a gate tester that simulates the gate board. In order to confirm the sequence when an abnormality occurs, it is necessary to simulate an abnormal situation, and the wiring between the machine side panel and the gate tester must be changed to a different wiring from that during normal operation. Therefore, in order to perform a gate control test, it is necessary to remove the electric wire inserted in the connector of the machine side panel and change the wiring. Therefore, it takes time and effort to change the wiring. Thus, conventionally, there were cases where gate control tests could not be easily performed.

JP 2014-58776 A Japanese Patent Application Laid-Open No. 2001-117628 JP-A-53-29434

A problem to be solved by the present invention is to provide a gate test control apparatus capable of easily performing a gate control test.

A gate test controller of an embodiment has a first button, a second button, and a control circuit. The first button indicates the open/closed state of the dam gate regardless of a signal input from the dam testing apparatus via one of a plurality of control lines respectively corresponding to a plurality of states representing the open/closed state of the dam gate. A signal indicating one of a plurality of states representing is forcibly output. A second button forcibly cuts off the signal input from the dam test device through any one of the plurality of control lines . A control circuit outputs a signal of a predetermined state according to the operation of the first button and the second button.

The figure which shows the system configuration|structure of the gate control test system of embodiment. 1 is an external view of a gate test control device according to this embodiment; FIG. The figure which shows the operation method of the forced button and the interruption|blocking button with respect to the test item of a gate control test. The figure which shows the internal structure of the gate test control apparatus in this embodiment. FIG. 2 is a diagram showing the configuration of a control circuit according to the embodiment; FIG. 4 is a diagram for explaining an interlock function in this embodiment; FIG. 4 is a diagram for explaining an interlock function in this embodiment; FIG. 4 is a diagram for explaining a method of operating the gate test control device during a gate control test according to the embodiment; FIG. 4 is a diagram for explaining a method of operating the gate test control device during a gate control test according to the embodiment; FIG. 4 is a diagram for explaining a method of operating the gate test control device during a gate control test according to the embodiment; FIG. 4 is a diagram for explaining a method of operating the gate test control device during a gate control test according to the embodiment; FIG. 4 is a diagram for explaining a method of operating the gate test control device during a gate control test according to the embodiment; FIG. 4 is a diagram for explaining a method of operating the gate test control device during a gate control test according to the embodiment; FIG. 4 is a diagram for explaining a method of operating the gate test control device during a gate control test according to the embodiment; FIG. 4 is a diagram for explaining a method of operating the gate test control device during a gate control test according to the embodiment; FIG. 4 is a diagram for explaining a method of operating the gate test control device during a gate control test according to the embodiment; FIG. 4 is a diagram for explaining a method of operating the gate test control device during a gate control test according to the embodiment; FIG. 4 is a diagram for explaining a method of operating the gate test control device during a gate control test according to the embodiment; FIG. 4 is a diagram for explaining a method of operating the gate test control device during a gate control test according to the embodiment; FIG. 4 is a diagram for explaining a method of operating the gate test control device during a gate control test according to the embodiment; FIG. 4 is a diagram for explaining a method of operating the gate test control device during a gate control test according to the embodiment; FIG. 4 is a diagram for explaining a method of operating the gate test control device during a gate control test according to the embodiment; FIG. 4 is a diagram for explaining a method of operating the gate test control device during a gate control test according to the embodiment; FIG. 4 is a diagram for explaining a method of operating the gate test control device during a gate control test according to the embodiment; FIG. 4 is a diagram for explaining a method of operating the gate test control device during a gate control test according to the embodiment; FIG. 4 is a diagram for explaining a method of operating the gate test control device during a gate control test according to the embodiment; FIG. 4 is a diagram for explaining a method of operating the gate test control device during a gate control test according to the embodiment;

A gate test control device according to an embodiment will be described below with reference to the drawings.
FIG. 1 is a diagram showing the system configuration of a gate control test system 100 according to an embodiment. The gate control test system 100 is a system for performing gate control tests. The gate control test system 100 is applied, for example, when performing a gate control test in a factory.
The gate control test system 100 includes a discharge operation device 10 , an input/output device 20 , a machine side panel 30 , a gate test control device 40 and a gate tester 50 .

The discharge operation device 10 outputs a start command including a command to open or close the gate and information on the target opening to the input/output device 20 according to the operation of the administrator. The discharge operation device 10 is configured using an FA personal computer or a PLC (programmable logic controller).
The input/output device 20 inputs and outputs information between the discharge operation device 10 and the machine side panel 30 . For example, the input/output device 20 transmits the activation command transmitted from the discharge operation device 10 and the target opening degree information to the machine side panel 30 . For example, the input/output device 20 receives a target opening answer and a target opening arrival signal from the machine side panel 30 . The input/output device 20 transmits the received target opening reach signal to the discharge operation device 10 . The input/output device 20 is configured using a PLC.

The machine side panel 30 transmits the activation command transmitted from the input/output device 20 to the gate tester 50 . The machine side panel 30 receives the opening degree and discharge amount from the gate tester 50 . In addition, the machine side panel 30 receives state information in gate opening/closing control from the gate test control device 40 . The state information is information indicating the state of opening or closing of the gate, such as fully open, open, closed and fully closed. Fully open means that the opening of the gate reaches the target opening and the gate is opened. Open indicates that the gate is open. Closed indicates that the gate is closed. Fully closed indicates that the opening of the gate when it is closed reaches the target opening and the gate is closed. The machine side board 30 is configured using a PLC.

