KR101306018B1 - Unmanned safety inspection system and method using self-diagnosis intelligent generator - Google Patents

Abstract

PURPOSE: A manless safety inspection system using the self-diagnosis intelligent generator and a manless safety inspection method using the same are provided to determine whether an emergency power supply system operates works normally itself, thereby preventing the failure of the emergency power supply system in advance. CONSTITUTION: A generator control panel (30) comprises a controller (31), a measuring instrument (32), and an outputter (33), and an alarm (34). The controller comprises a micro controller unit (MCU) including an input and output unit. The measuring instrument measures specified matters such as an output voltage, an output current, frequency, a coolant temperature, and a lubricant pressure of an emergency generator (20). The outputter outputs measured values of the measuring instrument. The alarm generates alarm sounds according to the signal output of the controller. [Reference numerals] (10) Currently-using power supply; (20) Emergency generator; (30) Generator control panel; (31,47) Controller; (32,46) Measuring instrument; (33) Outputter; (34) Alarm; (40) Power receiving and distributing panel; (43) Transformer; (45) Switcher; (50) Load; (51) Ordinary load; (52) Fire-fighting load; (53) Emergency load

Description

Unmanned safety inspection system and method using self-diagnosis intelligent generator}

The present invention uses a self-diagnostic intelligent generator that monitors and records the abnormality of the emergency power supply system by self-starting and operating the generator unattended during operation of the emergency generator safety management and supply and cut off the power generation, and the same conditions as the actual disaster occurrence. Unattended safety inspection system using self-diagnosis intelligent generator and unmanned safety using the self-diagnosis intelligent generator that enables safer response to disasters, and enables safer management of emergency generators by performing unattended safety inspection. It is about checking method.

In general, buildings over a certain size are required to install alarm, fire and fire extinguishing equipment for the safety of building users. These alarm, fire and fire extinguishing facilities require power for operation, and for this purpose, emergency generators are installed and used.

The conventional emergency generator is used to solve the disaster situation by supplying power to the fire load and emergency load composed of alarm equipment, fire fighting equipment and fire extinguishing equipment that require power supply in the event of a disaster such as fire or power outage.

Therefore, in order to minimize the physical and human damage that can be caused by supplying power to the emergency load that is needed quickly by performing the normal functions of the emergency power supply system in case of a disaster, the safety of the normal function of the emergency generator is always maintained. Management will be necessary.

The safety management of the conventional emergency generator is managed by human resources, but management failure due to problems such as the manager's insecurity and cost, and the emergency power supply is not supplied due to the failure of the emergency generator when an actual disaster occurs. There are many serious problems.

In addition, since the emergency power supply system operates unattended in the event of a real disaster, there is a problem in that the safety check method manually performed by such a conventional manager does not guarantee the normal operation of the emergency power supply system.

In order to solve the above problems, the present invention constitutes the same conditions as when a disaster or power failure occurs by the self-diagnostic intelligent generator when the safety check point arrives in the safety management of the emergency generator or when the safety check by the user is required By determining the normal operation of emergency power supply system by itself, it is possible to prevent malfunction of emergency generator and failure of emergency power supply system in case of disaster and power failure caused by management failure caused by manual safety management method by conventional human resources. The purpose of the present invention is to provide an unmanned safety inspection system using a self-diagnostic intelligent generator and an unmanned safety inspection method using the self-diagnostic intelligent generator, which prevents the disaster more proactively.

In addition, another object of the present invention is to provide a conventional human resource by using a self-diagnostic intelligent generator that measures, records, and outputs the state of the generator on its own during startup, operation, and stop during the test operation by the safety check of the emergency generator. The unmanned safety inspection system using the self-diagnosis intelligent generator and the unmanned safety inspection method using the self-diagnosis intelligent generator to prevent the errors and omissions caused by the method of checking the status of the generator manually by means of manual operation are prevented. To provide.

In addition, another object of the present invention by using a self-diagnostic intelligent generator to perform a safety check in a method of operating the emergency power supply system unattended in the safety management method of the emergency generator in the same way as the actual disaster condition. Unmanned safety inspection system using self-diagnosis intelligent generator and unmanned safety inspection using self-diagnosis intelligent generator to solve the problem of failing to guarantee the normal operation of emergency power supply system in the event of an actual disaster caused by the safety management method that configures the disaster occurrence condition artificially To provide a way.

