KR101715260B1 - Switchgear Fire Detection Devices - Google Patents

Abstract

According to the present invention, disclosed is a power distribution board fire detection apparatus. The power distribution board fire detection apparatus includes a bus bar unit and a temperature detection unit. The bus bar unit comprises: electric facilities which distribute supplied electricity to each load; a main bus bar having electrical connection with the electric facilities; a plurality of sub bus bars coupled the main bus bar; a plurality of bus bar coupling parts coupling cross contact points of the main bus bar and the sub bus bars; and a conductive connection part having the main bus bar and the sub bus bars connected to the electric facilities. The temperature detection unit detects temperature information of at least one of the bus bar coupling parts and the conductive connection part in a non-contact manner.

Description

{Switchgear Fire Detection Devices}

The present invention relates to an apparatus for detecting a fire in a switchboard, and more particularly, to a system for detecting a fire in an ASSEMBLY, more particularly, To a monitoring device.

Generally, a switchboard is installed in a unit of a building or an apartment or a hotel or a factory, and supplies electric power to each office or home.

Such a switchboard interrupts the supply and shutdown of main power to a number of power stations. Therefore, there is a risk of fire due to a short circuit due to contact failure.

Specifically, such an electrical flaw is caused by the deterioration of the insulation between contacts or wires over time, resulting in a partial and intermittent conduction state between the two wires. As a result, There is a problem that is occurring.

Therefore, a method for solving such problems is required.

SUMMARY OF THE INVENTION The present invention has been conceived in order to solve the above problems of the prior art, and it is an object of the present invention to provide a temperature sensing unit for sensing temperature information of a plurality of bus bar coupling portions in a non- When the control unit senses the sensing time for sensing the bus bar coupling portion and senses the temperature and the temperature information of the bus bar coupling portion sensed by the temperature sensing unit rises above a predetermined set temperature, It is an object of the present invention to prevent the occurrence of fire by redistributing the detection time of the bar coupling part to a relatively longer time than the detection time of the remaining bus bar coupling part.

The problems of the present invention are not limited to the above-mentioned problems, and other problems not mentioned can be clearly understood by those skilled in the art from the following description.

In order to accomplish the above object, according to the present invention, there is provided an apparatus for monitoring a switchboard fire, comprising: an electrical equipment for distributing electricity supplied to each load; a main bus bar having an electrical connection with the electrical equipment; A bus bar unit including a main bus bar and a bus bar bar; a plurality of bus bar coupling parts for connecting the main bus bar and the auxiliary part bar to each other, and a current connection part for connecting the main bus bar and the auxiliary bus bar to the electric equipment, Or temperature information of at least one of the energizing connection portions.

Also, the temperature sensing unit may continuously circulate the connection portion or the bus bar coupling portion and sense the respective temperature information.

At least one of the plurality of temperature information for the bus bar coupling portion sensed by the temperature sensing unit may have a relatively higher temperature than a predetermined set temperature or may have a temperature increase rate relatively higher than a predetermined set increase rate , The temperature sensing unit may control the temperature sensing unit to sense temperature information for a relatively longer time than the rest of the bus bar coupling unit.

The control unit may distribute the preset circulation time equally to the number corresponding to the number of the bus bar coupling parts, and the temperature sensing unit may independently sense one of the bus bar coupling parts for each time.

The booster bar coupling unit may include a first hazardous member detected by the temperature sensing unit at a temperature higher than the set temperature and a first safety member sensed below the preset temperature, The control unit may control the temperature sensing unit to sense the sensing time for the first dangerous member relatively longer than the sensing time for the first safety member.

And the control unit may redistribute the detection time for the first dangerous member within the circulation time for a relatively longer time than the detection time for the first safety member.

In addition, the control unit may extend the sensing time of the first dangerous member by extending the circulation time while maintaining the sensing time of the first safety member.

The control unit may maintain the sensing time of the first safety member evenly during the circulation time.

The boom bar coupling unit may include a second safety member that senses a temperature increase rate of the bus bar engagement portion sensed by the temperature sensing unit to be greater than or equal to the set increase rate and a second safety member that is sensed below the set increase rate, The control unit may control the temperature sensing unit to sense the sensing time of the second dangerous member relatively longer than the sensing time of the second safety member.

And the control unit may redistribute the detection time of the second dangerous member within the circulation time for a relatively longer time than the detection time of the second safety member.

In addition, the control unit may extend the sensing time of the second dangerous member by relatively extending the circulation time while maintaining the sensing time of the second safety member.

And, the control unit can keep the sensing time of the second safety member even during the circulation time.

And further comprising a shaft formed to correspond to the arrangement of the bus bar coupling portions, wherein the temperature sensing unit is arranged in a position along the longitudinal direction of the shaft and measures temperature information of the corresponding bus bar coupling portion at each position can do.

