KR102323689B1 - Method of monitoring electricity equipment anti-seismic device and sensing earthquake using distance measurement of optical type - Google Patents

Abstract

The present invention provides a method for monitoring a seismic device of electrical installations and detecting earthquakes by optical distance measurement. The method of the present invention enables detection of an earthquake that suddenly occurs in the process of regularly monitoring performance of a seismic device consisting of electrical installations that degrade over time by distance measurement using an optical sensor, thereby allowing a manager to be notified promptly and escape from the danger. Meanwhile, to check the performance of the seismic device and take appropriate measures accordingly, when a distance measurement shows that the seismic device of the electrical installations has reached a threshold over time, a spring replacement indication is displayed to maintain the seismic performance. If the distance measurement in this process is out of a range of normal values for keeping the seismic performance and continues to fluctuate, the continuous fluctuation of the distance measurement is promptly notified to the manager and the earthquake is displayed so that the manager can escape from the danger. Afterward, the seismic device has to be inspected on the spot for protection or the inspection can be skipped depending on the situation, thus time and costs can be saved.

Description

Method of monitoring electricity equipment anti-seismic device and sensing earthquake using distance measurement of optical type

The present invention relates to a seismic device monitoring and seismic detection method of electrical equipment by optical distance measurement, and more particularly, to a seismic device performance of electrical equipment that decreases over time by measuring distance by an optical sensor at all times. It relates to a seismic device monitoring and seismic detection method of electrical equipment by optical distance measurement, which enables to take necessary measures by detecting earthquakes that occur suddenly during this process while monitoring them in a systematic way.

In general, electric equipment for private use such as buildings and factories cannot receive electricity that can be used as it is from the electric power company like 220V low voltage general electric equipment because of the large amount of power required. It is equipped with a power receiving facility for power supply, a substation facility for stepping down the high voltage and special high voltage received from the substation into commercial voltage, and a power distribution facility for supplying the reduced electricity to electrical equipment and lighting in buildings and factories, ensuring safe and efficient electricity is supplied by

On the other hand, large and small earthquakes in various regions of the world cause a lot of damage to human life and property. In particular, strong earthquakes occur frequently in neighboring countries such as Japan and China, so Korea is no longer safe from earthquakes. Measures such as maintenance of the national disaster system and strengthening of earthquake-resistant design of buildings are being taken to minimize damage in the event of an emergency.

In relation to the electrical equipment installed on the floor of a building, if vibration or shock occurs due to vibration or shock caused by mechanical vibration or earthquake caused by vibration of the floor or electromagnetic force due to large-scale electricity supply, internal devices and wiring connecting these devices, etc. Since vibration or shock can be transmitted and damaged, it is designed as a seismic type to prevent this, but there is a limit to strengthening the seismic design due to various socio-economic constraints.

Moreover, for consumers of large-capacity electricity in buildings such as factories and buildings, electric facilities are installed in remote places such as basements or rooftops of buildings where people rarely travel due to the nature of receiving and converting the extra-high voltage and high-voltage power supplied by the electric power company into low voltage. Because the earthquake warning system of the Korea Meteorological Administration, which is issued to the people in the building to evacuate quickly in the event of an earthquake, is notified after a certain period of time has elapsed after the earthquake occurs, managers It is difficult to evacuate quickly outside.

1 is a configuration diagram of a switchgear having a conventional earthquake detection function.

From this, in Patent No. 10-1035647 (title of invention: switchboard with earthquake detection function), as shown in FIG. Although a technology that can detect an earthquake at an early stage has been proposed, additional parts are required and cumbersome because the seismic sensor must be installed separately inside the enclosure. There is a need for a realistic and practical way to do this.

Patent No. 10-1035647 (Title of the invention: Switchgear with earthquake detection function)

This invention is to solve the above problem, and while constantly monitoring the seismic device performance of electrical equipment that decreases over time by measuring the distance by an optical sensor, it detects an earthquake that occurs unexpectedly in this process. The task is to provide a method for monitoring seismic devices and detecting earthquakes in electrical installations by optical distance measurement, which enables them to quickly inform the public and escape from danger while also checking the performance of the seismic device and taking appropriate measures accordingly.

