KR20220043603A - Circuit breaker manufacturing system and control method the same - Google Patents

Abstract

Disclosed are a system for manufacturing a circuit breaker for wiring and a control method thereof. The system for manufacturing a circuit breaker for wiring according to an embodiment of the present invention includes a simulation unit, a manufacturing unit, and a database unit. The simulation unit uses the positions before and after a bimetal is bent, to obtain interval information, in advance, which is information about the optimal distance between the bimetal and a pressing member. The manufacturing unit uses a characteristic value of a circuit breaker for wiring and accumulated and stored interval information, to adjust the position of the pressing member. The database unit also accumulates and stores the interval information repeatedly obtained by the simulation unit and interval result information according to the adjusted position of the pressing member by the manufacturing unit.

Description

Circuit breaker manufacturing system and control method the same

The present invention relates to a system for manufacturing a circuit breaker for wiring and a control method therefor, and more particularly, to a system for manufacturing a circuit breaker for wiring and a method for controlling the same will be.

A circuit breaker for wiring is a type of circuit breaker, and when abnormal currents such as short circuit or overcurrent occur, it is a device that can cut off electricity to prevent electrical accidents.

A general circuit breaker for wiring includes a fixed contact and a movable contact inside. While the normal current, not the above-described abnormal current, flows, the stationary contact and the movable contact are in contact with each other and conduction is possible. In addition, when the above-described abnormal current flows, the fixed contact and the movable contact are spaced apart to prevent conduction.

The process in which the fixed contact and the movable contact are separated is referred to as a 'trip operation'. The trip operation is performed by rotating the crossbar positioned adjacent to the opening/closing mechanism and rotating the opening/closing mechanism, so that the movable contact is separated from the fixed contact.

In addition, a member such as a bimetal and a rivet that can be moved together by being coupled to the bimetal is provided adjacent to the crossbar. At this time, when an overcurrent or the like is applied, the bimetal is heated by heat generated from a heater adjacent to the bimetal and curved toward the crossbar.

Accordingly, a rivet or the like coupled to the bimetal presses the crossbar, and the crossbar and the opening/closing mechanism connected thereto are rotated by the pressurization to perform a trip operation.

At this time, in order to ensure the operation reliability of the circuit breaker, the time required to perform the trip operation when an overcurrent is applied must be less than a predetermined time.

That is, even when the material, size, shape, etc. are different for each circuit breaker, the operation reliability of the circuit breaker can be guaranteed only when the trip operation is performed within the predetermined time.

Referring to Figure 1, the configuration of the circuit breaker 1000 according to the prior art is schematically shown.

That is, the circuit breaker 1000 according to the prior art includes a bimetal 1100 , a rivet 1200 coupled to the bimetal 1100 , and a crossbar 1300 that is pressed and rotated by the rivet 1200 .

As described above, the optimal distance between the end of the rivet 1200 and the crossbar 1300 should be determined differently for each circuit breaker 1000 for wiring.

Referring to FIG. 2 , a process of adjusting the distance between the end of the rivet 1200 and the crossbar 1300 in the circuit breaker 1000 according to the prior art is schematically illustrated.

That is, first, the rivet 1200 is inserted and coupled to the through hole formed in the bimetal 1100 . In this case, the diameter of the through hole is formed to be larger than the outer diameter of the rivet 1200 , and the rivet 1200 may be moved in a direction toward the crossbar 1300 or in the opposite direction while being inserted and coupled to the through hole.

As shown in FIG. 2A , in an initial state, the rivet 1200 is adjusted to be in contact with the crossbar 1300 . Thereafter, when the overcurrent is applied to the circuit breaker 1000 for a set amount and time, the bimetal 1100 is heated and curved toward the crossbar 1300 (see FIG. 2B ).

Accordingly, since the rivet 1200 is maintained in contact with the crossbar 1300 , the position where the rivet 1200 and the bimetal 1100 are coupled is adjacent to the crossbar 1300 .

It will be understood that the maximum displacement at which the bimetal 1100 is curved is the displacement at the point in time when the overcurrent is cut off.

Accordingly, in the circuit breaker 1000 according to the prior art, the position of the rivet 1200 in the above state, that is, at the moment when the overcurrent is cut off, is the distance between the rivet 1200 and the crossbar 1300 of the circuit breaker 1000 for the wiring. is considered

After the above process is performed, the rivet 1200 is coupled to the bimetal 1100 by welding or the like. After the bonding process, the bimetal 1100 is cooled and rotated back to the position before the overcurrent is applied, that is, in a direction away from the crossbar 1300 (see FIG. 2(c) ).