The temperature sensing unit is configured to be tilting, and the angle of the temperature sensing unit can be adjusted to detect the bus bar coupling portion corresponding to the position of the bus bar coupling portion.

Further comprising a determination unit for generating the risk information on the bus bar coupling unit through the temperature information and transmitting the generated risk information to the outside.

In order to solve the above-described problems, the present invention provides an apparatus for monitoring a fire fighting system of a switchgear.

First, the temperature sensing unit is formed in a non-contact manner, so that heat is generated in the bus bar coupling portion or the energizing connection portion, thereby preventing the temperature sensing unit from being inoperable and reducing commercial losses due to mechanical defects.

Second, a temperature sensing unit is provided to circulate the booster bar coupling units sequentially within a predetermined cycle time and to sense the temperature information of the booster bar coupling units.

Third, a control unit is provided so that the temperature sensing unit senses the sensing time of the bus bar coupling portion with respect to the bus bar coupling portion of the predetermined set temperature or more within the circulation time, It is advantageous in that it can be distributed relatively longer.

Fourth, additional time is added to the circulation time to allow the temperature sensing unit to allocate additional time to the sensing time of the bus bar coupling portion with respect to the bus bar coupling portion of the predetermined set temperature or more, It is advantageous in that it can be distributed relatively longer than the detection time.

Fifth, the determination unit is provided to divide at least a preset temperature into a plurality of areas, to distribute the sensing time longer, to generate danger information for the bus bar coupling unit, and to deliver the information to the outside.

The effects of the present invention are not limited to the effects mentioned above, and other effects not mentioned can be clearly understood by those skilled in the art from the description of the claims.

1 is a view showing a state of a switchboard in a switchboard fire monitoring apparatus according to an embodiment of the present invention;
2 is a diagram illustrating an operation of a temperature sensing unit in a switchboard fire monitoring apparatus according to an embodiment of the present invention;
3 is a diagram illustrating operation of a temperature sensing unit by a control unit in a switchboard fire monitoring apparatus according to an embodiment of the present invention;
FIG. 4 is a graph showing a first dangerous member A1 and a first safety member B1 according to temperature in a switchboard fire monitoring apparatus according to an embodiment of the present invention; FIG.
FIG. 5 is a graph showing a second dangerous member A2 and a second safety member B2 according to the temperature increase rate in the switchboard fire monitoring apparatus according to an embodiment of the present invention; FIG.
6 (a) and 6 (b) are diagrams showing distribution of sensing time according to the first and second safety members in the control and monitoring system of a switchboard according to an embodiment of the present invention;
FIGS. 7A and 7B are diagrams for explaining the distribution of the detection time of the first dangerous member according to the expansion of the circulation time in the switchboard fire monitoring apparatus according to the embodiment of the present invention; FIG.
FIG. 8 is a flowchart showing a series of operations in a switchboard fire monitoring apparatus according to an embodiment of the present invention; FIG.
9 is a view showing a state in which the temperature sensing unit is adjusted in an angle corresponding to the position of the bus bar coupling portion in the apparatus for monitoring a switchboard fire according to an embodiment of the present invention.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, preferred embodiments of the present invention will be described with reference to the accompanying drawings. In describing the present embodiment, the same designations and the same reference numerals are used for the same components, and further description thereof will be omitted.

Further, in describing the embodiments of the present invention, the configuration shown in the drawings is only an example for facilitating understanding of the detailed description, and the configuration thereof may be various without limitation, thereby indicating that the scope of the right is not limited .

First, the switchboard is installed in a unit of a building or an apartment or a hotel or a factory, and a power is supplied to a power supply unit such as an office or a home.

Therefore, the present invention is disclosed to prevent the above-mentioned reasons.

1 and 2, a general configuration of a watt-hour temperature monitoring apparatus according to an embodiment of the present invention will be described.

FIG. 1 is a view showing a state of a switchboard in a switchboard temperature monitoring apparatus according to an embodiment of the present invention, and FIG. 2 is a diagram illustrating an operation of a temperature sensing unit 400 according to an embodiment of the present invention.

As shown in FIGS. 1 and 2, the switchboard temperature monitoring apparatus includes a housing 100, a power distribution apparatus 200, a bus bar unit 300, a temperature sensing unit 400, and a control unit (not shown) . ≪ / RTI >

A housing space is formed in the housing 100, and a plurality of the electric power distributing apparatuses 200 for controlling power supply are provided in the housing space.

The electrical equipment 100 may distribute the supplied electricity to each load or intermittently supply electric power, and may be formed of a plurality of electric devices.

In addition, the power distribution apparatus 200 may include one main electrical apparatus 220 and a plurality of auxiliary electrical apparatuses 240 as shown in FIG.