The gate test control device 40 is a device capable of simulating an abnormal situation. The gate test control device 40 is provided between the machine side panel 30 and the gate tester 50 . Creating a simulation of an abnormal situation means creating a situation that makes it possible to recognize that an abnormal situation has occurred, even if it has not actually occurred.
The gate tester 50 simulates opening/closing control of the gate according to the activation command transmitted from the machine side panel 30 . To simulate opening/closing control of a gate means to virtually control the opening or closing of the gate without actually controlling the opening or closing of the gate. The gate tester 50 transmits the degree of opening and the amount of discharge to the machine side panel 30 .

Next, the machine side panel 30 and the gate tester 50 will be described in further detail.
The machine side panel 30 includes a control section 31 and a transmission section 32 .
The control unit 31 is a functional unit that controls each function of the machine side panel 30 . For example, the control section 31 controls the transmission section 32 to transmit the activation command to the gate tester 50 . Also, for example, the control unit 31 determines abnormality based on the status information received via the transmission unit 32 .

The transmission unit 32 is a connector having a signal line for connection with the gate test control device 40 and a signal line for connection with the gate tester 50 . For example, the signal lines connected to the gate test controller 40 include a plurality of signal lines for determining at least the states of fully open, open, closed and fully closed. Further, for example, the signal lines connected to the gate tester 50 include at least a signal line for transmitting a start command and a signal line for receiving the opening degree and discharge amount.

The gate tester 50 includes a driving device 51 , an opening meter 52 and a flow meter 53 .
The driving device 51 is a device that simulates opening/closing control of the gate according to the start command transmitted from the machine side panel 30 . For example, if the activation command includes an "open" instruction, the driving device 51 simulates gate opening control. Further, for example, when the activation command includes a "close" instruction, the driving device 51 simulates gate closing control.

The opening meter 52 is a sensor that measures the opening. The opening meter 52 transmits the measured opening to the machine side panel 30 periodically or at a predetermined timing.
The flowmeter 53 is a sensor that measures the flow rate. The flow meter 53 periodically or at a predetermined timing transmits the measured flow rate to the machine side panel 30 .

The gate tester 50 has a connector having a signal line for connection with the machine side board 30 and a signal line for connection with the gate test control device 40 . For example, the signal line connected to the machine side panel 30 includes at least a signal line for receiving the activation command and a signal line for transmitting the opening degree and the discharge amount. Further, for example, the signal lines connected to the gate test control device 40 include a plurality of signal lines for transmitting state information indicating at least the respective states of fully open, open, closed and fully closed.

FIG. 2 is an external view of the gate test control device 40 in this embodiment.
The gate test control device 40 includes a machine-side panel-side connector 41 , a gate tester-side connector 42 , a force button 43 and a shutoff button 44 . A caution label 45 is attached to the surface of the gate test controller 40 .
The machine-side board-side connector 41 is a connector having a plurality of signal lines for connecting with the machine-side board 30 . For example, the machine-side board-side connector 41 has at least a signal line corresponding to "fully open", a signal line corresponding to "open", a signal line corresponding to "closed", and a signal line corresponding to "fully closed". There is The machine-side board-side connector 41 outputs a signal to the machine-side board 30 via a predetermined signal line.
The gate tester-side connector 42 is a connector having a plurality of signal lines for connecting with the gate tester 50 . The gate tester-side connector 42 inputs a signal output from the gate tester 50 to its own device via a predetermined signal line.

The force button 43 (first button) is a button for forcibly outputting a signal indicating an arbitrary state. Here, to forcibly output a signal indicating an arbitrary state means to output a signal indicating an arbitrary state regardless of the signal input from the gate tester 50 . The forced buttons 43 include a forced fully open button 431 , a forced open button 432 , a forced closed button 433 and a forced fully closed button 434 . The forced fully open button 431, the forced open button 432, the forced closed button 433, and the forced fully closed button 434 are illuminated push buttons. When any one of the forced fully open button 431, the forced open button 432, the forced closed button 433, and the forced fully closed button 434 is ON, the button in the ON state lights up. In this manner, the force button 43 outputs a signal corresponding to any one of the fully open, open, closed and fully closed states representing the open/closed state of the gate.

The forced full open button 431 is a button for forcibly outputting a signal through the signal line corresponding to "fully open". When the forced full open button 431 is in the ON state, a signal is output to the machine side panel 30 via the signal line corresponding to "fully open".
The forced open button 432 is a button for forcibly outputting a signal through the signal line corresponding to "open". When the forced open button 432 is in the ON state, a signal is output to the machine side panel 30 via the signal line corresponding to "open".

The forced closed button 433 is a button for forcibly outputting a signal through the signal line corresponding to "closed". When the forced closing button 433 is in the ON state, a signal is output to the machine side panel 30 through the signal line corresponding to "closed".
The forced fully closed button 434 is a button for forcibly outputting a signal through the signal line corresponding to "fully closed". When the forced full-close button 434 is in the ON state, a signal is output to the machine-side panel 30 via the signal line corresponding to "fully closed".