In order to solve the above problem, the present invention comprises the steps of: transmitting light at predetermined time intervals from the inside of the seismic device 110 to the photosensor 120 and measuring the received distance after reflection (S101); Determining whether the measured value continues to fluctuate (S102) in the step (S101), and if it is determined that the measured value does not continue to fluctuate, determining whether the measured value has reached a threshold for the normal value of the performance of the seismic device 110 ( S103); If it is determined that the measured value has not reached the threshold in the step S103, the process returns to the step S101, and the subsequent steps are performed. ); If it is determined that the threshold value is reached and it is not maintained for a predetermined time in the step (S104), the process returns to the step (S101) and the subsequent steps are performed. displaying the replacement as an alarm and returning to the step (S101) to perform subsequent steps (S105); Determining whether the measured value continues to fluctuate in the step (S101) (S102), and when it is determined that the measured value continues to fluctuate, determining whether the measured value deviates from the range of fluctuation based on the normal value of the performance of the seismic device 110 ( S106); If it is determined that the measured value does not deviate from the fluctuation range in the step S106, it is determined whether the threshold value for the normal value of the performance of the seismic device 110 has been reached in the step S103 and the subsequent steps are performed, and the measured value is outside the fluctuation range If it is determined that the predetermined time is maintained (S107); And, if it is determined in the step (S107) that the measured value is out of the fluctuation range but not maintained for a predetermined time, it is determined in the step (S103) whether the threshold for the normal value of the performance of the seismic device 110 has been reached and the subsequent steps are performed and, if it is determined that the measured value is maintained for a predetermined time out of the range of fluctuations, the alarm unit 140 displays an earthquake as an alarm and returns to the step (S101) to perform the subsequent steps (S108); Without the seismic sensor of In the above step (S103), the measurement value does not deviate from the fluctuation range in the step (S106) or the fluctuation range is outside the fluctuation range in the step (S107) but is not maintained for a predetermined time in the above step (S103). ), it is judged with caution and additional inspection of the seismic device 110 is not performed. Provides a seismic device monitoring and seismic detection method of an electrical facility by optical distance measurement, characterized in that it is judged as a risk even if it does not reach the seismic device 110 and additional inspection is performed.

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According to the seismic information monitoring and seismic sensing method of the electric equipment by the optical distance measurement of the present invention having the above solution means, while constantly monitoring the seismic equipment performance of the electric equipment, which decreases with time, at the same time By making it possible to detect earthquakes that occur suddenly during the process by measuring the distance by means of an optical sensor, the configuration is simple and maintenance is convenient, and the earthquake-resistant device of electrical equipment has reached a critical value over time. When the distance value is measured, the replacement of the spring is displayed as an alarm to maintain seismic performance. It has the effect of promptly and efficiently responding to earthquakes, such as by displaying an earthquake as an alarm, and then ensuring that the earthquake-resistant device can be protected by inspecting the site depending on the situation, or by omitting the inspection to save time and money. .

1 is a configuration diagram of a switchgear having a conventional earthquake detection function;
2 is a block diagram showing a seismic device monitoring and earthquake detection device that implements a seismic device monitoring and earthquake detection method of an electrical facility by optical distance measurement according to an embodiment of the present invention;
3 is a view showing normal values, thresholds, and fluctuation ranges as a standard for monitoring and detecting earthquakes by measuring the distance of an optical sensor inside the seismic device of the earthquake-resistant device monitoring and earthquake detection device of FIG. 2;
4 is a flowchart illustrating a process of implementing the earthquake-resistant device monitoring and earthquake detection method of an electrical facility by optical distance measurement according to an embodiment of the present invention;
5 is a view showing the threshold value for the normal value as a standard for monitoring the seismic device of FIG. 3 together with the distance measurement value by the optical sensor;
6A and 6B are diagrams in which the fluctuation range with respect to the normal value as a reference for detecting an earthquake while monitoring the earthquake-resistant device of FIG. 3 is displayed together with the distance measurement value by the optical sensor.