The auxiliary electrical equipment 240 is formed in the accommodation space in a direction orthogonal to the main electrical equipment 220 and is connected to the main electrical equipment 220 through the bus bar unit 300 having an electrical coupling And is electrically connected to the main electrical equipment (220).

Here, the electric equipment 200 may be formed as a circuit breaker according to the embodiment, and may be configured to supply or cut off the supplied power to the respective auxiliary electric equipment 240.

The bus bar unit 300 includes a main bus bar 320 electrically connected to the main electrical equipment 220, a plurality of auxiliary unit bars 340 coupled to the main bus bar 320, And a plurality of bus bar coupling portions 360 for coupling the intersections of the main booth and the auxiliary section bar 340.

Further, the electrical equipment 200 for distributing the supplied electricity to each load can be coupled with the bus bar unit 300 by forming an output unit.

Therefore, a portion where the electrical equipment 200 and the bus bar unit 300 are coupled is referred to as an energizing connection portion.

At least one main bus bar 320 is formed to extend downward from an output portion of the main electrical equipment 220. The auxiliary bus bar 340 is electrically connected to the main bus bar 320 electrically, And an end thereof is connected to the output of the auxiliary electrical equipment 240.

A plurality of auxiliary shelves 340 are electrically connected to one main bus bar 320 and each auxiliary shelf 340 is coupled to the plurality of auxiliary electrical installations 240 The main bus bar 320 and the auxiliary section bar 340 are coupled to each other at the intersections of the main bus bar 320 and the auxiliary section bar 340 by the bus bar coupling part 360.

Accordingly, a plurality of auxiliary section bars 340 are aligned and coupled to the plurality of main bus bars 320, respectively.

The description will be made with reference to the drawings.

A main bus bar 320 is formed on the upper portion of the housing 100. The main bus bar 320 is formed in a direction orthogonal to the left side of the main bus bar 320 and is provided with a first auxiliary electric device 240, It is referred to as a facility 240. The third auxiliary electric equipment 240 is formed in the right direction orthogonally to the right and the fourth auxiliary electric equipment 240 is disposed in the lower portion.

Four main bus bars 320 are connected to the output unit and are extended downward in the main electric equipment 220. In the figure, the first main bus bar 320, the second main bus bar 320, the third main bus bar 320, Main bus bar, and fourth main bus bar.

The first main busbar 320 is connected to the auxiliary portion scuba 340 connecting the first auxiliary electrical equipment and the third auxiliary electrical equipment 240 by the bus bar coupling portion 360, And the auxiliary part scuba 340 connecting the third auxiliary electric equipment and the fourth auxiliary electric equipment are connected.

Thus, the main bus bar 320 and the auxiliary section bar 340 are connected to each other with an electrical coupling relationship.

Accordingly, the temperature sensing unit 400 sequentially circulates the plurality of the bus bar coupling units 360 or the plurality of the power supply connection units 380 one by one and detects the temperature information of the bus bar coupling units 360 have.

At this time, the temperature sensing unit 400 senses temperature information of at least one of the bus bar coupling unit 360 and the current connection unit 380 in a non-contact manner.

More specifically, the temperature sensing unit 400 is configured to circulate the bus bar coupling unit 360 or the energizing connection unit 380. The temperature sensing unit 400 uniformly distributes the sensing times within the circulation time, Can be detected.

In this way, it is determined whether the temperature information of the booth coupling portion 360 and the energizing connection portion 380 has temperature information within a predetermined normal temperature range, and is determined by a determination unit, which will be described later, .

The reason why the temperature sensing unit 400 is formed in a non-contact manner is that when a temperature is sensed in a conventional manner, a sensor (not shown) for sensing the temperature and a sensor (not shown) 380) is caused by fire due to resistance or the like.

Therefore, in one embodiment of the present invention, the temperature sensing unit 400 is formed to be in a non-contact manner to sense the temperature by being spaced apart from the bus bar coupling part 360 or the energizing connection part 380 by a certain distance.

The temperature information of the bus bar coupling part 360 may be information indicating the temperature of the bus bar coupling part 360 in numerical values or may be a rate of increase in temperature with time.

Meanwhile, the housing 100 may be provided inside the temperature sensing unit 400 to sense the bus bar coupling unit 360 or the current connection unit 380, so that the bus bar coupling unit 360, The temperature sensing unit (400) further includes a shaft (120) formed to be long in correspondence with the arrangement of the connecting portion (380), the temperature sensing unit (400) being positionally adjusted along the longitudinal direction of the shaft The temperature information of the bar joining portion 360 can be measured.

The temperature sensing unit 400 senses temperature information of the bus bar coupling part 360 and the energizing connection part 380 so as to face the bus bar coupling part 360 and the current connection part 380, Is formed on the shaft 120 so as to be vertically raised and lowered corresponding to the positions of the bus bar coupling portion 360 and the energizing connection portion 380 and the energizing connection portion 380, And is installed so as to be able to move up and down and rotate so as to circulate the bus bar engaging portion 360 and the energizing connecting portion 380.