According to a feature of the present invention for achieving the above object, a commercial power source for providing a main power for the operation of the load; An emergency generator for inputting power generation in an emergency according to the inability to use the commercial power; A generator control panel for monitoring a safety check cycle of the emergency generator, generating a safety check signal upon arrival of the corresponding time point, transmitting a signal to a switchgear, and generating and sending the emergency generator stop signal to a switchgear after a specified trial run time; Receive the safety check signal of the generator control panel to cut off commercial power to configure the conditions of power failure, and after the start of the emergency generator, the generator power is supplied to the ATS changer during normal operation, and the emergency generator stop signal is received from the generator control panel. Switchgear panel to cut off the power and turn on commercial power; It is characterized in that it comprises a; load consisting of the general load, fire load, emergency load to perform the function for the disaster prevention and rescue of life by receiving the power generation from the commercial power and emergency generator.

In such an unmanned safety check system using a self-diagnostic intelligent generator according to the present invention, the commercial power is supplied to the transformer through an automatic switchgear and MOF (mechanical current transformer), by converting the commercial power to a low voltage in the transformer An unmanned safety inspection system using a self-diagnostic intelligent generator, which is supplied to a load, but installed to cut off the connection between the load and the commercial power when an accident occurs by installing an ACB (air circuit breaker) between the load and the transformer.

In the unmanned safety check system using a self-diagnostic intelligent generator according to the present invention, the emergency generator is connected to the switch to perform the switching function using the ATS switch in the switchgear is installed to be connected to or disconnected from the load by the switch The switchboard is controlled by a controller composed of an MCU including an input / output device of a switchgear for detecting a safety check signal, so that part of the load is connected to an emergency generator to perform power switching. Inspection system.

In the unmanned safety check system using the self-diagnostic intelligent generator according to the present invention, the generator control panel monitors the safety check interval of the emergency generator, generates a safety check signal when the arrival of the time point and sends a safety check signal to the switchboard And a controller comprising an MCU including an input / output device for generating and transmitting the emergency generator stop signal to a switchgear after a specified trial run time, and the output voltage, output current, and frequency of the emergency generator when the emergency generator is started, operated and stopped. A measuring instrument for measuring specified items such as coolant temperature and lubricating oil pressure, an output unit for receiving a measured value of the measuring instrument from the controller and outputting it using a print for recognition by a user, and a signal output according to the controller. It consists of an alarm that generates an alarm sound according to safety When the inspection point arrives, it sends a safety check signal to the switchgear, detects the power failure signal from the switchgear, starts the emergency generator, turns on the power generation, and stops the emergency generator after the designated trial run time of the emergency generator has passed. After generating and sending to the switchgear, and detecting the power failure release signal of the switchgear characterized in that the operation of the emergency generator is stopped.

In the unattended safety inspection system using a self-diagnostic intelligent generator according to the present invention, the measuring instrument is a current transformer for measuring the current value, a transformer for measuring the voltage value, a frequency measuring instrument, a temperature sensor, a pressure sensor Unattended safety inspection system using a self-diagnostic intelligent generator, characterized in that, including, and transmit the measured information to the controller of the generator control panel

In the unmanned safety check system using the self-diagnostic intelligent generator according to the present invention, the switchgear monitors the abnormality of the switching operation of the ATS switch during the test operation for the safety check of the emergency generator, the current value, voltage of the power supply Measure the value, frequency, characterized in that sent to the controller of the generator control panel.