The cutoff button 44 (second button) is a button for forcibly cutting off the output of a signal indicating an arbitrary state. Here, to forcibly cut off the output of a signal indicating an arbitrary state means that the signal indicating an arbitrary state input from the gate tester 50 is not output to the machine side panel 30 . The blocking buttons 44 include a blocking fully open button 441 , a blocking open button 442 , a blocking closed button 443 and a blocking fully closed button 444 . The shut-off full-open button 441, the shut-off open button 442, the shut-off closed button 443, and the shut-off full-close button 444 are illuminated push buttons. When any one of the shut-off full-open button 441, the shut-off open button 442, the shut-off closed button 443, and the shut-off full-close button 444 is in the OFF state, the button in the OFF state lights up. Thus, the cutoff button 44 cuts off the output of the signal corresponding to any one of the fully open, open, closed and fully closed states.

The cut-off full-open button 441 is a button for forcibly cutting off the output of the signal through the signal line corresponding to "fully open". When the shut-off full-open button 441 is in the OFF state, the output of the signal via the signal line corresponding to "fully open" is forcibly shut off. That is, when the shut-off full-open button 441 is in the OFF state, no signal is output from the signal line corresponding to "fully open". For example, when the shut-off full-open button 441 is in the OFF state, even if a signal is input from the gate tester 50 to the gate test control device 40 via the signal line corresponding to "fully open" of the gate tester-side connector 42, No signal is output from the signal line corresponding to "fully open".

On the other hand, when the cut-off full-open button 441 is in the ON state, a signal is output to the machine-side panel 30 via the signal line corresponding to "fully open". That is, when the cut-off full-open button 441 is in the ON state, a signal is output from the signal line corresponding to "fully open". For example, when the shut-off full-open button 441 is in the ON state, when a signal is input from the gate tester 50 to the gate test control device 40 via the signal line corresponding to "fully open" of the gate tester-side connector 42, " A signal is output from the signal line corresponding to "fully open".

The cut-off open button 442 is a button for forcibly cutting off the output of the signal through the signal line corresponding to "open". When the cut-off open button 442 is in the OFF state, the output of the signal through the signal line corresponding to "open" is forcibly cut off. That is, when the cut-off open button 442 is in the OFF state, no signal is output from the signal line corresponding to "open". For example, when the shut-off open button 442 is in the OFF state, a signal is input from the gate tester 50 to the gate test control device 40 via the signal line corresponding to "open" of the gate tester-side connector 42. Also, no signal is output from the signal line corresponding to "open".

On the other hand, when the cut-off/open button 442 is in the ON state, a signal is output to the machine-side panel 30 via the signal line corresponding to "open". That is, when the cut-off/open button 442 is in the ON state, a signal is output from the signal line corresponding to "open". For example, when the shut-off/open button 442 is in the ON state, when a signal is input from the gate tester 50 to the gate test control device 40 via the signal line corresponding to "open" of the gate tester-side connector 42, , a signal is output from the signal line corresponding to "open".

The cut-off closed button 443 is a button for forcibly cutting off the output of the signal through the signal line corresponding to "closed". When the cut-off closed button 443 is in the OFF state, the output of the signal through the signal line corresponding to "closed" is forcibly cut off. That is, when the cut-off/closed button 443 is in the OFF state, no signal is output from the signal line corresponding to "closed". For example, when the shut-off/closed button 443 is in the OFF state, a signal is input from the gate tester 50 to the gate test control device 40 via the signal line corresponding to "closed" of the gate tester-side connector 42. Also, no signal is output from the signal line corresponding to "closed".

On the other hand, when the shut-off closed button 443 is in the ON state, a signal corresponding to "closed" is output to the machine side panel 30 via the signal line. That is, when the shut-off closed button 443 is in the ON state, a signal is output from the signal line corresponding to "closed". For example, when the shut-off/closed button 443 is in the ON state, when a signal is input from the gate tester 50 to the gate test control device 40 via the signal line corresponding to "closed" of the gate tester-side connector 42, , a signal is output from the signal line corresponding to "closed".

The shut-off full-close button 444 is a button for forcibly shutting off the output of the signal through the signal line corresponding to "fully-closed". When the cutoff fully closed button 444 is in the OFF state, the output of the signal via the signal line corresponding to "fully closed" is forcibly cut off. That is, when the shut-off full-close button 444 is in the OFF state, no signal is output from the signal line corresponding to "fully-closed". For example, when the shut-off full-close button 444 is in the OFF state, it is assumed that a signal is input from the gate tester 50 to the gate test control device 40 via the signal line corresponding to "fully closed" of the gate tester-side connector 42. Also, no signal is output from the signal line corresponding to "fully closed".

On the other hand, when the shut-off full-close button 444 is in the ON state, a signal is output to the machine-side panel 30 via the signal line corresponding to "fully closed". That is, when the shut-off full-close button 444 is in the ON state, a signal is output from the signal line corresponding to "fully-closed". For example, when the shut-off full-close button 444 is in the ON state, when a signal is input from the gate tester 50 to the gate test control device 40 via the signal line corresponding to "fully closed" of the gate tester-side connector 42, , a signal is output from the signal line corresponding to "fully closed".

The caution label 45 is a label for calling attention to the user. If any button of the force button 43 is turned ON or any button of the cutoff button 44 is turned OFF, there is a possibility that adverse effects (equipment failure, test error) will be exerted on the next use. be. Therefore, after use, it is necessary to put away all the force buttons 43 in the OFF state and all the cutoff buttons 44 in the ON state. Therefore, the caution label 45 describes, for example, a character string that reads, "When the test ends, turn off all the force buttons and turn all the shutoff buttons back on."

