KR102684142B1 - Electrical safety management system - Google Patents

Abstract

The electrical safety management system according to the present invention includes a distribution board that distributes indoor electrical wiring; At least two branches branching off from the distribution board; and an outlet provided in the branch to connect a load to the power line and the neutral line of the branch. In the indoor electricity supply system, if at least one of the branches is assumed to be a main branch and the remaining branches are assumed to be sub-grounds, , including a branch branch connected from the main branch to the remaining sub-branch, wherein the branch branch includes a first breaker provided in the branch branch to open and close the electrical connection of the branch branch; A first voltage measuring unit that measures the voltage before and after the first circuit breaker; and is provided at a connection point between the branch branch and the sub branch to electrically connect two terminals of the three terminals that are connection terminals to the branch branch and the front and rear terminals of the sub branch, and connects the sub branch to a plurality of terminals. It includes a switching module divided into unit circuits.

Description

Electrical safety management system}

The present invention relates to an electrical safety management system.

Recently, due to the increase in electricity consumption and the increase in the size, high-rise, and advanced technology of buildings in densely populated areas, the frequency of occurrence of power outages and electrical fires has increased and the damage has increased, increasing the need to prevent electrical accidents.

Typically, the main causes of electrical fires are short circuit, overcurrent, arc, and leakage current. In an ongoing effort to reduce the occurrence of electrical fires, distribution boards and distribution boards are equipped with individual equipment such as circuit breakers that can prevent fire accidents by cutting off the power supply when a short circuit, overcurrent, or electric leak occurs.

Recently, due to the explosive spread of digital loads, most of the capacitance between wires and ground has been changed to the capacitance (C) component of the noise filter, and the generation of harmonics has also increased. As a result, the capacitance between the ground and the line increased significantly compared to the past, and the capacitive leakage current (Igc) also increased. Therefore, in order to accurately detect resistive leakage current (Igr), it has become more important to compare the phases of voltage and current with a signal with minimal distortion.

In order to detect the resistive leakage current (Igr), conventionally, both the reduced voltage signal and the leakage current measured by the current sensor are processed into a square wave, and then the phases of the signals processed into the square wave are compared and based on the results. Thus, the phase difference between the reduced voltage signal and the leakage current was calculated. However, in order to process the voltage signal and leakage current into a square wave, a multi-step normalization process must be performed, which causes distortion of the signal, and the distorted signal has the disadvantage of making it difficult to accurately detect the resistive leakage current.

Meanwhile, since electrical safety information is managed for all branches of the distribution panel, there is a problem in that it is difficult to manage electrical safety information for each branch when multiple loads are connected to each branch. In addition, there is a problem in that it is difficult to determine the exact location of the line where an abnormality occurred, making it impossible to take prompt action.

The present invention provides an electrical safety management system that determines whether there is an abnormality in an electric line.

The electrical safety management system according to the present invention includes a distribution board that distributes indoor electrical wiring; At least two branches branching off from the distribution board; and an outlet provided in the branch to connect a load to the power line and the neutral line of the branch. In the indoor electricity supply system, if at least one of the branches is assumed to be a main branch and the remaining branches are assumed to be sub-grounds, , including a branch branch connected from the main branch to the remaining sub-branch, wherein the branch branch includes a first breaker provided in the branch branch to open and close the electrical connection of the branch branch; A first voltage measuring unit that measures the voltage before and after the first circuit breaker; and is provided at a connection point between the branch branch and the sub branch to electrically connect two terminals of the three terminals that are connection terminals to the branch branch and the front and rear terminals of the sub branch, and connects the sub branch to a plurality of terminals. It includes a switching module divided into unit circuits.

In addition, a first connection state in which the switching module connects the front terminal and the rear terminal of the branch branch, a second connection state in which the switching module connects the front terminal of the sub branch and the connection terminal of the branch branch, and a rear terminal of the sub branch. and the connection terminals of the branch branch are switched to a third connection state, and when the switching module detects a short circuit to the sub-ground in the first connection state, the switching module on the distribution board side is sequentially switched to the second connection state. After switching, if the voltage difference measured by the first voltage measuring unit is similar to the voltage according to the supplied power within a standard value, the front-end unit ground circuit is judged to be short-circuited and a plurality of switching modules are used as an isolation process to isolate the branch circuit. It may include a control unit that controls.