Hereinafter, a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings, which is intended to be described in detail so that a person of ordinary skill in the art to which this invention pertains can easily implement, thereby It does not mean that the technical spirit and scope of this invention are limited. And the terms defining the relative positions such as front and rear, left and right, up and down, inside and outside used are based on the accompanying drawings.

FIG. 2 is a block diagram illustrating a seismic device monitoring and earthquake detection device that implements a seismic device monitoring and earthquake detection method of an electric facility by optical distance measurement according to an embodiment of the present invention, and FIG. 3 is a diagram of FIG. It is a diagram showing the normal value, threshold value, and fluctuation range as a standard for seismic device monitoring and earthquake detection by measuring the distance of an optical sensor inside the seismic device among seismic device monitoring and earthquake detection devices.

As shown in Figs. 2 and 3, the seismic device monitoring and earthquake detection device 100 for electrical equipment implementing the method according to an embodiment of the present invention includes a seismic device 110, an optical sensor 120, and Including the control unit 130 and the alarm unit 140, it is possible to monitor information according to the vibration or shock, it is possible to respond quickly and efficiently when the vibration or shock is applied. Here, the electrical equipment may have a built-in necessary device such as a control unit as a housing and have an alarm unit on the front side.

The seismic device 110 is installed between the lower part of the enclosure and the floor of the electrical equipment to enable earthquake resistance by a buffer action that absorbs and reduces vibration or shock applied from the floor while supporting the electric equipment, and the upper case 111 ), a lower case 112 , an upper and lower case connection part 113 , and a spring 114 .

The upper case 111, the upper part is located in the lower part of the enclosure of the electrical equipment, and forms a lower part to be opened while being bent inward by a predetermined distance from both side ends.

The lower case 112 has a lower portion on the bottom surface, and forms an upper portion to be opened while being bent by a predetermined distance inward from both side ends.

The upper and lower case connection part 113 is bent inward from both side ends of the upper case 111 and the lower case 112 so that the facing parts are mounted with bolts passing through, and the ends are coupled with nuts, the upper case ( 111) and the lower case 112 are maintained in a connected state while spaced apart by the screw length of the bolt.

The spring 114 is bent inward from both side ends of the upper case 111 and the lower case 112 while penetrating the open portion and is installed between the lower part of the enclosure and the bottom surface of the electrical equipment, and the upper and lower case As it vibrates up and down as much as the length of the bolt screw of the connection part 113 , it prevents earthquake-resistant damage such as conduction or vibration of the electrical equipment itself by a buffering action that absorbs and reduces vibration and shock transmitted from the floor.

The photosensor 120, in the embodiment of the present invention, transmits light in units of 0.1 seconds and receives the transmitted light reflected in units of 0.1 seconds.

The optical sensor 120 is attached to the lower part of the enclosure of the electrical equipment inside the upper case 111, and the upper and lower case connection part 113 connecting the upper case 111 and the lower case 112. Measure the distance using the length of the bolt screw as the range.

In general, in order to detect an earthquake, an earthquake sensor should be separately provided as shown in FIG. 1 , but in the embodiment of the present invention, the configuration is simplified by detecting an earthquake in the process of monitoring the conventional earthquake-resistant device 110 , and maintenance becomes convenient

The control unit 130 receives the distance measured with the bolt screw length of the upper and lower case connection unit 113 as a range from the optical sensor 120 connected by wire or wirelessly as a reference for seismic monitoring and earthquake detection If an abnormality occurs by determining whether it is out of a set range, the alarm unit 140 displays an alarm, and if necessary, it can be controlled to share the measurement result in connection with an external system or other manager device through a network.

Here, the control unit 130 determines differently depending on whether the distance measured by the optical sensor 120 continues to fluctuate. The alarm unit 140 displays the replacement of the spring 114 as an alarm, depending on whether the threshold for the normal value of is reached and whether the threshold is maintained for a predetermined time. 110) The alarm unit 140 controls the earthquake to be displayed as an alarm depending on whether the fluctuation range is out of the normal performance standard and whether the fluctuation range continues for a predetermined time.