As described above, when all the force buttons 43 are in the OFF state and all the cutoff buttons 44 are in the ON state, the signal output from the gate tester 50 is output to the machine side board 30 as it is. This represents a normal state in which no abnormality has occurred. In the following description, a state in which all the force buttons 43 are in the OFF state and all the cutoff buttons 44 are in the ON state is called an initial state. When it is desired to generate an abnormal situation, by operating either one or both of the force button 43 and the cutoff button 44, a signal of an arbitrary state can be output in a simulated manner.

FIG. 3 is a diagram showing how to operate the force button 43 and the shutoff button 44 for test items of the gate control test.
As shown in FIG. 3, operation methods of the force button 43 and the shutdown button 44 are shown for each abnormality name of the test item. The test item abnormality name represents the name of an abnormality as a test item of the gate control test. In FIG. 3, as the names of test items, "reverse operation abnormality", "signal abnormality during signal failure control", "signal abnormality at stop of illegal operation", "signal abnormality at start of control congestion", and "elapsed time" The target opening is not reached even after" is displayed.

The "opening direction" in the event of an abnormality represents the operation method of the force button 43 and the cutoff button 44 when performing a simulated test of the gate opening control in the event of an abnormality.
The "closing direction" in the event of an abnormality represents the operation method of the force button 43 and the cutoff button 44 when testing the gate closing control in a simulated manner in the event of an abnormality.

The user can simulate an abnormal state by operating the force button 43 and the cutoff button 44 according to the operating method shown in FIG. For example, in FIG. 3, if the user wants to generate an "unauthorized operation reverse operation abnormality" when controlling the opening of the gate, the user turns on the forced open button 432 of the force button 43, and the shut-off button 44 is turned on. It is shown that the "unauthorized operation reverse operation abnormality" can be generated by turning the middle button 442 and the cut-off/closed button 443 to the OFF state.

FIG. 4 is a diagram showing the internal configuration of the gate test control device 40 in this embodiment.
Gate test controller 40 includes control circuitry 46 . The control circuit 46 has a configuration as shown in FIG. 5, and simulates an abnormal state by operating the force button 43 and the cutoff button 44 .

FIG. 5 is a diagram showing the configuration of the control circuit 46 in this embodiment.
The control circuit 46 includes a plurality of signal lines 461-465.
A signal line 461 (first signal line) is a commonly used signal line.
A signal line 462 (second signal line) is a signal line corresponding to "fully open". Signal line 462 is provided with SW1, lamp L1 and magnet 1 (moving contact control section). SW 1 and lamp L 1 constitute shut-off full-open button 441 . SW1 is a push button type switch. The lamp L1 is, for example, an LED lamp. When SW1 is turned on, it becomes conductive and current flows on the signal line 462 . As a result, the lamp L1 lights up. Also, the magnet 1 becomes an electromagnet. In the present embodiment, the configuration in which the magnet 1 controls the operation of the opening/closing portion 1a using electromagnetic force will be described as an example, but the configuration for controlling the operation of the opening/closing portion 1a need not be limited to the magnet. do not have. For example, coils may be used instead of magnets.

A signal line 463 (second signal line) is a signal line corresponding to "open". Signal line 463 is provided with SW2, lamp L2 and magnet 2 . SW 2 and lamp L 2 constitute shut-off button 442 . SW2 is a push button type switch. The lamp L2 becomes conductive and current flows through the signal line 463 when SW2, which is an LED lamp, is turned on. As a result, the lamp L2 is lit. Also, the magnet 2 becomes an electromagnet.

A signal line 464 (second signal line) is a signal line corresponding to "closed". SW3, lamp L3 and magnet 3 are provided on the signal line 464 . SW3 and lamp L3 constitute shut-off button 443 . SW3 is a push button type switch. The lamp L3 becomes conductive and current flows through the signal line 464 when SW3, which is an LED lamp, is turned on. As a result, the lamp L3 lights up. Also, the magnet 3 becomes an electromagnet.

A signal line 465 (second signal line) is a signal line corresponding to "fully closed". SW4, lamp L4 and magnet 4 are provided on signal line 465 . SW4 and lamp L4 constitute shut-off full-close button 444 . SW4 is a push button type switch. The lamp L4 becomes conductive and current flows through the signal line 465 when SW4, which is an LED lamp, is turned on. As a result, the lamp L4 lights up. Also, the magnet 4 becomes an electromagnet.

A signal line between the contact 466 of the signal line 461 and the contact 467 of the signal line 462 is provided with lamps L5 and SW5 and an opening/closing portion 1a. The opening/closing portion 1a opens and closes according to the state of the magnet 1. As shown in FIG. When the magnet 1 is an electromagnet, the opening/closing portion 1a is attracted to the magnet 1 by an electromagnetic force and becomes an open state. The lamps L5 and SW5 constitute a forced full-open button 431. FIG. SW5 is a push button type switch. In the lamp L5, when SW5, which is an LED lamp, for example, is in the ON state and the opening/closing portion 1a is closed, current flows from the signal line 461 to the signal line 462. FIG. As a result, the lamp L5 lights up.
On the other hand, when the opening/closing portion 1a is open (in the open state), no current flows from the signal line 461 to the signal line 462 . Therefore, the lamp L5 does not turn on even when the SW5 is turned on.