Accordingly, the temperature sensing unit 400 is raised and lowered to sense the temperature information of the bus bar coupling unit 360 or the current connection unit 380 on the shaft 120, and the booster bar coupling unit 360 or The bus bar coupling part 360 or the energizing connection part 380 can be sensed for a predetermined time while sensing the energizing connection part 380.

In the following description, the temperature sensing unit 400 senses the temperature of the bus bar coupling unit 360, and thus the power connection unit 380 is not excluded from the right range. do.

A more detailed description will be given with reference to the drawings.

2, the temperature sensing unit 400 may move up and down on the shaft 120 and may move in correspondence with the number of the bus bar coupling portions 360, And may be rotated at a predetermined angle along the circumference of the shaft 120 in a direction in which the auxiliary section bar 340 is formed so as to sense the bus bar coupling sections 360 formed on the respective ones.

Here, the temperature sensing unit 400 may be controlled by the control unit so that the temperature sensing unit 400 can stay for a predetermined time according to the position of the bus bar coupling unit 360.

In addition, the temperature sensing unit 400 may be formed as a thermal infrared camera so as to be able to sense a temperature by a certain distance as shown in the figure in order to sense the temperature of the bus bar coupling portion 360.

Therefore, the temperature sensing unit 400 capable of ascending and descending and rotating on the shaft 120 can sense the temperature of the booster bar coupling part 360 from the booster bar coupling part 360, The temperature of the bus bar unit 300 as well as the bus bar coupling unit 360 can be sensed.

Specifically, the temperature sensing unit 400 senses the circulation of the bus bar coupling unit 360, and the temperature sensing unit 400 may sense one of the bus bar coupling units 360 during a stay time And a plurality of booths may sense the coupling unit 360.

This allows the temperature sensing unit 400 to sense a plurality of the bus bar coupling portions 360 during a single sensing time, thereby effectively utilizing the sensing time.

In the present embodiment, the temperature sensing unit 400 is a thermal infrared camera. However, the thermal sensing unit 400 is not limited to the thermal infrared camera as long as it can sense the temperature in a noncontact manner corresponding to the position of the bus bar coupling unit 360 , And can be easily changed by those skilled in the art.

Next, the control unit will be described in detail with reference to FIGS. 3 to 7. FIG.

The control unit may be configured such that at least one of temperature information of the bus bar coupling unit 360 sensed by the temperature sensing unit 400 has a relatively higher temperature than a predetermined set temperature T, When the temperature sensing unit 400 senses the temperature of the booster bar coupling part 360 for a relatively longer time than the rest of the temperature of the booster bar coupling part 360, Information can be detected.

In addition, the control unit may equally distribute the predetermined circulation time C to the number corresponding to the number of the bus bar couplers 360, The bus bar coupling portion 360 can be sensed.

Accordingly, the temperature sensing unit 400 distributes the circulation time C equally to the number of the bus bar coupling units 360 by the control unit, and the plurality of the bus bar coupling units 360, And can sense the temperature information of the bus bar coupling portion 360. FIG.

A more detailed description will be given with reference to the drawings.

3 is a diagram illustrating operation of the temperature sensing unit 400 by the control unit in the switchboard temperature monitoring apparatus according to the embodiment of the present invention.

The temperature sensing unit 400 senses the temperature of the bus bar coupling portion 360 on the shaft 120 as shown in FIG.

The time can be divided by the number of the bus bar coupling portions 360 at the circulation time C during which the temperature sensing unit 400 circulates throughout the bus bar coupling portion 360, And the temperature sensing unit 400 may stay in the bus bar coupling part 360. [

The temperature sensing unit 400 independently monitors the temperatures of the plurality of the bus bar coupling units 360 and the temperature of the bus bar coupling unit 360, which is raised above the set temperature T, Thereby detecting the temperature information of the display unit 360.

Specifically, the temperature sensing unit 400 ascends and descends on the shaft 120 and senses temperature information of the bus bar coupling unit 360, and the control unit determines whether the temperature sensing unit 400 senses temperature information of the booth bar coupling unit 360, It is possible to distribute the staying time in the engaging portion 360. [

The temperature sensing unit 400 divides the time for circulating the booster bar coupling unit 360 once by the number of the booster bar coupling units 360 so that the temperature sensing unit 400 can rotate the booster bar coupling unit 360 ) Can be distributed equally to each other.

The boiler bar coupling part 360 may include a first hazardous material A1 and a second hazardous material A1 that are sensed at a temperature equal to or higher than the set temperature T detected by the temperature sensing unit 400, And a first safety member B1 sensed below the set temperature T.

