KR101237881B1 - Power receiving and distributing board for high voltage - Google Patents

Abstract

PURPOSE: A power receiving and distributing board for high voltage is provided to prevent an electric shock accident by generating a warning signal according to the distance between a human body and the power receiving and distributing board. CONSTITUTION: A first infrared radiation net includes a first transmission light emitting rod(410A) and a first reception light emitting rod(410B). The first transmission light emitting rod radiates infrared ray. The first reception light emitting rod senses the infrared ray emitted from the first transmission light emitting rod. The second infrared radiation net includes a second transmission light emitting rod(420A) and a second reception light emitting rod(420B). The second reception light emitting rod senses the infrared ray emitted from the second transmission light emitting rod.

Description

Switchgear with infrared light emitting diodes {Power receiving and distributing board for high voltage}

The present invention relates to a switchgear, and in detail, when an abnormal phenomenon occurs in the switchgear, an administrator may prevent an electric shock accident by detecting an electric shock due to human body contact with a live part due to carelessness during an accident recovery such as inspection and maintenance. It is about the switchboard which can.

In general, the switchgear consists of a special high pressure plate (or the same high pressure plate or less), a modified base for power supply meter, transformer board, and low pressure plate. It is a well-known fact that the interconnection works are used to interconnect each other.

However, in order to check and maintain the switchboard during operation, the manager consciously or unknowingly frequently caused an electric shock death accident due to human contact with the extra-high voltage charging part, and thus, preventive measures were required.

The present invention has been made to solve the above-mentioned problems, an object of the present invention is to detect the movement in accordance with the degree of entry into the high-voltage switchgear for the first electric shock boundary distance proximity alarm when the second electric shock dangerous distance load Or by providing a switchgear that can prevent the electric shock accident in advance by sequentially blocking the main power applied to the switchgear.

In the switchgear according to the present invention, the switchgear is formed in a rectangular shape with an empty inside, and a plurality of frames in which the respective devices are fixed therein are installed vertically and horizontally, and doors are provided in the longitudinal front and rear surfaces of the switchgear. The interior of the switchgear is divided into two or more spaces through the partition wall, and the terminal part and the low voltage cut-off part which are adjacent to each other but separated by the partition wall are located in a space adjacent to one side of the switchgear among the two or more spaces. In case of occurrence, the first light-emitting rod transmitter and receiver are installed in parallel on the inside of the front and rear doors in the first stage to prevent the electric shock from the charging unit. Infrared rays formed in parallel and formed by interaction between the first light-emitting rod transmitter and the receiver In the case of infringement of the first luminous network, the primary warning signal is sequentially cut off the main power applied to the switchgear when the second infrared luminous network is infringed by the interaction between the second light emitting rod transmitter and the receiving unit.

In addition, the first light emitting rod is installed at 80mm to 100mm from the doors on both sides of the door of the switchgear, respectively, the second light emitting rod is characterized in that it is installed on the back 80 ~ 100mm from the first light emitting rod.

In addition, an infrared auxiliary sensor is installed between the first infrared light emitting network and the second infrared light emitting network, and when an object of a predetermined speed or more is detected inside the high-voltage switchgear, the object is formed by the second transmitting and receiving light emitting rod. The alarm and before the power to reach the network is characterized in that at the same time cut off the load and power applied to the switchboard.

According to the present invention configured as described above, the infrared network is formed in the first and second stages inside the switchgear to differentially generate an alarm or to apply the main power applied to the load or the switchgear according to the degree of danger of electric shock to the human body and the object. By blocking it, it is possible to prevent an electric shock accident in advance.

1 is a disconnection diagram showing a system of a general switchgear.
Figure 2 is a view showing a perspective view of a switchgear to which the present invention can be applied.
3 is a view showing a perspective view when the infrared light emitting network is applied to the switchboard according to the present invention.
4 is an enlarged view of a portion A in Fig.
5 is a flowchart illustrating driving an infrared light emitting network.