Additionally, in the isolation process, the control unit may control the switching module at the front end of the unit branch judged to be short-circuited to the second connection state and control the switching module at the rear end to the third connection state.

Additionally, the switching module may be provided as a complex rotary switch type.

Additionally, the switching module may be provided as a composite rotary switch having two fixed contacts that are alternately connected according to the rotation of the rotating shaft.

It may also include a load measurement unit that periodically measures the load of each branch and creates a database.

Additionally, if the total amount of load connected to a specific sub-circuit measured by the load measurement unit immediately before a short circuit is detected exceeds the standard value, the control unit may not perform the isolation process.

It is possible to determine whether there is an abnormality in the line for each branch of the distribution panel, and based on the location information of the outlet, it is possible to analyze electrical safety information such as overcurrent, leakage current, and arc for the abnormal line and take prompt action.

1 is a schematic circuit diagram showing an electrical safety management system according to an embodiment of the present invention.
2 to 5 are schematic circuit diagrams for explaining the operation method of the branch branch.

Hereinafter, embodiments of the present invention will be described with reference to the attached drawings. Unless otherwise specified or specified, terms indicating direction used in this description are based on the state shown in the drawings. Additionally, the same reference numerals refer to the same members throughout each embodiment. Meanwhile, the thickness or dimensions of each configuration shown in the drawings may be exaggerated for convenience of explanation, and this does not mean that the configuration should actually be composed of the ratio between the corresponding dimensions or configurations.

An electrical safety management system according to an embodiment will be described with reference to FIGS. 1 to 5 . 1 is a schematic circuit diagram showing an electrical safety management system according to an embodiment of the present invention. 2 to 5 are schematic circuit diagrams for explaining the operation method of the branch branch.

The distribution board 110 is a component for distributing indoor electrical wiring. The main line through which electricity flows is called the main line. In indoor wiring, it is installed where it branches off from the main line into each branch circuit or branch, and an overcurrent breaker for the branch circuit is installed and gathered in one place, called a distribution panel.

In this embodiment, the first branch (Br1) to the Nth branch (BrN) are assumed and described, and among them, the third branch (Br3M) is set as the main branch. At this time, except for the main jiro, the remaining jiro are called sub-jiro. A plurality of main channels may be provided.

Each branch may be equipped with an outlet 130 that connects a load to the power line and neutral line of the branch, and each outlet is equipped with electricity and power consumption devices to act as a load on each branch.

The branch management module 133 includes a first circuit breaker and a first voltage measurement unit. The first breaker is provided in the branch branch and opens and closes the electrical connection of the branch branch. The first voltage measuring unit measures the voltage at the front and rear ends or both ends of the first breaker.

Meanwhile, when describing a direction such as forward or backward based on a specific terminal, the direction closest to the main branch and distribution board is called 'front' and the opposite direction is called 'back'.

As shown in FIG. 2, the switching module 131 is provided at the connection point between the branch branch and the sub branch to electrically connect two of the three terminals that are the front and rear terminals of the sub branch and the connection terminal to the branch branch. and divide the sub-district into a plurality of unit branches. In other words, each branch branch among one branch is divided into multiple branches based on the connecting points, and each divided branch is called a unit branch.

Meanwhile, referring to FIGS. 2 to 4, the control state in which the switching module 131 connects the front terminal and the rear terminal of the branch branch is called a first connection state, as shown in FIG. 2. In addition, the control state connecting the front terminal of the sub branch and the connection terminal of the branch branch is called a second connection state, as shown in FIG. 3. In the drawing, the left side is the direction of the distribution board. In addition, the control state connecting the rear terminal of the sub branch and the connection terminal of the branch branch is called a third connection state, as shown in FIG. 4.

If a short circuit to the sub-circuit is detected in the switching module in the first connection state, the control unit (not shown) measures the voltage by the first voltage measurement unit while sequentially switching to the second connection state starting from the distribution board side switching module. do.