In addition, in the case where the measured value continues to fluctuate, the measured value does not deviate from the fluctuation range, or when the measured value does not exceed the fluctuation range but does not reach the threshold value in a state that is not maintained for a predetermined period of time, it is judged with caution, 110) is not performed, and in a state in which the measured value is maintained for a predetermined time out of the range of fluctuations, even if the threshold value is not reached, it is determined as a risk and additional inspection of the seismic device 110 can be performed.

The alarm unit 140 may be provided on the front side of the electrical equipment, and when a vibration or shock is applied by monitoring without performing a separate operation when the measured value is normal within a set range, Controlled information and corresponding countermeasure alarms are displayed audiovisually through warning lights, speakers, etc., so that the administrator can take appropriate countermeasures.

The process of implementing the method according to an embodiment of the present invention using the earthquake-resistant device monitoring and earthquake detection device 100 as described above will be described in detail with reference to the accompanying drawings.

4 is a flowchart illustrating a process of implementing a seismic device monitoring and earthquake detection method of an electrical facility by optical distance measurement according to an embodiment of the present invention, and FIG. 5 is a normal value as a standard for monitoring the seismic device of FIG. 3 It is a view showing the threshold value for , together with the distance measurement value by the optical sensor, and FIGS. 6A and 6B are the distance measurement values by the optical sensor as a reference for detecting an earthquake while monitoring the seismic device of FIG. 3 . The drawing is shown with

First, as shown in FIG. 4 , the control unit 130 transmits light from the optical sensor 120 at a predetermined time interval of, for example, 0.1 second, reflects it in 0.1 second, and then measures the received distance ( S101), it is controlled to determine whether the measured value continues to fluctuate (S102).

Next, if it is determined that the measured value does not continue to fluctuate in step S102 in the control unit 130, it is controlled to determine whether the measured value of the photosensor 120 has reached a threshold for the normal value of the performance of the seismic device 110. (S103).

Here, when the maintenance of the seismic device 110 is easy, when the initial state of the spring 114 is based on 100% of the normal, 80% can be set as a critical value to be careful and 60% to be replaced, The numerical value can be adjusted by reflecting it according to the situation.

And if the control unit 130 determines that the measured value does not reach the threshold value in step S103, it returns to step S101 and transmits light at a predetermined time interval from the optical sensor 120 and measures the received distance after reflection While performing the subsequent steps, the monitoring of the seismic device 110 is continuously controlled.

In addition, as shown in FIG. 5 , when the controller 130 determines that the measured value has reached the threshold value in step S103, the spring 114 may temporarily reach the threshold value due to an instantaneous impact. It is controlled to determine whether it is maintained for a predetermined time, for example, 5 minutes (S104).

And if the control unit 130 determines that the measured value reaches the threshold value in step S104 but is not maintained for a predetermined time, returns to step S101 and transmits light at predetermined time intervals from the photosensor 120 and receives it after reflection It continuously controls the monitoring of the seismic device 110 while performing the subsequent steps by measuring the distance.

In addition, when the control unit 130 determines that the measured value reaches the threshold value and is maintained for a predetermined time in step S104, the alarm unit 140 displays an alarm to replace the spring 104 (S105), and the Returning to step S101, light is transmitted from the photosensor 120 at predetermined time intervals and the received distance is measured after reflection to continuously control the monitoring of the seismic device 110 while performing the subsequent steps.

On the other hand, in the control unit 130, as shown in FIGS. 6A and 6B, when it is determined that the measured value continues to fluctuate in the step S102, the measured value of the photosensor 120 is of the seismic resistance device 110 performance. Control is determined to determine whether the fluctuation range is out of the normal value reference (S106).

Here, the normal value of the performance of the seismic device 110 is based on the initial state of the spring 114, and it is determined whether the earthquake is up and down by 30%, and the specific range can be reflected and adjusted according to the situation.

And if the control unit 130 determines that the measured value of the photosensor 120 does not deviate from the fluctuation range in step S106, it is determined whether the threshold value for the normal value of the performance of the seismic device 110 has been reached in the step S103, and then step is performed, and when it is determined that the measured value of the photosensor 120 is out of the fluctuation range, it is controlled to determine whether it lasts for a predetermined time, for example, 5 minutes (S107).