A signal line between the contact 468 of the signal line 461 and the contact 469 of the signal line 463 is provided with the lamps L6, SW6 and the opening/closing portion 2a. The opening/closing portion 2a opens and closes depending on the state of the magnet 2. As shown in FIG. When the magnet 2 is an electromagnet, the opening/closing portion 2a is attracted to the magnet 2 by an electromagnetic force to be in an open state. The lamps L6 and SW6 constitute the forced open button 432. FIG. SW6 is a push button type switch. In the lamp L6, when SW6, which is an LED lamp, for example, is in an ON state and the opening/closing portion 2a is closed, current flows from the signal line 461 to the signal line 463. FIG. As a result, the lamp L6 lights up.
On the other hand, when the opening/closing portion 2a is open (open state), no current flows from the signal line 461 to the signal line 463. FIG. Therefore, the lamp L6 does not turn on even if the SW6 is turned on.

A signal line between the contact 470 of the signal line 461 and the contact 471 of the signal line 464 is provided with lamps L7, SW7, and an opening/closing portion 3a. The opening/closing portion 3a opens and closes according to the state of the magnet 3. As shown in FIG. When the magnet 3 is an electromagnet, the opening/closing portion 3a is attracted to the magnet 3 by an electromagnetic force, and the opening/closing portion 3a is opened. The lamps L7 and SW7 constitute a forced closed button 433. FIG. SW7 is a push button type switch. In the lamp L7, for example, the LED lamp SW7 is in an ON state, and when the opening/closing portion 3a is closed, the lamp L7 is conductive and a current flows from the signal line 461 to the signal line 464. FIG. As a result, the lamp L7 lights up.
On the other hand, when the opening/closing portion 3a is open (open state), no current flows from the signal line 461 to the signal line 464. FIG. Therefore, the lamp L7 does not turn on even when the SW7 is turned on.

A signal line between the contact 472 of the signal line 461 and the contact 473 of the signal line 465 is provided with the lamps L8, SW8 and the opening/closing portion 4a. The opening/closing portion 4a opens and closes according to the state of the magnet 4. As shown in FIG. When the magnet 4 is an electromagnet, the opening/closing portion 4a is attracted to the magnet 4 by an electromagnetic force and the opening/closing portion 4a is opened. Lamps L8 and SW8 constitute a forced full-close button 434. FIG. SW8 is a push button type switch. In the lamp L8, for example, the LED lamp SW8 is in an ON state, and when the opening/closing portion 4a is closed, the lamp L8 is conductive and current flows from the signal line 461 to the signal line 465. FIG. As a result, the lamp L8 lights up.
On the other hand, when the opening/closing portion 4a is open (open state), no current flows from the signal line 461 to the signal line 465. FIG. Therefore, the lamp L8 does not turn on even when the SW8 is turned on.

Also, as shown in FIG. 5, the control circuit 46 is composed of a relay circuit having an interlock function to prevent the specific force button 43 and the cutoff button 44 from being turned on at the same time. The gate test control device 40 in this embodiment has an interlock function that prevents the force button 43 and the cutoff button 44 that use the same path from being turned on at the same time. The forced button 43 and the cutoff button 44 that use the same path are, for example, a combination of the forced full open button 431 and the cutoff full open button 441, a combination of the forced open button 432 and the cutoff open button 442, a combination of the forced close button 433 and the cutoff close button. A combination of the middle button 443 and a combination of the forced full-close button 434 and the cut-off full-close button 444 .

The interlock function in this embodiment will be described with a specific example using FIGS. 6 and 7. FIG. 6 and 7 are diagrams for explaining the interlock function in this embodiment.
FIG. 6 shows the operation of the relay circuit when a signal is output from the cutoff button 44 path. Note that FIG. 6 shows a case where all of the shutoff buttons 44 are in the ON state, and only the forced full-open button 431 of the forced buttons 43 is in the ON state.

As shown in FIG. 6, when a signal is input from the gate tester 50 to the signal line 462 corresponding to "fully open" of the gate test control device 40, the signal flows on the signal line 462 and is output to the machine side panel 30. Monkey. Since the magnet 1 becomes an electromagnet when passing through SW1, the contact of the opening/closing portion 1a is separated. Since the contact of the opening/closing part 1a is separated, the switch is in an open state, so that no signal is output even if the SW5 is pressed.

FIG. 7 shows the operation of the relay circuit when a signal is output from the path of the force button 43. In FIG. Note that FIG. 7 shows a case where only 441 of the shutoff buttons 44 are in the OFF state, and only the forced fully open button 431 of the forced button 43 is in the ON state.

As shown in FIG. 7, since SW1 is turned off, the magnet 1 ceases to be an electromagnet. As a result, the opening/closing portion 1a is in a contact state. Therefore, when the SW5 is turned on, a signal can be output from the path of the force button 43 .
The relay circuit as described above prevents the shutoff button 44 of SW1 to SW4 and the force button 44 of SW5 to SW8 from being turned on at the same time.

Next, the operation of the gate test controller 40 during the gate control test will be described with reference to FIGS. 8 to 17. FIG. 8 to 17 are diagrams for explaining the operation method of the gate test control device 40 during the gate control test in this embodiment.
FIG. 8 shows an operation method for generating an "illegal operation reverse operation abnormality" in the gate control test in the opening direction. Specifically, regarding the forced button 43, the forced closed button 433 is turned on, and the forced fully open button 431, forced open button 432, and forced fully closed button 434 are turned off. As for the shutoff button 44, the shutoff full-open button 441 and shutoff full-close button 444 are shown to be in the ON state, and the shutoff/open button 442 and shutoff/close button 443 are set to be in the OFF state.