1 is a disconnected wiring diagram showing a system of a switchgear according to the present invention. As shown, the switchgear is divided into a special high platen (or high platen) 10 and the low platen 20 according to the power supply order and voltage type of the power system. Here, the switchgear refers to power distribution by high or low pressure by receiving extra high or high pressure.

The special high pressure plate 10 receives electricity of a special high pressure supplied from the outside, and the low pressure plate 20 performs a function of sending the low pressure electricity to a plurality of loads.

As shown in FIG. 1, the special high pressure plate 10 is connected to the cables CH1 and CH2 on the KEPCO side, the cable is connected to a load switch AISS, and an arrester (B) to the load switch AISS. LA) and connect it to the enclosure ground box. On the other hand, a load transformer AISS is connected to the instrument transformer MOF in parallel with the arrester LA, and a power fuse PF is installed between the arrester LA and the instrument transformer MOF in parallel. . In addition, by connecting the DM meta to the instrument transformer (MOF) it is possible to examine the state of the switchgear. The other end of the transformer MOF for the instrument is connected to the transformer PT, and is installed in the special high pressure plate 10 of the switchgear up to the above-mentioned part.

The low pressure plate 20 is connected to the capacitor breaker and the capacitor (C) through the low voltage busbar from the transformer (PT), the air circuit breaker (ACB) is connected in parallel, the other end of the air circuit breaker (ACB) MCCB) is connected.

Next will be described the structure of the switchgear according to the present invention. In the following examples, for convenience, it will be described on the basis of the simplified power switchboard, but the present invention is not limited thereto and may be applied to all switchboards within a range that can be created by those skilled in the art.

Figure 2 is a view showing a perspective view of a switchgear to which the present invention can be applied.

According to Figure 2, the switchgear according to the present invention is made of a rectangular rectangular shape, a plurality of frames in which each device is fixed therein is installed vertically and horizontally, the door 110 is installed on the longitudinal front and rear surfaces do. Here, the front and rear surfaces in the longitudinal direction of the switchgear according to the present invention may be further provided with a repair door (not shown). In addition, as shown in Fig. 2, the interior of the switchboard is partitioned into partitions and separated into respective spaces. That is, as shown in Figure 2, the interior of the switchgear according to the present invention is divided into two spaces based on the partition wall formed in the longitudinal direction, one of the two spaces is located in the high-pressure space 210, In the remaining spaces, the terminal unit 220 and the low voltage blocking unit 230 which are adjacent to each other and partitioned by a partition are positioned.

The high-pressure space 210 includes a special input cable (CH1, CH2, ...), load switch (AISS), instrument transformer (MOF), instrument transformer (PT), vacuum circuit breaker (VCB), and instrument current transformer (CT). ) Is electrically connected via a busbar or cable

Next, an infrared light emitting network of the switchboard according to the present invention will be described. Figure 3 is a view showing a perspective view when the infrared light emitting network is applied to the switchboard according to the present invention, Figure 4 is an enlarged view of the portion A of Figure 3, Figure 5 is a block diagram for driving the infrared light emitting network. One drawing. In the present invention, for convenience of description, the infrared light emitting network has been described as being composed of two, but it will be apparent to those skilled in the art that three or more can be mounted within a range that can be created.

According to FIG. 3, the switch panel according to the present invention is provided with a first infrared light emitting rod 410A.B and a second infrared light emitting rod 420A.B. That is, when an abnormal phenomenon occurs in the special high voltage plate inside the switchgear, and the administrator unintentionally touches the charging unit during the inspection and maintenance, the first infrared light emitting network formed by the interaction between 410A and 410B of FIG. 4 is detected. And a second infrared light emitting network (420A, 420B) installed at the dangerous distance of the electric shock accident when the human body and the object is in contact with the detection of the alarm and at the same time load side breaker (ACB) By blocking the and main circuit breaker (VCB) sequentially, an electric shock accident can be prevented from high voltage.

As shown in FIG. 3, it is preferable that the infrared light emitted from the 1.2th infrared transmission / reception light emitting rod emits light in a plurality of directions instead of one direction. In this case, the first infrared light transmitting and receiving rods 410A and 410B are preferably installed at 80 mm to 100 mm from the door 110, and the second infrared transmitting and receiving light emitting rods 420A and 420B are disposed at 160 mm to 200 mm from the door 110. It is preferable to be installed, and the distance between the first transmission and reception infrared light emitting rods 410A and 410B and the second transmission and reception light emitting rods 420A and 420B is preferably 60 to 100 mm apart.