The control unit may control the temperature sensing unit 400 to sense the sensing time of the first dangerous member A1 relatively longer than the sensing time of the first safety member B1.

The first dangerous member A1 and the first safety member B1 will be described in detail with reference to the drawings.

The first dangerous member (A1) and the first safety member (B1) are determined based on the set temperature (T).

FIG. 4 is a graph showing a first dangerous member A1 and a first safety member B1 according to temperature in a watt-hour temperature monitoring apparatus according to an embodiment of the present invention.

As shown in the figure, the graph represents a temperature increase with time, and the booth bar joining unit 360 whose temperature has risen above the set temperature T, based on the set temperature T, Member A1 and the booster bar coupling portion 360 having a temperature not higher than the set temperature T are denoted by the first safety member B1.

Specifically, the control unit can redistribute the circulation time C according to the temperature of the boom bar coupling portion 360, and thereby, the first dangerous member A1 above the set temperature T Can be distributed relatively longer than the first safety member (B1) within the circulation time (C).

In FIG. 4, the first dangerous member A1 and the first safety member B1 are shown as typical curves for distinguishing between the set temperature T and the following, The first safety member B1 becomes the first dangerous member A1 if it has a temperature equal to or higher than the set temperature T and the first safety member B1 has a temperature equal to or lower than the preset temperature T, .

The temperature sensing unit 400 may redistribute the circulation time C according to the temperature increase rate of the bus bar coupling unit 360.

Subsequently, the bus bar coupling portion 360 according to the temperature increase rate will be described.

FIG. 5 is a graph showing a second dangerous member A2 and a second safety member B2 according to a temperature increase rate in the apparatus for detecting a temperature of a switchboard according to an embodiment of the present invention.

As shown in the graph, the graph shows that the bus bar coupling portion 360 having a temperature increase rate that is smaller than the set increase rate R about a predetermined set increase rate R is set to a second safety Member B2 and the bus bar coupling portion 360 having a temperature increase rate larger than the set increase rate R are denoted by a second hazardous member A2.

Wherein the temperature sensing unit (400) senses the booster bar coupling part (360) with the set increase rate (R), and the second dangerous part (A2) having a temperature increase rate larger than the set increase rate And relatively longer than the second safety member (B2) within the time (C).

In FIG. 5, the second dangerous member A2 and the second safety member B2 are shown as representative curves for distinguishing between the set increase rate R and the following, The second safety member B2 becomes the second dangerous member A2 if the second safety member B2 has a temperature higher than the set increase rate R and the second safety member B2 has a temperature lower than the set increase rate R .

Subsequently, the redistribution of the circulation time C according to the temperature information of the bus bar coupling part 360 will be described in more detail.

6A and 6B are diagrams showing distribution of sensing time according to the first and second safety members A1 and B1 in the switchboard temperature monitoring apparatus according to an embodiment of the present invention.

The circulation time C distributed to the first and second safety members A1 and B1 is equal to each other, as shown in FIG. 6 (a).

This is because the bus bar coupling portion 360 is maintained at the set temperature T or less.

The control unit may control the temperature sensing unit 400 to circulate by evenly distributing the circulation time C in which the temperature sensing unit 400 circulates the plurality of the engagement cycles.

Accordingly, the temperature sensing unit 400 can sense the sensing times of the plurality of the bus bar coupling units 360 at the same time.

However, if the boiler bar coupling portion 360 is regarded as the first dangerous member A1 whose temperature rises above the set temperature T, the control unit can redistribute the circulation time C.

Specifically, the control unit distributes the sensing time for the first dangerous member A1 longer than the first safety member B1, and for the first safety member B1, The remaining time except the time can be evenly distributed.

The drawings are referred to in more detail.

FIG. 6B is a diagram showing the distribution of the circulation time C when the control unit detects the first dangerous member A1.

The control unit can redistribute the sensing time of the first dangerous member A1 relatively longer than the sensing time of the first safety member B1 within the circulation time C. [

As shown in the figure, half of the circulation time C is distributed to the first dangerous member A1, and a plurality of the first safety members B1 are equally divided with respect to the remaining half of the circulation time C, .

Therefore, the control unit may change the circulation time C for the first dangerous member A1, which is the bus bar coupling portion 360, which is greater than or equal to the preset temperature T through the temperature sensing unit 400, It is possible to distribute the first safety member B1 so as to detect more time than the first safety member B1 and to distribute the first safety member B1 to the first dangerous member A1 and to distribute the same evenly for the remaining time.

In addition, even if the number of the first dangerous members (A1) exceeding the set temperature (T) is plural, the control unit sets the detection time for the first dangerous member (A1) It can be redistributed to be larger than the safety member B1 so that it can be sensed.

And the circulation time C can be redistributed with respect to the temperature increase rate.