As shown in FIG. 8, when the force button 43 and the cutoff button 44 are operated, the control circuit 46 is switched to the circuit configuration shown in FIG. As shown in FIG. 9, when a signal is input from the gate tester 50 to the signal line 463 corresponding to "open" of the gate test controller 40, the flow of the signal input from the gate tester 50 is interrupted. be. On the other hand, since the forced closing button 433 is ON and the blocking/closing button 443 is OFF, current flows from the signal line 461 to the signal line 464 . As a result, a signal is output to the machine side panel 30 from the signal line 464 corresponding to "closed". In this case, the machine side panel 30 should receive a signal from the signal line 463 corresponding to "open", but the signal is input from the signal line 464 corresponding to "closed". is determined to have occurred.

FIG. 10 shows a method of operation when it is desired to generate an "incorrect operation reverse operation abnormality" in the gate control test in the closing direction. Specifically, regarding the forced button 43, the forced open button 432 is turned on, and the forced fully open button 431, forced closed button 433, and forced fully closed button 434 are turned off. As for the shutoff button 44, the shutoff full-open button 441 and shutoff full-close button 444 are shown to be in the ON state, and the shutoff/open button 442 and shutoff/close button 443 are set to be in the OFF state.

As shown in FIG. 10, when the force button 43 and the cutoff button 44 are operated, the control circuit 46 is switched to the circuit configuration shown in FIG. As shown in FIG. 11, when a signal is input from the gate tester 50 to the signal line 464 corresponding to "closed" of the gate test controller 40, the flow of the signal input from the gate tester 50 is interrupted. be. On the other hand, since the forced open button 432 is in the ON state and the cut-off open button 442 is in the OFF state, current flows from the signal line 461 to the signal line 463 . As a result, a signal is output to the machine side panel 30 from the signal line 463 corresponding to "open". In this case, the machine side panel 30 should receive a signal from the signal line 464 corresponding to "closed", but the signal is input from the signal line 463 corresponding to "open". is determined to have occurred.

FIG. 12 shows an operation method when it is desired to generate "signal failure during signal failure control" in the gate control test in the opening direction. Specifically, all of the force buttons 43 are shown to be in the OFF state. As for the shutoff button 44, the full open shutoff button 441 is turned off, and the open shutoff button 442, closed close button 443, and fully closed shutoff button 444 are turned on.

As shown in FIG. 12, when the force button 43 and the cutoff button 44 are operated, the control circuit 46 is switched to the circuit configuration shown in FIG. As shown in FIG. 13, when a signal is input from the gate tester 50 to the signal line 462 corresponding to "fully open" of the gate test controller 40, the flow of the signal input from the gate tester 50 is interrupted. . In this case, even if the target opening is reached, no signal is input to the machine side panel 30 from the signal line 462 corresponding to "fully open". Therefore, the machine-side panel 30 determines that a signal abnormality has occurred during signal failure control.

FIG. 14 shows an operation method for generating "signal failure during signal failure control" in the gate control test in the closing direction. Specifically, all of the force buttons 43 are shown to be in the OFF state. As for the shutoff button 44, the shutoff fully closed button 444 is shown to be in the OFF state, and the shutoff fully open button 441, the shutoff open button 442, and the shutoff closed button 443 are turned on.

As shown in FIG. 14, when the force button 43 and the cutoff button 44 are operated, the control circuit 46 is switched to the circuit configuration shown in FIG. As shown in FIG. 15, when a signal is input from the gate tester 50 to the signal line 465 corresponding to "fully closed" of the gate test controller 40, the flow of the signal input from the gate tester 50 is interrupted. be. In this case, even if the target opening is reached, no signal is input to the machine side panel 30 from the signal line 465 corresponding to "fully closed". Therefore, the machine-side panel 30 determines that a signal abnormality has occurred during signal failure control.

FIG. 16 shows an operation method when it is desired to generate "signal abnormality at stop of illegal operation" in the gate control test in the opening direction. Specifically, regarding the forced button 43, the forced open button 432 is turned on, and the forced fully open button 431, forced closed button 433, and forced fully closed button 434 are turned off. As for the shut-off button 44, the shut-off open button 442 is turned off, and the shut-off fully open button 441, shut-off closed button 443, and shut-off fully closed button 444 are turned on.

As shown in FIG. 16, when the force button 43 and the cutoff button 44 are operated, the control circuit 46 is switched to the circuit configuration shown in FIG. As shown in FIG. 17, when a signal is input from the gate tester 50 to the signal line 462 corresponding to "fully open" of the gate test control device 40, the signal input from the gate tester 50 corresponds to "fully open". It is output to the machine-side panel 30 via the signal line 462 that connects. Further, since the forced open button 432 is in the ON state and the cut-off open button 442 is in the OFF state, current flows from the signal line 461 to the signal line 463 . As a result, a signal is output to the machine side panel 30 also from the signal line 463 corresponding to "open". In this case, although the machine-side panel 30 has already reached the target opening, a signal is input from the signal line 463 corresponding to "open", so a signal abnormality occurs at the time of illegal operation stop. determined to be

FIG. 18 shows a method of operation when it is desired to generate a "signal abnormality at stop of illegal operation" in the gate control test in the closing direction. Regarding the forced button 43, it is shown that the forced closed button 433 is turned on, and the forced full open button 431, forced open button 432, and forced fully closed button 434 are turned off. As for the shutoff button 44, the shutoff closed button 443 is turned off, and the shutoff fully open button 441, shutoff open button 442, and shutoff fully closed button 444 are turned on.