When the process is finished, a process of testing the performance of the circuit breaker 1000 for wiring is performed.

That is, a current for testing the distance between the rivet 1200 and the crossbar 1300 or the performance of the completed circuit breaker 1000 for wiring is passed through the circuit breaker 1000 for wiring, and the bimetal 1100 is curved, and thus the crossbar A process in which 1300 is rotated to perform a trip operation is performed again.

In summary, in the manufacturing method of the circuit breaker 1000 for wiring according to the prior art, the position of the rivet 1200 is adjusted in a state in which current is applied.

Moreover, according to the prior art, in order to manufacture the circuit breaker 1000 for wiring of different specifications, the above process must be separately performed for each circuit breaker 1000 for wiring.

Therefore, according to the prior art, since it is necessary to thoroughly investigate the performance of all the circuit breakers 1000 for wiring, this also requires a lot of time.

As a result, the manufacturing method of the circuit breaker 1000 for wiring according to the prior art is complicated and requires a lot of time to improve the reliability of the finished product.

Korean Patent Laid-Open Publication No. 10-2009-0002882 discloses a bimetal bonding structure of an earth leakage breaker. Specifically, a bimetal coupling structure having a structure capable of force-fitting a bimetal and a connection terminal by using a contact portion between a coupling protrusion formed on the bimetal and a connection terminal is disclosed.

However, this type of bimetal coupling structure only suggests a coupling method with a connection terminal, and does not suggest a method for easily measuring the curved distance of the bimetal.

Korean Utility Model Document No. 20-2010-0000571 discloses a current breaker using a positive thermistor and a bimetal. Specifically, when the bimetal is cooled, the bimetal electrode and the bimetal are automatically turned on, and when a predetermined time elapses after the trip operation is performed, a current circuit breaker having a structure that can be energized with the outside is disclosed.

However, this type of current breaker only suggests a method for conducting electricity with the outside, and still does not provide a method for easily measuring the curvature distance of the bimetal.

Korean Patent Publication No. 10-2009-0002882 (2009.01.09.) Korean Utility Model Document No. 20-2010-0000571 (2010.01.19.)

An object of the present invention is to provide a system for manufacturing a circuit breaker for wiring and a method for controlling the same, which can solve the above problems.

First, an object of the present invention is to provide a system for manufacturing a circuit breaker capable of determining a relative position between a crossbar, a bimetal, and a pressing member without passing through a separate current passing process in the actual manufacturing process, and a method for controlling the same.

Another object of the present invention is to provide a system for manufacturing a circuit breaker capable of accurately determining a relative position between a crossbar, a bimetal, and a pressing member, and a method for controlling the same.

Another object of the present invention is to provide a circuit breaker manufacturing system and a control method thereof, in which positions of a crossbar, a bimetal, and a pressing member can be precisely adjusted according to the determined relative positions.

Another object of the present invention is to provide a system for manufacturing a circuit breaker for wiring capable of preventing damage to a bimetal due to overcurrent application, and a method for controlling the same.

In addition, an object of the present invention is to provide a circuit breaker manufacturing system and a method for controlling the same, in which reliability and accuracy of collected data can be improved.

In order to achieve the above object, the present invention, a simulation unit for calculating test result information related to the test manufacturing of a circuit breaker for wiring; and a manufacturing unit that manufactures the circuit breaker using the test result information calculated by the simulation unit, wherein the wiring circuit breaker includes: a crossbar movably provided; a bimetal positioned spaced apart from the crossbar and curved in a direction toward the crossbar by receiving a current; and a pressing member coupled to the bimetal and moving toward the crossbar together with the bimetal to press the crossbar, wherein the test result information is information on an optimal distance between an end of the pressing member and the bimetal It provides a circuit breaker manufacturing system for wiring including gap information.

In addition, the simulation unit of the circuit breaker manufacturing system may include: a current application module connected to the circuit breaker and energized to apply the current to the circuit breaker for a preset time; and an image information collection module configured to collect image information on a position of the bimetal bent toward the crossbar by the heat generated by the current.