The control unit can redistribute the sensing time of the second dangerous member A2 relatively longer than the sensing time of the second safety member B2 within the circulation time C. [

As shown in the figure, half of the circulation time C is distributed to the second dangerous member A2, and a plurality of the second safety members B2 are equally divided with respect to the remaining half of the circulation time C, .

Therefore, the second dangerous member A2, which is the busbar engaging portion 360 having the set increase rate R or more, through the temperature sensing unit 400, the control unit may vary the circulation time C, The second safety member B2 may be distributed to the second dangerous member A2 and the second safety member B2 may be distributed evenly for the remaining time.

In addition, even if the number of the second dangerous members (A2) larger than the set increase rate (R) is plural, the control unit can set the detection time for the second dangerous member (A2) It can be redistributed to be larger than the safety member B2 so that it can be sensed.

In this way, the detection time for the bus bar coupling portion 360 can be adjusted within the circulation time C, and the booster bar coupling portion 360 over the set temperature T can be intensively monitored Thus, the risk of fire can be prevented.

6 (b), the circulation time C distributed to the first and second safety members A1 and B1 is greater than the circulation time C to the first dangerous member A1, And the remaining half of the time is distributed equally to a plurality of the first safety members B1, but this is only an embodiment, and the control unit is arranged to divide the first danger member A1 and the first safety member B1, The circulation time C to be distributed to the member B1 can be easily changed by those skilled in the art, and thus the scope of the right is not limited.

Meanwhile, the circulation time C may be extended in distributing the circulation time C for the first dangerous member A1 and the first safety member B1.

Next, the circulation time (C) is expanded and distributed through FIGS. 7 (a) and 7 (b).

7 (a) and 7 (b) illustrate that the detection time of the first dangerous component A1 is extended and distributed according to the expansion of the circulation time C in the watt-hour temperature monitoring apparatus according to the embodiment of the present invention FIG.

As shown in the figure, when the circulation time C for the first dangerous member A1 and the first safety member B1 is distributed, an additional time E is added to the circulation time C, It can be confirmed that the whole time (C) is expanded.

Accordingly, the control unit can extend the sensing time of the first dangerous member A1 relatively long by extending the circulation time C while maintaining the sensing time of the first safety member B1 .

More specifically, the control unit controls the temperature sensing unit 400 to sense the sensing time of the first dangerous member A1 when the temperature sensing unit 400 senses the bus bar coupling 360, To control for longer sensing, an additional time (E) is added to the cycle time (C).

Here, the additional time E is added only to the sensing time of the first dangerous member A1, and is not applied to the first safety member B1.

Therefore, the sensing time of the first dangerous member A1 is extended and the sensing time of the first safety member B1 is maintained.

In addition, during the circulation time C, the rest of the time except for the detection time of the first dangerous member A1 is equally distributed to the plurality of first safety members B1.

Even if the number of the first dangerous members A1 equal to or greater than the set temperature T is plural, the control unit can equally distribute the plurality of first dangerous members A1 at the additional time E So that the detection time of the first dangerous member A1 can be redistributed to be relatively larger than the detection time of the first safety member B1.

7, the number of the first dangerous member A1 and the number of the first safety member B1 are limited to one and three, respectively. However, the present invention is not limited to the number shown in the drawings, And may be variously shown according to a plurality of bus bar coupling portions 360 as shown in FIG.

Meanwhile, the control unit may control the temperature sensing unit 400 according to the temperature increase rate as well as the temperature information of the bus bar coupling unit 360.

The temperature sensing unit 400 senses that the temperature of the bus bar coupling portion 360 rises rapidly and recognizes that the temperature increase rate is dangerous when the temperature increase rate is higher than a certain level.

More specifically, the temperature sensing unit 400 circulates a plurality of the bus bar coupling units 360 within the circulation time C and senses a change in the temperature of the temperature sensing unit 400, The circulation time C can be redistributed when the temperature is suddenly increased during the time of sensing the part 360 or when it is detected as the set increase rate R or more.

The booster bar coupling unit 360 may be configured such that the temperature increase rate of the bus bar coupling unit 360 sensed by the temperature sensing unit 400 is greater than the second riser member A2 ), And classified into the second safety member B2 sensed as the set increase rate R or less.

As shown in the figure, the temperature increase rate of the bus bar coupling unit 360 sensed by the temperature sensing unit 400 is compared with the set increase rate R to determine the booster bar coupling unit 360 as the second Is classified into the dangerous member (A2) or the second safety member (B2).

The control unit may control the temperature sensing unit 400 to sense the sensing time of the second dangerous member A2 relatively longer than the sensing time of the first safety member B2.

Therefore, the control unit can redistribute the sensing time of the second dangerous member A2 longer than the sensing time of the second safety member B2.