The unmanned safety inspection method using the unmanned safety inspection system using the self-diagnostic intelligent generator according to the present invention is a generator control panel monitors the safety inspection cycle of the emergency generator, and detects whether commercial power is supplied to the load from the main power source A safety check waiting step for monitoring a safety check signal; A safety check generation step of the generator control panel monitoring a safety check cycle of the emergency generator to determine the arrival of a safety check point; A power failure condition constituting step in which the switchgear receives a safety check generation signal from the generator control panel, and cuts off commercial power to configure the same condition as in the case of power failure; A generator driving step of starting the emergency generator by detecting that a power failure occurs because the commercial power source of the main power is blocked by the generator control panel; A load connection step of the switchgear detecting a normal voltage output of the emergency generator and operating a transfer switch to input power generation power; Resolving the power failure condition that the switchgear receives the emergency generator stop signal from the generator control panel to operate the transfer switch to cut off the power generation power and turn on the commercial power; A generator stopping step of stopping, by the generator control panel, whether the commercial power is supplied to the load and stopping the emergency generator; The generator control panel comprises a test operation completion step of outputting a result after the emergency generator is stopped and the test operation is completed, including; and, when the start-up failure of the emergency generator and the switching of the ATS switch of the switchboard is activated It is characterized by.

The unmanned safety check system using the self-diagnostic intelligent generator according to the present invention and the unmanned safety checking method using the same are provided by the self-diagnostic intelligent generator when the safety check point arrives in the safety management of the emergency generator or when the safety check is required by the user. In the event of a power outage, the emergency power supply system is not operated and emergency in case of disaster and power failure due to the management failure caused by manual management by the conventional human resources by judging whether the emergency power supply system is normally operated by itself. Power supply system can be prevented from failure in advance, so that more appropriate disaster response is possible.

In addition, the unmanned safety check system using the self-diagnostic intelligent generator and the unmanned safety check method using the self-diagnostic intelligent generator according to the present invention measures and records the state of the generator during start-up, operation and stop of the generator during test operation by the safety check of the emergency generator. By using the self-diagnostic intelligent generator which outputs the power, the safety management of the emergency generator is possible by preventing the errors and omissions caused by the method of checking the status of the generator manually by the conventional human resources in advance.

In addition, the unmanned safety check system using the self-diagnostic intelligent generator and the unmanned safety check method using the self-diagnostic intelligent generator according to the present invention is a method of operating the emergency power supply system unattended in the safety management method of the emergency generator in the same way as the actual disaster condition. By using a self-diagnostic intelligent generator that performs a safety check, it is possible to solve the problem of failing to guarantee the normal operation of the emergency power supply system in the event of an actual disaster caused by the conventional safety management method of artificially configuring a disaster occurrence condition.

1 is a configuration example showing the configuration of an unmanned safety check system using a self-diagnostic intelligent generator according to the present invention
Figure 2 is a connection diagram showing the connection of the unmanned safety check system using a self-diagnostic intelligent generator according to the present invention
Figure 3 is a flow chart for explaining an unmanned safety check method using a self-diagnostic intelligent generator according to the present invention
Figure 4 is a flow chart for explaining the signal flow of the generator control panel and switchboard

Hereinafter, with reference to the accompanying drawings, preferred embodiments of the present invention will be described to be easily carried out by those of ordinary skill in the art. In the accompanying drawings, it should be noted that the same reference numerals are used in the drawings to designate the same configuration in other drawings as much as possible. In addition, in describing the present invention, when it is determined that a detailed description of a related known function or known configuration may unnecessarily obscure the subject matter of the present invention, the detailed description thereof will be omitted. And certain features shown in the drawings are enlarged or reduced or simplified for ease of description, the drawings and their components are not necessarily drawn to scale. However, those skilled in the art will readily understand these details.

1 is a configuration example showing the configuration of an unmanned safety check system using a self-diagnostic intelligent generator according to the present invention.

Referring to FIG. 1, an unmanned safety check system using a self-diagnostic intelligent generator includes a commercial power source 10, an emergency generator 20, a generator control panel 30, a switchgear 40, and a load 50.

The commercial power supply 10 is configured to be supplied to the load through the switchgear 40 for the operation of the load 50 as a main power source.

In addition, such a commercial power supply (10) 'disaster' in the event of a fire, power outage and equivalent disaster situation (hereinafter, fire, power outage and power supply impossible, and the normal power supply to the load 50 in other situations) The load 50 is supplied with normal power in other situations.

The emergency generator 20 is configured to produce power generated in the event of a disaster, and to supply the generated power to the load 50 through the switchgear 40. Power generation power supplied at this time is to supply power to the fire and emergency load consisting of alarm equipment, fire fighting equipment and fire fighting equipment.