In addition, the simulation unit of the circuit breaker manufacturing system for wiring may include: an interval information calculation module configured to calculate the interval information using the collected image information; and a speed information calculation module for calculating speed information on a speed at which the bimetal is bent by using the interval information and the preset time.

In addition, the circuit breaker manufacturing system for wiring further includes a database unit operably connected to the simulation unit to store the test result information calculated by the simulation unit, and the database unit, the interval for storing the calculated interval information information storage unit; and a speed information calculation unit for storing the calculated speed information.

In addition, the circuit breaker of the circuit breaker manufacturing system for wiring includes an opening/closing mechanism to which the crossbar is connected and rotationally operated by rotation of the crossbar, and the simulation unit includes load information for the load of the opening-and-closing mechanism and the opening/closing mechanism. and an opening/closing mechanism information collection module configured to detect one or more pieces of information among distance information on a rotation distance of the crossbar according to rotation of the mechanism.

In addition, the circuit breaker for wiring of the circuit breaker manufacturing system includes an opening/closing mechanism to which the crossbar is connected and rotationally operated by rotation of the crossbar, and the manufacturing unit is based on a load of the opening-and-closing mechanism and a rotation distance of the crossbar. It may include a manufacturing information input module for receiving the opening and closing mechanism manufacturing information for the input.

In addition, the manufacturing unit of the circuit breaker manufacturing system for wiring, a gap adjusting module for adjusting the optimum distance between the end of the pressing member and the bimetal according to the calculated test result information; and a welding module for welding the pressing member and the bimetal.

In addition, the manufacturing unit of the circuit breaker manufacturing system for wiring may include an image information collection module configured to detect image information on positions of the welding pressing member and the bimetal.

In addition, the manufacturing unit of the circuit breaker manufacturing system for wiring may include an interval result information calculation module for calculating interval result information for the shortest distance between the bimetal and the end of the pressing member coupled using the collected image information. can

In addition, the circuit breaker manufacturing system for wiring further includes a database unit connected to the manufacturing unit to be energized and storing the interval result information calculated by the manufacturing unit, wherein the database unit stores the input opening/closing mechanism unit manufacturing information an opening/closing mechanism manufacturing information storage unit; and an interval result information storage unit for storing the calculated interval result information.

In addition, the database unit of the circuit breaker manufacturing system for wiring may include an information comparison module for comparing the interval information calculated in the simulation unit with the interval result information, and correcting the interval information calculated according to the interval result information there is.

In addition, the present invention, (a) the simulation unit collecting test information related to the test manufacturing of the circuit breaker for wiring; (b) calculating test result information using the test information collected by the simulation unit; (c) storing the collected test information and the calculated test result information in a database unit; and (d) manufacturing the circuit breaker according to the stored test information and the test result information, wherein the test information is provided in the wiring breaker and directed toward the crossbar by the heat generated by the application of current. Containing image information on the position of the curved bimetal, the test result information includes interval information that is information about the optimal distance between the bimetal and the pressing member of the circuit breaker for wiring that is test-manufactured Control of a circuit breaker manufacturing system provide a way

In addition, the step (a) of the control method of the circuit breaker manufacturing system for wiring includes: (a1) the opening/closing mechanism information collection module determines the load information on the load of the opening/closing mechanism unit and the rotation distance of the crossbar according to the rotation of the opening/closing mechanism unit. collecting distance information for and (a2) an image information collection module collecting the image information of the bimetal.

In addition, the step (b) of the control method of the circuit breaker manufacturing system for wiring includes: (b1) calculating the interval information using the image information collected by the interval information calculation module; and (b2) calculating the speed information by using the interval information calculated by the speed information calculation module and preset time information, which is the time when a current is applied to the circuit breaker for wiring.

In addition, the step (c) of the control method of the circuit breaker manufacturing system for wiring may include: (c1) storing the load information or distance information of the opening and closing mechanism unit in which the opening/closing mechanism information storage unit is collected; and (c2) storing the calculated interval information by the interval information storage module.

In addition, the step (d) of the control method of the circuit breaker manufacturing system for wiring, (d1) receiving the manufacturing information of the opening and closing mechanism part of the circuit breaker for wiring to be manufactured manufacturing information input module is manufactured; and (d2) matching the manufacturing information of the opening and closing mechanism unit input by the manufacturing information input module with the test information stored in the database unit.