In addition, the length of the first transmission and reception rod and the second transmission and reception rod is preferably 1800mm to 2400mm.

In addition, an infrared auxiliary sensor (not shown) may be additionally provided to detect a moving speed of the object between the door and the first transmission / reception light rod or between the first transmission / reception light rod and the second transmission / reception light rod. That is, by predicting the moving speed of the object detected by the installed auxiliary sensor and the first transmission and reception light-emitting rod, the second transmission and reception light-emitting rod, when the moving speed of the object is a certain speed or more, the object is the second water-transmitting shoe bar (420A, 420B) ), The load side breaker (ACB) and main breaker AISS (VCB) can be cut off in order to prevent electric shock even if the manager enters the switchboard at high speed.

Assuming this point, the distance between the first transmission and reception infrared light emitting rods 410A and 410B and the second transmission and reception light emitting rods 420A and 420B is 60 to 100 mm apart. To 60 to 100 mm. However, this is the optimum separation distance determined by the present inventors after the long-term observation of the size of the switchboard, constraints on manufacturing, and moving speeds of various workers due to characteristics of each person.

In addition, the separation distance between the first transmission and reception infrared light emitting rods 410A and 410B and the second transmission and reception light emitting rods 420A and 420B may be changed according to the design of the switchboard, such as the size of the switchboard.

The first transmitting light emitting rod 410A and the second transmitting light emitting rod 420A include a plurality of infrared light emitting elements to emit infrared light, and the first receiving light emitting rod 410B and the second receiving light emitting rod 420B. An infrared sensor may be included to sense infrared light from the first transmitting light emitting rod 410A and the second transmitting light emitting rod 420A. In addition, it is also possible to additionally install a camera, a sound wave detection sensor, etc. to accurately grasp the movement of the object.

As illustrated in FIG. 5, the alarm control unit 430 has an infrared ray emitting network formed by the first transmitting and receiving light emitting rod and the second transmitting and receiving light emitting rod, and the first transmitting and receiving light emitting light is installed at a danger distance of electric shock boundary in one step. When an object is detected by infrared rays blocked by a person or the like by the infrared networks formed on the rods 410A and 410B, a signal for generating an alarm signal is generated, and the second transmission and reception is formed at the electric shock accident distance in two steps. When an object is detected by an infrared light emitting network formed on the light emitting rods 420A and 420B, an alarm is issued and an electric shock is generated by sending a control signal that can sequentially block the load breaker (ACB) and the main breaker (AISS). It is to prevent accidents.

Looking at the specific operation as shown in Figure 5, when an abnormal phenomenon occurs inside the special high-voltage switchgear panel and the object is detected by the switchgear, the first transmission and reception light emitting rods (410A, 410B), the alarm control unit receiving this detection signal Operation 430 controls the electric shock alarm signal generator to generate an electric shock alarm. In addition, the alarm control unit 430 may be to send a text to the managers of the switchboard. In this case, controlling the text transmission and the like may be a central controller or a control device that controls and monitors water distribution and communicates with an external communication network, and is called a control device in the present invention.

In addition, when an object is detected by the alarm control unit 430 and the second transmission / reception light emitting rods 420A and 420B, the alarm control unit 430 detects the object and controls the electric shock alarm signal generation unit to generate an alarm and at the same time the load breaker ( It generates a blocking signal to block ACB) and main breaker (AISS) in order to prevent an electric shock accident in advance.

In this case, as described above, additional infrared support between the door 110 and the first transmit / receive light emitting rods 410A and 410B and between the first transmit / receive light emitting rods 410A and 410B and the second transmit / receive light emitting rods 420A and 420B. According to the sensed result of installing a sensor (not shown), the alarm controller 430 is configured in advance before the object reaches the second transmitting / receiving light emitting rods 420A and 420B when the speed at which the object enters the switchboard is a certain speed or more. By sequentially blocking the load breaker (ACB) and the main breaker (AISS) it is possible to prevent people from entering the high speed inside the switchgear from being shocked.