That is, when a specific switching module is switched to the second connection state and the voltage is measured by the first voltage measuring unit connected to the branch branch, the voltage between the unit branch to which the switching module is connected and the main branch is measured. Afterwards, the control state of the corresponding switching module is returned to the first connection state and the same process is performed for the next switching module. As a result of sequentially measuring the voltage in this way, if the voltage difference in a specific switching module is similar to the voltage according to the supplied power and within the standard value rather than a value close to 0, the front-end unit ground path is judged to be short-circuited. Afterwards, the control unit controls the plurality of switching modules as an isolation process to isolate the corresponding circuit.

The isolation process is performed under the control of the control unit as shown in FIG. 5. The control unit may control the switching module at the front end of the unit branch that is determined to be short-circuited to be in the second connection state and control the switching module at the rear end to be in the third connection state. In this case, power can still be supplied to the remaining unit circuits except for the unit circuit where the short circuit occurred, and the control status of each switching module can be databased so that it can be used when restoring the power supply system in the future.

The switching module may be provided as a complex rotary switch type. In the case of a general rotary switch type, there is one fixed contact point and can be connected to multiple rotating contact points, but in the case of the composite rotary switch according to this embodiment, it has two fixed contact points alternately connected according to the rotation of the rotating shaft. It can be provided with a rotary switch.

It may also include a load measurement unit 120 that periodically measures the load of each branch and creates a database. If the total amount of load connected to a specific sub-circuit measured by the load measurement unit 120 immediately before a short circuit is detected exceeds the standard value, the control unit may not perform the isolation process. Through this control, it is possible to prevent a load exceeding capacity from being connected to one branch.

Although the preferred embodiments of the present invention have been described above, the technical idea of the present invention is not limited to the above-described preferred embodiments, and may be implemented in various ways without departing from the technical spirit of the present invention as specified in the patent claims. there is.

110: Distribution board
120: Load measurement unit
130: outlet
DBr1: branch road

Claims (7)

Distribution board for distributing indoor electrical wiring;
At least two branches branching off from the distribution board; and
In an indoor electricity supply system including an outlet provided in the branch and connecting a load to the power line and neutral line of the branch,
Assuming at least one of the branches is a main branch and the remaining branches are sub-branchs, it includes a branch branch connected from the main branch to the remaining sub-branch,
The above branch route is,
a first breaker provided in the branch branch to open and close an electrical connection to the branch branch;
A first voltage measuring unit that measures the voltage before and after the first circuit breaker; and
It is provided at a connection point between the branch branch and the sub branch to electrically connect the front and rear terminals of the sub branch and two of the three terminals that are connection terminals to the branch branch, and connects the sub branch to a plurality of units. It includes a switching module divided by branch,
A first connection state in which the switching module connects the front terminal and the rear terminal of the branch branch, a second connection state in which the switching module connects the front terminal of the sub branch and the connection terminal of the branch branch, and a rear terminal of the sub branch and Switched to a third connection state connecting the connection terminals of the branch branch,
If a short circuit to the sub-ground is detected in the switching module in the first connection state, the switch is sequentially switched to the second connection state starting from the switchboard side switching module, and then the voltage difference measured by the first voltage measuring unit is changed according to the supplied power. An electrical safety management system comprising a control unit that controls a plurality of switching modules as an isolation process to determine that a front-end unit circuit is short-circuited and isolate the circuit if the voltage is similar within the reference value. delete According to paragraph 1,
In the isolation process, the control unit controls the switching module at the front of the unit branch judged to be short-circuited to the second connection state and controls the switching module at the rear to the third connection state. According to paragraph 1,
The switching module is an electrical safety management system provided as a complex rotary switch type. According to clause 4,
The switching module is an electrical safety management system equipped with a complex rotary switch having two fixed contacts that are alternately connected according to the rotation of the rotating shaft. According to paragraph 1,
An electrical safety management system including a load measurement unit that periodically measures the load of each branch and creates a database. According to clause 6,
An electrical safety management system in which the control unit does not perform the isolation process when the total amount of load connected to a specific sub-circuit measured by the load measurement unit immediately before a short circuit is detected exceeds the standard value.