Therefore, it is possible to supply power to the fire and emergency loads that are needed quickly by performing the normal functions of the emergency power supply system in the event of a disaster, thereby minimizing the physical and human damage that may occur during a disaster. Therefore, the safety management for the normal function of the emergency generator 20 is always very important to prevent in advance.

The generator control panel 30 monitors the safety check cycle of the emergency generator 20, generates a safety check signal and sends a signal to the switchgear 40 when the corresponding time arrives, and after the required operating time has elapsed, the emergency generator 20 sends a stop signal to the switchboard 40 to monitor and record the state of the emergency generator 20 and output it.

The configuration and detailed functions of the generator control panel 30 will be described in detail with reference to the other drawings below.

The switchgear 40 receives the safety check signal from the generator control panel 30 to shut off the commercial power supply 10, configure the conditions during power failure, and switch the power generation to ATS switching during normal operation after starting the emergency generator 20. Injecting, when receiving the stop signal of the emergency generator 20 from the generator control panel 30 is configured to cut off the power generation and input the commercial power.

The load 50 receives main power from the commercial power supply 10 in a normal situation where a disaster does not occur, consumes power, and performs a desired function. And in the event of a disaster, power generation is supplied from the emergency generator 20 to perform a function for disaster prevention and rescue of life.

To this end, the load 50 is typically divided into general load, emergency load, and fire load in a disaster situation.

Figure 2 is a connection diagram showing the connection of the unmanned safety check system using a self-diagnostic intelligent generator according to the present invention.

2, the unmanned safety inspection system using a self-diagnostic intelligent generator is composed of a commercial power supply 10, emergency generator 20, generator control panel 30, switchgear 40, the load 50 are interconnected. .

The commercial power supply 10 supplied from KEPCO is supplied to the transformer 43 through the automatic section switch 41 and the MOF (meter current transformer) 42. The transformer 43 converts the commercial power supply 10 into a low pressure that can be used by the load 50 and supplies it to the load 50. At this time, the ACB (air circuit breaker, 44) is installed between the load 50 and the transformer 43 to cut off the connection of the load 50 and the commercial power supply 10 in case of an accident.

The emergency generator 20 is connected to the switch 45 in the switchgear 40, it is connected to or disconnected from the load 50 by the switch 45. The switcher 45 is controlled by the controller 47 of the switchboard 40 that detects a safety check signal to perform power switching so that a part of the load 50 is connected to the emergency generator 20.

The controller 31 of the generator control panel 30 monitors the input safety check cycle, and when the corresponding time arrives, a trial run for determining whether the emergency generator 20 and the emergency power supply system are abnormal is performed. Advance notice through 34).

After the preliminary notice is completed, the controller 31 of the generator control panel 30 generates a safety check signal and sends the safety check signal to the controller 47 of the switchgear 40. The commercial power supply 10 is controlled by the controller 47 of the switchgear 40. ) Is shut off to sense that the conditions at the time of power failure are configured to drive the emergency generator 20.

At this time, the controller 31 of the generator control panel 30 monitors the starting state of the emergency generator 20 and restarts in case of failure. In addition, the alarm 34 is activated in the event of a failure by starting more than a specified number of times.

When the emergency generator 20 is started and the normal voltage is output, the controller 47 of the switchgear 40 operates the switcher 45 to supply the power generated from the emergency generator 20 to the fire load 52 and Supply to the emergency load (53).

In addition, the controller 47 of the switchgear 40 monitors the operation state of the switcher 45, restarts it when it fails, and attempts a specified number of times to send a failure signal to the controller 31 of the generator control panel 30 in case of failure. By sending the alarm 34 of the generator control panel 30 to be operated.

The measuring unit 46 of the switchgear 40 detects measured values of specified matters such as voltage value, current value and frequency of the power generation power supplied from the emergency generator 20, and sends them to the output unit 33 of the generator control panel 30. So that it can be printed.

The controller 31 of the generator control panel 30 generates a stop signal of the emergency generator 20 and sends it to the controller 47 of the switchgear 40 after the designated trial run time has elapsed, and the controller of the switchgear 40. When the 47 receives the emergency generator 20 stop signal, operates the switcher 45 to cut off the power generated from the emergency generator 20, and detects that the power failure is eliminated by inputting the commercial power 10. The emergency generator 20 is stopped.