In addition, the step (d) of the control method of the circuit breaker manufacturing system for wiring includes the pressing member provided in the circuit breaker according to the interval information calculated by the (d3) interval adjustment module after the step (d2); It may include adjusting the distance between the bimetals.

In addition, the step (d) of the control method of the circuit breaker manufacturing system for wiring, after the step (d3), (d4) welding module welding the pressing member and the bimetal to combine; and (d5) collecting image information on a distance between the bimetal and the pressing member to which the image information collection module is coupled.

In addition, the control method of the circuit breaker manufacturing system for wiring is, after step (d), (e) using the image information about the distance between the pressing member and the bimetal of the circuit breaker for the wiring produced by the manufacturing result information calculating unit, the manufacturing unit It may include calculating the interval result information, which is information about the optimal distance between the pressing member of the circuit breaker for wiring and the bimetal manufactured by .

In addition, the control method of the circuit breaker manufacturing system for wiring may include, after step (e), (f) storing the opening and closing mechanism unit manufacturing information input by the database unit and the calculated interval result information.

In addition, the step (f) of the control method of the circuit breaker manufacturing system for wiring includes: (f1) storing the opening and closing mechanism manufacturing information to which the opening and closing mechanism manufacturing information storage unit is input; and (f2) storing the calculated interval result information by an interval result information calculation unit.

In addition, in the control method of the circuit breaker manufacturing system for wiring, after step (f), (g) an information comparison module compares the stored test result information and the stored result information, and the stored test according to the stored result information It may include the step of modifying the result information.

According to an embodiment of the present invention, the following effects can be achieved.

First, the circuit breaker manufacturing system for wiring is provided with a simulation unit and a manufacturing unit. The simulation unit collects data for manufacturing a circuit breaker for wiring. The simulation unit collects test result information on the relative positions of the crossbar, the bimetal, and the pressing member by applying an overcurrent.

The manufacturing unit actually manufactures the circuit breaker based on the test result information obtained from the simulation unit. At this time, the manufacturing unit adjusts the relative positions of the crossbar, the bimetal, and the pressing member by using the test result information obtained without a separate process of applying the overcurrent.

Therefore, in the process of actually manufacturing the circuit breaker for wiring, an overcurrent application process other than the overcurrent application for testing the completed circuit breaker may be omitted.

In addition, the simulation unit is provided with an image information collection module. The image information collection module collects image information about the degree of curvature of the bimetal according to the application and release of the overcurrent in real time and continuously. The image information collected by the image information collection module is mapped with the collected time and stored.

That is, the simulation unit may calculate the interval information and the velocity information by using the information on the displacement of the bimetal and the information on the time during which the bimetal is bent. Accordingly, the position of the pressing member can be determined more quickly and accurately compared to a case where an overcurrent is additionally applied during the manufacturing process.

In addition, the manufacturing unit is provided with a spacing adjustment module. The gap adjusting module automatically adjusts the position of the pressing member according to the matched gap information.

Accordingly, compared to the case of manually adjusting the position of the pressing member while measuring the distance between the pressing member and the bimetal, the speed, reliability, and productivity of the operation may be improved.

In addition, when the manufacturing unit actually manufactures the circuit breaker by the above-described configuration, an overcurrent conduction process for determining the relative positions of the crossbar, the bimetal, and the pressing member is not required.

Therefore, except for the test process, the overcurrent application process is not performed in the manufacturing process of the circuit breaker. As a result, damage to the components of the circuit breaker according to the overcurrent application can be minimized.

In addition, the database unit includes a test result information storage module and a result information storage module. In the test result information storage module, the information collected in the test production process by the simulation unit is accumulated and stored. In addition, information collected in the actual manufacturing process by the manufacturing unit is accumulated and stored in the result information storage module.

In other words, the data collected during trial production and actual production are accumulated and stored in the database to make it big data.

Furthermore, the database unit includes an information comparison module. The information comparison module is electrically connected to the test result information storage module and the result information storage module, respectively. The information comparison module compares the result information stored in the result information storage module with the test result information stored in the test result information storage module, and if there is a difference, corrects the test result information according to the result information, which is information collected during actual production.

Accordingly, each piece of information collected during the trial production process and the actual production process is stored and configured as big data. In addition, the test result information stored by the information comparison module may be corrected according to the actual production situation. Accordingly, reliability and accuracy of information stored in each storage module may be improved through a machine learning process.