Here, if the measured value does not deviate from the fluctuation range in step S106 or exceeds the fluctuation range in step S107 but does not reach the threshold value of step S103 in a state that is not maintained for a predetermined time, it is judged with caution and additional inspection of the seismic device 110 do not do

In addition, in the control unit 130, if it is determined that the measured value is outside the fluctuation range in step S107 but not maintained for a predetermined time, it is determined whether the threshold value for the normal value of the performance of the seismic device 110 has been reached in the step S103 and subsequent steps When it is determined that the measured value of the photosensor 120 is maintained for a predetermined time out of the range of fluctuation, the alarm unit 140 displays an earthquake as an alarm, and returns to step S101 and controls to perform subsequent steps. (S108).

Here, in the state in which the measured value exceeds the fluctuation range in step S108 and is maintained for a predetermined time, it is judged as a risk even if the emergency evacuation including the manager or the threshold value of step S103 is not reached, and additional inspection of the seismic device 110 must be performed. make it

Therefore, in the embodiment of the present invention, seismic detection is simultaneously performed in the process of constantly monitoring the performance of the seismic device of the electrical equipment, so that it is possible to quickly and efficiently cope with it in the field.

The present invention is not limited to the above embodiments, and various modifications are possible within the scope of the invention described in the claims, and such modifications are also included within the scope of the present invention.

100: seismic device monitoring and earthquake detection device implementing a method according to an embodiment of the present invention
110: seismic device
111: upper case
112: lower case
113: upper and lower case connection part
114: spring
120: light sensor
130: control unit
140: alarm unit
S101 to S108: The process of monitoring and seismic sensing of an electrical equipment seismic device by optical distance measurement in a method according to an embodiment of the present invention

Claims (2)

delete Step (S101) of measuring the received distance after transmitting light at predetermined time intervals from the inside of the seismic device 110 to the optical sensor 120 and reflecting it;
Determining whether the measured value continues to fluctuate (S102) in the step (S101), and if it is determined that the measured value does not continue to fluctuate, determining whether the measured value has reached a threshold for the normal value of the performance of the seismic device 110 ( S103);
If it is determined that the measured value has not reached the threshold in the step S103, the process returns to the step S101, and the subsequent steps are performed. );
If it is determined that the threshold value is reached and it is not maintained for a predetermined time in the step (S104), the process returns to the step (S101) and the subsequent steps are performed. displaying the replacement as an alarm and returning to the step (S101) to perform subsequent steps (S105);
Determining whether the measured value continues to fluctuate in the step (S101) (S102), and when it is determined that the measured value continues to fluctuate, determining whether the measured value deviates from the range of fluctuation based on the normal value of the performance of the seismic device 110 ( S106);
If it is determined that the measured value does not deviate from the fluctuation range in the step S106, it is determined whether the threshold value for the normal value of the performance of the seismic device 110 has been reached in the step S103 and the subsequent steps are performed, and the measurement value is outside the fluctuation range If it is determined that the predetermined time is maintained (S107); and,
In the step (S107), if it is determined that the measured value is out of the fluctuation range but not maintained for a predetermined time, it is determined whether the threshold for the normal value of the performance of the seismic device 110 has been reached in the step (S103) and the subsequent steps are performed, If it is determined that the measured value is maintained outside the fluctuation range for a predetermined time, the alarm unit 140 displays the earthquake as an alarm, returns to the step S101, and performs the subsequent steps (S108); including,
Without a separate seismic sensor, by measuring the distance by the optical sensor 120 inside the seismic device 110, it is possible to constantly monitor the seismic device performance of the electrical equipment, which decreases over time, and at the same time It enables the detection of earthquakes that occur suddenly during the process,
If the measured value does not deviate from the fluctuation range in the step S106 or the threshold value in the step S103 is not maintained for a predetermined time although the measured value does not deviate from the fluctuation range in the step S107, it is judged with caution and the earthquake-resistant device Without additional inspection of (110), in the state in which the measured value is maintained for a predetermined time out of the fluctuation range in the step (S108), even if the threshold value of the step (S103) is not reached, it is determined as a risk and the earthquake-resistant device (110) Seismic device monitoring and seismic detection method of electrical equipment by optical distance measurement, characterized in that the additional inspection of

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