The controller 31 of the generator control panel 30 confirms that the emergency generator 20 is stopped and the commercial power supply 10 is normally supplied to the load 50 to operate the alarm to complete the trial run for safety check. Inform them.

The measuring instrument 32 of the generator control panel 30 measures measured values of specified matters such as the output voltage, the output current, the frequency, the coolant temperature, the lubricant pressure, and the like of the emergency generator 20 when the emergency generator 20 is started, operated, and stopped. It is detected and sent to the output unit 33 to be output.

Hereinafter, an unmanned safety check method using an unmanned safety check system using the self-diagnostic intelligent generator will be described.

3 is a flow chart for explaining the unmanned safety check method according to the invention, Figure 4 is a flow chart for explaining the signal flow of the generator control panel 30 and the switchgear (40).

Unattended safety check method according to the present invention is a safety check waiting step (S100), safety check generation step (S200), power failure condition configuration step (S300), generator driving step (S400), load connection step (S500), eliminating the power failure condition It is configured to include a step (S600), a generator stop step (S700), a trial run completion step (S800).

The safety check waiting step (S100) is a step in which the generator control panel 30 recognizes a designated safety check cycle of the emergency generator 20 and monitors the arrival of a time point.

The safety check generation step (S200) is a step in which the generator control panel 30 for monitoring the safety check cycle of the emergency generator 20 in the safety check wait step (S100) determines the arrival of the safety check point.

In addition, in this step, when the safety check point does not arrive, the safety check wait step S100 is performed again, and when the safety check point arrives, the power failure condition configuration step S300 is performed.

The power failure condition configuration step (S300) is a step in which the switchgear 40 receives the safety check generation signal from the generator control panel 30, and shuts off the commercial power supply 10 to configure the same condition as in the power failure.

The generator driving step (S400) is a step in which the generator control panel 30 detects that the commercial power supply 10, which is the main electric power, is cut off to start an emergency generator 20 by detecting a power failure.

In this step, the generator control panel 30 monitors the starting state of the emergency generator 20, and restarts in case of failure. If it starts more than a specified number of times, if it fails, the test run for safety check is stopped and the alarm 34 is operated.

In the load connection step (S500), when the emergency generator 20 is started in the switchgear 40 and the normal voltage is output, the power switch 52 operates the power switch 52 to operate the power generator supplied from the emergency generator 20. And supplying to the emergency load 53.

In addition, the controller 47 of the switchgear 40 monitors the operation state of the switcher 45, restarts it in the case of failure, and attempts the specified number of times to stop the trial run for safety check in case of failure, and the generator control generator control panel ( By sending a failure signal to the controller 31 of 30), the alarm 34 of the generator control panel 30 can be operated.

In the step S600, the controller 31 of the generator control panel 30 generates a stop signal of the emergency generator 20 and sends it to the controller 47 of the switchgear 40 after the designated trial run time elapses. Then, the controller 47 of the switchgear 40 receives the emergency generator 20 stop signal to operate the switcher 45 to cut off the generator power supplied from the emergency generator 20, and the commercial power source 10. This step is to eliminate the power failure.

The generator stop step (S700) is a step in which the controller 31 of the generator control panel 30 detects that the commercial power 10 is being supplied to the load 50 and stops the emergency generator 20.

In the test operation completion step (S800), the controller 31 of the generator control panel 30 checks the stop state of the emergency generator 20, operates the alarm 34 to notify that the test operation is completed, and measures the switchboard 40. The measured value of the power generation power supplied to the fire load 52 and the emergency load 53 measured at 46 and the measured value of the emergency generator 20 measured by the measuring device 32 of the generator control panel 30 are outputted. 33).

On the other hand, in the commissioning of the emergency power supply system for the safety check, the flow of signals between the generator control panel 30 and the switchboard 40 can be more detailed as shown in FIG.