Here, the sensing time of the second danger member (A2) can be extended relatively by extending the circulation time (C) while maintaining the sensing time of the second safety member (B2).

Also, the sensing time of the second safety member B2 during the circulation time C can be maintained evenly.

The apparatus for monitoring a temperature of the busbar according to an embodiment of the present invention includes a determination module for generating the risk information for the temperature sensing unit 400 through the temperature information of the bus bar coupling unit 360 and for transmitting the information to the outside .

Wherein when the circulation time C is redistributed by the control unit to cause the temperature sensing unit 400 to circulate and is greater than or equal to the set temperature T and the set increase rate R, (C), and the boiler bar coupling unit 360 is intensively monitored through the temperature sensing unit 400. The fire risk is determined through the determination module to generate dangerous information to the outside, The power can be cut off through the power supply 200.

Here, the risk information according to the risk can be generated by dividing the set temperature T or more into a plurality of pieces (S06).

For example, when the first dangerous member (A1) enters the second temperature by dividing the set temperature (T) or more by the first temperature and the second temperature, the danger information is generated and automatically The electric power can be interrupted through the electric equipment 200.

The temperature increase rate may also be determined by dividing the set increase rate R by a first set increase rate R and a second set increase rate R so that the second dangerous member A2 is equal to or greater than the second set increase rate R , The risk information may be generated and the power source may be interrupted.

Next, the overall operation and control will be described in the flowchart.

FIG. 8 is a flowchart illustrating a series of operations in a watt-hour temperature monitoring apparatus according to an embodiment of the present invention.

The temperature sensing unit 400 operates to circulate the bus bar coupling unit 360 repeatedly (S01).

At this time, the control unit equally distributes the predetermined circulation time C corresponding to the number of the bus bar coupling units 360 (S02).

The temperature sensing unit 400 circulates through the bus bar coupling unit 360 through the distributed time and senses the temperature (S03).

The control unit may simultaneously determine whether the temperature of the bus bar coupling portion 360 is equal to or higher than the set temperature T or the temperature increase rate is equal to or greater than the set increase rate R. [

(S04) whether the boiler bar engaging portion 360 is not less than the set temperature T or the set increasing rate R or not.

At this time, if the booster bar coupling unit 360 is sensed above the set temperature T or above the set increase rate R, the control unit redistributes the sensing time for the booster bar coupling unit 360 S05).

The temperature sensing unit 400 can continuously circulate the booth bar coupling unit 360 with the detection time of the redistributed booth bar coupling unit 360. When the danger information is detected by the determination module The risk information may be generated (S06).

Here, in the method of redistributing the boiler bar coupling portion 360, the booster bar coupling portion 360 having the set temperature T or more is referred to as a first dangerous portion A1, The bus bar coupling portion 360 of the set increase rate R or more is referred to as the first safety member B1 and the second dangerous portion A2 is formed in the bus bar coupling portion 360 The detection time of the first dangerous member A1 and the second dangerous member A2 is set to the first safety member B2 within the circulation time C, B1 and the first safety member B2.

The additional time (E) may be added to the circulation time (C) to add the additional time (E) to the sensing time of the first and second dangerous members (A1, A2) Can be distributed longer than the member (B1) and the first safety member (B2).

If the temperature detection unit 400 does not detect the boom bar coupling unit 360 at a temperature higher than the set temperature T to the set increase rate R, (360). ≪ / RTI >

Meanwhile, the temperature sensing unit 400 may be hinged on the shaft 120, and the angle may be adjusted corresponding to the position of the bus bar coupling portion 360.

9 is a view illustrating a temperature sensing unit 400 hinged on a shaft 120 to sense temperature information of the bus bar coupling unit 360 in a switchboard temperature monitoring apparatus according to an embodiment of the present invention. to be.

The temperature sensing unit 400 is configured to be capable of tilting in the housing 100. The temperature sensing unit 400 may be tilted within the housing 100 to detect the angle of the bus bar coupling portion 360 in accordance with the position of the bus bar coupling portion 360 .

Since the temperature sensing unit 400 is formed in a non-contact manner and spaced apart from the bus bar coupling portion 360, the temperature sensing unit 400 is hinged to a part of the shaft 120 to measure the temperature of the bus bar coupling portion 360 The angle can be adjusted so that it can be done.

In the present embodiment, the temperature sensing unit 400 is formed as one unit and circulated. However, the number of the temperature sensing units 400 and the non-contact thermal infrared camera may be used to sense the bus bar coupling unit 360 It is needless to say that the form can be easily changed by a person skilled in the art and the scope of the right is not limited thereby.

In the control unit, when the temperature sensing unit (400) senses a temperature change of the bus bar coupling portion (360), the temperature of the booster bar coupling portion (360) When the temperature increase rate is equal to or higher than the set temperature T or the temperature increase rate is equal to or greater than the set increase rate R, the detection time of the boom bar coupling unit 360 is extended, .