As shown in FIG. 18, when the force button 43 and the cutoff button 44 are operated, the control circuit 46 is switched to the circuit configuration shown in FIG. As shown in FIG. 19, when a signal is input from the gate tester 50 to the signal line 465 corresponding to "fully closed" of the gate test controller 40, the signal input from the gate tester 50 is "fully closed". is output to the machine-side panel 30 via the signal line 465 corresponding to . Further, since the forced closing button 433 is in the ON state and the cutoff closing button 443 is in the OFF state, current flows from the signal line 461 to the signal line 464 . As a result, a signal is output to the machine side panel 30 also from the signal line 464 corresponding to "closed". In this case, although the machine side panel 30 has reached the target degree of opening, a signal is input from the signal line 464 corresponding to "closed", so a signal abnormality occurs at the time of illegal operation stop. determined to be

FIG. 20 shows an operation method for generating a "signal abnormality at the start of control congestion" in a gate control test in the opening direction. Specifically, all of the force buttons 43 are shown to be in the OFF state. As for the shut-off button 44, the shut-off open button 442 is turned off, and the shut-off fully open button 441, shut-off closed button 443, and shut-off fully closed button 444 are turned on.

As shown in FIG. 20, when the force button 43 and the cutoff button 44 are operated, the control circuit 46 is switched to the circuit configuration shown in FIG. As shown in FIG. 21, when a signal is input from the gate tester 50 to the signal line 463 corresponding to "open" of the gate test controller 40, the flow of the signal input from the gate tester 50 is interrupted. be. In this case, no signal is input from the signal line 463 corresponding to "during opening" to the machine-side panel 30 even though the activation of the opening control is started. Therefore, the machine-side panel 30 determines that the control congestion start signal abnormality has occurred.

FIG. 22 shows an operation method when it is desired to generate a "signal abnormality at the start of control congestion" in a gate control test in the closing direction. Specifically, all of the force buttons 43 are shown to be in the OFF state. As for the shutoff button 44, the shutoff closed button 443 is turned off, and the shutoff fully open button 441, shutoff open button 442, and shutoff fully closed button 444 are turned on.

As shown in FIG. 22, when the force button 43 and the cutoff button 44 are operated, the control circuit 46 is switched to the circuit configuration shown in FIG. As shown in FIG. 23, when a signal is input from the gate tester 50 to the signal line 464 corresponding to "closed" of the gate test control device 40, the flow of the signal input from the gate tester 50 is interrupted. be. In this case, no signal is input from the signal line 464 corresponding to "closed" to the machine side panel 30 even though the activation of the closing control is started. Therefore, the machine-side panel 30 determines that the control congestion start signal abnormality has occurred.

FIG. 24 shows an operation method for generating "the target opening is not reached even after a certain period of time has elapsed" in the gate control test in the opening direction. Specifically, regarding the forced button 43, the forced open button 432 is turned on, and the forced fully open button 431, forced closed button 433, and forced fully closed button 434 are turned off. As for the shutoff button 44, the shutoff fully open button 441 and shutoff open button 442 are shown to be in the OFF state, and the shutoff closed button 443 and shutoff fully closed button 444 are shown to be in the ON state.

As shown in FIG. 24, when the force button 43 and the cutoff button 44 are operated, the control circuit 46 is switched to the circuit configuration shown in FIG. As shown in FIG. 25, when a signal is input from the gate tester 50 to the signal line 462 corresponding to "fully open" of the gate test controller 40, the flow of the signal input from the gate tester 50 is interrupted. . On the other hand, since the forced open button 432 is in the ON state and the cut-off open button 442 is in the OFF state, current flows from the signal line 461 to the signal line 463 . As a result, a signal is output to the machine side panel 30 from the signal line 463 corresponding to "open". However, since the cut-off full-open button 441 is in the OFF state, no signal is input from the signal line 462 corresponding to "fully open" to the machine-side panel 30 even after a certain period of time has elapsed. Therefore, the machine-side panel 30 determines that there is an abnormality in which the target opening is not reached even after the lapse of a certain period of time.

FIG. 26 shows an operation method for generating "the target opening is not reached even after a certain period of time" in the gate control test in the closing direction. Specifically, regarding the forced button 43, the forced closed button 433 is turned on, and the forced fully open button 431, forced open button 432, and forced fully closed button 434 are turned off. As for the shutoff button 44, the shutoff/closed button 443 and shutoff fully closed button 444 are shown to be in the OFF state, and the shutoff full open button 441 and shutoff open button 442 are set to be in the ON state.

As shown in FIG. 26 , when the force button 43 and the cutoff button 44 are operated, the control circuit 46 is switched to the circuit configuration shown in FIG . As shown in FIG. 27 , when a signal is input from the gate tester 50 to the signal line 465 corresponding to "fully closed" of the gate test controller 40, the flow of the signal input from the gate tester 50 is interrupted. be. On the other hand, since the forced closing button 433 is ON and the blocking/closing button 443 is OFF, current flows from the signal line 461 to the signal line 464 . As a result, a signal is output to the machine side panel 30 from the signal line 464 corresponding to "closed". However, since the cut-off full-close button 444 is in the OFF state, no signal is input from the signal line 465 corresponding to "fully-closed" to the machine-side panel 30 even after the lapse of a certain period of time. Therefore, the machine-side panel 30 determines that there is an abnormality in which the target opening is not reached even after the lapse of a certain period of time.