The installation position of the additional infrared auxiliary sensor is suitable for an intermediate point between the first transmission / reception light emitting rods 410A and 410B and the second transmission / reception light emitting rods 420A and 420B, in order to exclude mutual interference with infrared light. However, the installation position of the additional infrared auxiliary sensor can be changed according to the design specifications of the switchboard, such as the size of the switchboard.

If the speed is above

According to the Korea Traffic Safety Association data based on the Korean pedestrian record, it is 1.16m / sec when walking slowly and 1.31m / sec when walking quickly. This means that the speed detected by the auxiliary sensor is more than 1.16m / sec, but this may be changed depending on the usage environment where the switchboard is installed.

The additional infrared auxiliary sensor installed to measure the speed of the object may be the same as the first transmission and reception light emitting rods (410A, 410B) and the first transmission and reception light emitting rods (410A, 410B), the first transmission and reception light emitting network auxiliary sensor The measurement of the passing speed in the case where any object passes between them is such as measuring the speed of the object passing between the light emitting elements as shown in a known technique used for measuring the speed of a moving object. Since a known technique is used, a detailed description thereof will be omitted.

On the other hand, the infrared light emitting network of the switchgear for the convenience of the description of the description, but limited to the switchgear of a specific structure, but the present invention is not limited to this, the formal switchgear having a power capacity of 1000kVA or more and less than 1000kVA within the creative range of those skilled in the art It is special power switchboard for both informal switchgear with power capacity. LBS half MOF. Applicable to the PT half and TR half, as shown in FIG. 2, the high pressure space 210 and the low pressure breaker 230 are adjacent to each other in the width direction of the switchgear, as well as the high pressure space 210 and the low pressure shutoff. Both parts 230 may be applied to a structure in which the switchboard is disposed in the longitudinal direction.

10: high platen 20: low platen
100: enclosure 110: door
210: high pressure space portion 220: terminal portion
230: low pressure cutoff
410A, 410B: first transmitting and receiving light emitting rod
420A and 420B: second transmit / receive light emitting rod
430: alarm control unit

Claims (4)

In a switchgear panel having a hollow rectangular shape and a plurality of frames in which the devices are fixed therein are installed vertically and horizontally, when a human body and an object come into contact with the switchboard charging unit, a plurality of transmission / reception infrared sensors interact. Infrared light emitting network formed to detect this, and generates an alarm differentially according to the entry distance, and cut off the internal power of the switchboard when the danger distance of electric shock is close,
Installing a first transmitting light emitting rod for emitting infrared light inside the switchboard and a first receiving light emitting rod for detecting the infrared light emitted from the first transmitting light emitting rod at a distance spaced from the doors on both sides, Forming an infrared light emitting net,
A second transmitting light emitting rod for emitting infrared light at a distance separated by a predetermined interval from the first infrared light emitting network, and a second receiving light emitting rod for detecting infrared light emitted from the second transmitting light emitting rod To form a second infrared light emitting network,
When an object is detected by the infrared light emitting network formed by the first transmitting light emitting rod and the first receiving light emitting rod, an alarm is sounded and the second transmitting light emitting rod and the second receiving light emitting rod are formed. When the entrance of the object is detected by the infrared light emitting network, at the same time the alarm and cut off the power applied to the load and the switchgear,
And an infrared auxiliary sensor for detecting a speed of an object entering the switchboard between the doors on both sides and the first transmitting and receiving light emitting rod and between the first transmitting and receiving light emitting rod and the second transmitting and receiving light emitting rod. Switchgear equipped with an infrared light emitting network.
delete delete The method of claim 1,
The power is applied to the load and the switchboard at the same time an alarm is sounded before the object reaches the infrared network formed by the second transmission / reception light emitting rod when the entry of an object of a predetermined speed or more is detected by the infrared auxiliary sensor. Switchgear equipped with an infrared light emitting network, characterized in that to block.

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