Further, a separate temperature holding means may be further included in the receiving space to keep the room temperature inside the receiving space unchanged.

Here, the temperature holding means includes a temperature sensor and a humidity sensor, and may be a heater, a fan, or the like.

It will be apparent to those skilled in the art that the present invention can be embodied in other specific forms without departing from the spirit or scope of the invention as defined in the appended claims. It is obvious to them. Therefore, the above-described embodiments are to be considered as illustrative rather than restrictive, and the present invention is not limited to the above description, but may be modified within the scope of the appended claims and equivalents thereof.

100: housing 120: shaft
200: electrical equipment 220: main electrical equipment
240: auxiliary electric equipment 300: bus bar unit
320: main bus bar 340: auxiliary bus bar
360: bus bar coupling part 400: temperature sensing unit
C: Circulation time E: Additional time
T: Set temperature R: Set increase rate
A1: first danger member B1: first safety member
A2: second danger member B2: second safety member

Claims (15)

A main bus bar having an electrical connection with another electrical equipment, a plurality of auxiliary portion severs coupled to the main bus bar, a plurality of bus bar coupling portions for connecting the cross contacts of the main bus bar and the auxiliary portion bar, A bus bar unit including a main bus bar and an energizing connection part to which the auxiliary bus bar is connected; And
A temperature sensing unit that continuously circulates the bus bar coupling portion or the energizing connection portion to detect at least one or each temperature information in a noncontact manner; And
A control unit for controlling the temperature sensing unit to uniformly distribute and detect a circulation time for circulating the bus bar coupling portion; / RTI >
Wherein the control unit relatively distributes the sensing time of the corresponding bus bar coupling portion detected when the temperature of the plurality of bus bar coupling portions sensed by the temperature sensing unit is higher than a predetermined set temperature. The method according to claim 1,
The control unit includes:
Wherein a time for sensing the bus bar coupling portion at a temperature higher than the set temperature within the circulation time is relatively largely distributed and the remaining time is evenly distributed to the bus bar coupling portion at the set temperature or lower, . The method according to claim 1,
The control unit includes:
Wherein the control unit further controls the booth bar coupling unit to detect the boiler bar coupling unit more than the set temperature when the boiler bar coupling unit is detected. The method of claim 3,
The control unit includes:
Wherein the temperature sensing unit independently senses one of the bus bar coupling portions during each time period by equally dividing the predetermined circulation time by a number corresponding to the number of the bus bar coupling portions. 5. The method of claim 4,
Wherein the boom bar coupling portion comprises a first hazardous member in which the temperature of the bus bar coupling portion sensed by the temperature sensing unit is sensed at the set temperature or higher and a first safety member sensed below the set temperature,
Wherein the control unit controls the temperature sensing unit to sense a sensing time of the first dangerous member relatively longer than a sensing time of the first safety member. 6. The method of claim 5,
The control unit includes:
Wherein the sensing time of the first dangerous member is redistributed to be longer than the sensing time of the first safety member within the circulation time. 6. The method of claim 5,
The control unit includes:
Wherein the detection time of the first dangerous member is extended relatively long by extending the circulation time while maintaining the detection time of the first safety member. 6. The method of claim 5,
The control unit includes:
Wherein the control unit maintains the detection time of the first safety member evenly during the circulation time. 5. The method of claim 4,
Wherein the boom bar coupling portion comprises a second safety member whose temperature increase rate of the bus bar engagement portion sensed by the temperature sensing unit is sensed above the set increase rate and a second safety member sensed below the set increase rate,
Wherein the control unit controls the temperature sensing unit to sense the sensing time of the second dangerous member relatively longer than the sensing time of the second safety member. 10. The method of claim 9,
The control unit includes:
Wherein the detection time of the second dangerous member is longer than the detection time of the second safety member within the circulation time. 10. The method of claim 9,
The control unit includes:
Wherein the sensing time of the second safety member is extended while extending the circulation time while maintaining the sensing time of the second safety member. 10. The method of claim 9,
The control unit includes:
Wherein the control unit maintains the detection time of the second safety member evenly during the circulation time. The method according to claim 1,
Further comprising a shaft formed so as to correspond to the arrangement of the bus bar coupling portion,
Wherein the temperature sensing unit is positioned along the longitudinal direction of the shaft and measures temperature information of the corresponding bus bar coupling portion at each position. The method according to claim 1,
The temperature sensing unit includes:
Wherein the angle of the boom bar engaging portion is adjusted to correspond to the position of the boom bar engaging portion. The method according to claim 1,
Further comprising a determination unit for generating the risk information for the bus bar coupling unit through the temperature information and delivering the information to the outside.

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