According to the gate test controller 40 configured as described above, it is possible to easily perform a gate control test. Specifically, an abnormal state can be generated by operating a button on the gate test control device 40 without changing the wiring between the gate tester 50 and the machine side panel 30 . This eliminates the need to change the wiring, so that it is possible to reduce the labor and time required for the change work. Furthermore, the test becomes more efficient, and it is possible to reduce backtracking due to incorrect wiring. Therefore, it becomes possible to easily perform a gate control test.

Conventionally, in order to perform a gate control test, the wires inserted into the connector on the side panel of the equipment are removed and the wiring is changed. There was also On the other hand, the gate test control device 40 eliminates the work of changing the wiring, so it is possible to suppress the deterioration of the electric wire. Furthermore, since the gate test control device 40 is merely added, it is more immediate than introducing a new test method. In addition, since the gate test control device 40 can be manufactured using only inexpensive materials such as buttons and lights, the cost can be kept low.

<Modified example of gate test control device 40>
In this embodiment, the caution label 45 attached to the gate test control device 40 prompts the user to return the force button 43 and the shutoff button 44 to their initial states. However, the gate test controller 40 may be configured to further include an initial state button for resetting the force button 43 and the shutoff button 44 to their initial state. The initial state button is connected to the force button 43 and the shutoff button 44 so that the force button 43 and the shutoff button 44 return to their initial state in response to being pressed.
With this configuration, it is possible to return to the initial state with a single button. Therefore, it is not necessary to return the force button 43 and the cutoff button 44 to their initial states after use. Therefore, the initial state can be easily restored.
A relay circuit that outputs the states of "fully open" and "fully closed" may not have an interlock function. Specifically, in the control circuit 46, the opening/closing portions 1a and 4a and the magnets 1 and 4 may not be provided.

According to at least one embodiment described above, a first button for outputting a signal corresponding to any one of fully open, open, closed, and fully closed representing the open/closed state of the gate of the dam; A second button that cuts off the output of a signal corresponding to one of the states of open, closed, and fully closed, and outputs a signal of a predetermined state according to the operation of the first button and the second button. By having the control circuit, the gate control test can be easily performed.

While several embodiments of the invention have been described, these embodiments have been presented by way of example and are not intended to limit the scope of the invention. These embodiments can be implemented in various other forms, and various omissions, replacements, and modifications can be made without departing from the scope of the invention. These embodiments and their modifications are included in the scope and spirit of the invention, as well as the scope of the invention described in the claims and equivalents thereof.

DESCRIPTION OF SYMBOLS 10... Discharge operation device, 20... Input-output device, 30... Machine side board, 31... Control part, 32... Transmission part, 40... Gate test control apparatus, 50... Gate tester, 51... Drive device, 52... Opening degree meter, 53 ... flow meter

Claims (7)

A plurality of states representing the open/closed states of the dam gate regardless of a signal input from the dam testing apparatus via one of a plurality of control lines respectively corresponding to the plurality of states representing the open/closed states of the dam gate . a first button for forcibly outputting a signal indicating one of the states ;
a second button for forcibly interrupting the signal input from the dam test device through one of the plurality of control lines;
a control circuit that outputs a signal of a predetermined state in accordance with the operation of the first button and the second button;
A gate test controller comprising: the plurality of states representing the opening/closing state of the gate of the dam are any of fully open, open, closed and fully closed;
The plurality of control lines corresponding to each of the plurality of states representing the open/close state of the gate of the dam are composed of fully open, open, closed, and fully closed signal lines.
The gate test controller of claim 1. The plurality of control lines of the control circuit are
a commonly used first signal line;
a plurality of second signal lines respectively corresponding to the fully open, open, closed and fully closed states ;
a plurality of third signal lines branched from the first signal line and provided between the first signal line and the plurality of second signal lines;
The plurality of third signal lines are provided with a switch corresponding to the first button and an opening/closing portion movable by electromagnetic force,
3. The gate according to claim 2, wherein the second signal line is provided with a switch corresponding to the second button and a movable contact control section that controls the operation of the opening and closing section using electromagnetic force. Test controller. The control circuit includes a relay circuit having an interlock function that prevents the other button from being turned on when either the first button or the second button is on.
The gate test controller of claim 1. The plurality of control lines of the control circuit are
a commonly used first signal line;
a plurality of second signal lines respectively corresponding to the fully open, open, closed and fully closed states;
a plurality of third signal lines branched from the first signal line and provided between the first signal line and the plurality of second signal lines;
The relay circuit having the interlock function is
When a switch provided on the plurality of third signal lines and corresponding to one of the second buttons is turned on, current does not flow through the third signal line corresponding to the switch that is turned on. It is composed of a switch that is in an open state,
5. The gate test controller of claim 4. As information on precautions after use, a label is affixed to caution the user,
Said label says:
an instruction to return the state of the first button to a specified state so as not to forcibly output a signal indicating one of the plurality of states;
and an instruction to return the state of the second button to a designated state so as not to forcibly block the signal input from the dumb test device.
The gate test controller of claim 1. Returning the state of the first button to a state in which the signal indicating one of the plurality of states is not forcibly output, and forcibly blocking the signal input from the dam test device. further comprising an initial state button that returns the state of the second button to a non-existing state;
The gate test controller of claim 1.

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