In detail, the generator control panel 30 monitors the safety check cycle and sends a safety check signal to the switchboard 40 to generate a safety check signal when the corresponding time arrives (ss01); An electrostatic condition configuration detecting step (ss02) in which the switchboard 40 receiving the safety check signal by the generator control panel 30 blocks the commercial power supply 10 to configure the condition at the time of power failure; A generator driving step (ss03) for driving the emergency generator 20 by detecting that the generator control panel 30 blocks the commercial power supply 10 supplied to the load 50; The power switchboard 40 detects that the normal voltage is output from the emergency generator 20 and inputs the generated power to the fire load 52 and the emergency load 53 (ss04); A generator stop signal transmission step (ss05) for transmitting the generator stop signal to the power distribution 40 after the designated trial run time has passed by the generator control panel 30; The power switchboard 40 receiving the generator stop signal cuts off the power generation power supplied to the load 50 and inputs the commercial power 10 and the commercial power supply step (ss06); The generator control panel 30 detects the elimination of the electrostatic condition for detecting that the commercial power 10 is supplied to the load 50 (ss07); Generator control panel 30 is a generator stop step (ss08) for stopping the emergency generator 20 by detecting that the power failure condition is eliminated; is configured to include.

Specific embodiments have been shown and described in order to illustrate the technical idea of the present invention, but the present invention is not limited to the same configuration and preparation as the specific embodiments as described above, and various modifications do not depart from the scope of the present invention. It may be practiced within limits. Accordingly, such modifications should also be considered to be within the scope of the present invention, the scope of which should be determined by the claims set forth herein.

10: commercial power 20: emergency generator 30: generator control panel
31 controller 32 instrument 33 output device
34: alarm 40: switchgear 41: automatic switchgear
42: MOF 43: Transformer 44: ACB
45: transfer machine 46: instrument 47: controller

Claims (7)

A commercial power source 10 providing main power for the operation of the load 50;
Emergency generator 20 for inputting the power generation power in emergency according to the unavailable of the commercial power (10);
Monitoring the safety check cycle of the emergency generator 20, generates a safety check signal when the time arrives to send a signal to the switchgear 40, to stop the emergency generator 20 after a specified trial run time A generator control panel 30 for generating a stop signal and transmitting the generated stop signal to the switchboard 40;
Receiving the safety check signal of the generator control panel 30 to cut off the commercial power supply 10 to configure the conditions of power failure, and after the start of the emergency generator 20, the generator power supply to the ATS switcher during normal operation A switchgear (40) for receiving the emergency generator (20) stop signal from the (30) to cut off the power generation and input the commercial power (10);
Load consisting of a general load 51, a fire load 52, an emergency load 53 to receive the power generation power from the commercial power source 10 and the emergency generator 20 to perform a function for disaster prevention and rescue of life In the unattended safety check system using a self-diagnostic intelligent generator, characterized in that configured to include;

The generator control panel 30 monitors the safety check cycle of the emergency generator 20, generates a safety check signal upon arrival of the corresponding point in time, sends a safety check signal to the switchgear 40, and after the designated trial run time, the emergency A controller 31 comprising an MCU including an input / output device for generating a generator 20 stop signal and sending the signal to the switchboard 40;
A measuring device 32 for measuring specified items such as an output voltage, an output current, a frequency, a coolant temperature, and a lubricating oil pressure of the emergency generator 20 when the emergency generator 20 is started, operated and stopped;
An output unit 33 which receives the measured value of the measuring instrument 32 from the controller 31 and outputs it using a print so that a user can recognize the measured value;
It is composed of an alarm 34 for generating an alarm sound according to the signal output according to the controller 31 to send a safety check signal to the switchgear at the arrival of the safety check point, to detect the commercial power failure signal from the switchgear to start the emergency generator To generate power, and to generate a stop signal of the emergency generator after the designated trial run time of the emergency generator is passed to the switchgear, and to stop the operation of the emergency generator when the breakdown signal of the switchgear is detected. Unattended safety check system with self-diagnostic intelligent generator.
delete delete delete The method of claim 1,
The measuring instrument 32 includes a current transformer for measuring a current value, a transformer for measuring a voltage value, a frequency measuring device, a temperature sensor, a pressure sensor, and the measured information is the generator control panel 30. Unattended safety check system using a self-diagnostic intelligent generator, characterized in that sent to the controller 31 of the. delete delete

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