As a result, the operational reliability of the circuit breaker for wiring manufactured according to the stored information can also be improved.

1 is a front view (a) and a side view (b) showing the assembly state of the bimetal and rivets provided in the circuit breaker for wiring according to the prior art.
2 is a side view illustrating a process of adjusting a distance between a crossbar and a rivet in a circuit breaker for wiring according to the prior art.
3 is a side cross-sectional view illustrating a circuit breaker for wiring manufactured according to a system for manufacturing a circuit breaker and a control method thereof according to an embodiment of the present invention.
4 is a block diagram illustrating a configuration for implementing a circuit breaker manufacturing system and a control method thereof according to an embodiment of the present invention.
5 is a plan view illustrating factors utilized to implement a circuit breaker manufacturing system for wiring and a control method thereof according to an embodiment of the present invention.
6 is a conceptual diagram illustrating a process in which a relative position between a pressing member and a bimetal is determined by a circuit breaker manufacturing system and a control method thereof according to an embodiment of the present invention.
7 is a flowchart illustrating a control method of a circuit breaker manufacturing system according to an embodiment of the present invention.
8 is a flowchart illustrating a detailed flow of step S100 of the control method of a circuit breaker manufacturing system for wiring according to an embodiment of the present invention.
9 is a flowchart illustrating a detailed flow of step S200 of the control method of a circuit breaker manufacturing system for wiring according to an embodiment of the present invention.
10 is a flowchart illustrating a detailed flow of step S300 of the control method of a circuit breaker manufacturing system for wiring according to an embodiment of the present invention.
11 is a flowchart illustrating a detailed flow of step S400 of the control method of a circuit breaker manufacturing system for wiring according to an embodiment of the present invention.
12 is a flowchart illustrating a detailed flow of step S500 of the control method of a circuit breaker manufacturing system for wiring according to an embodiment of the present invention.
13 is a flowchart illustrating a detailed flow of step S600 of a control method of a circuit breaker manufacturing system for wiring according to an embodiment of the present invention.
14 is a flowchart illustrating a detailed flow of step S700 of the control method of a circuit breaker manufacturing system for wiring according to an embodiment of the present invention.

Hereinafter, a system for manufacturing a circuit breaker and a control method thereof according to an embodiment of the present invention will be described in detail with reference to the accompanying drawings.

In the following description, in order to clarify the characteristics of the present invention, descriptions of some components may be omitted.

1. Definition of terms

The term "breaker" used in the following description means any device capable of cutting off current when detecting leakage current or overcurrent, such as a ground leakage breaker or a circuit breaker for wiring.

The term "normal current" used in the following description means a current flowing in a normal state, in which the circuit breaker does not perform a blocking operation.

The term "abnormal current" used in the following description refers to a current other than a normal current in which the circuit breaker performs a blocking operation. The abnormal current may include a leakage current, an overcurrent, an undercurrent, and the like.

The term “conductive connection” used in the following description means that one or more members are connected to transmit a current or an electrical signal. The energizable connection may be formed by a wired method such as a conducting wire member or a wireless method such as Bluetooth or Wi-Fi.

The term "test information" used in the following description means any information collected in the course of the simulation unit 10 testing and manufacturing the circuit breaker 30 for wiring. In an embodiment, the test information may include opening/closing mechanism information and image information.

The term "test result information" used in the following description means any information that the simulation unit 10 calculates using the collected test information. In an embodiment, the test result information may include interval information and speed information.

The term "manufacturing information" used in the following description means any information that is a criterion for determining the standard of the circuit breaker 30 for wiring, which is manufactured by the manufacturing unit 20 . In an embodiment, the manufacturing information may include manufacturing information of the opening/closing mechanism.

The term “result information” used in the following description means any information that is calculated using the image information collected by the manufacturing unit 20 while manufacturing the circuit breaker 30 for wiring. In an embodiment, the result information may include interval result information.

The term “optimal distance” used in the following description means a distance between the pressing member 35 and the crossbar 33 for the circuit breaker 30 to perform a trip operation within a preset reference time. In an embodiment, the optimal distance may mean the shortest distance between the pressing member 35 and the crossbar 33 .

The term “gap information” used in the following description means information on an optimal distance between a plurality of members spaced apart from each other.

2. Description of the circuit breaker manufacturing system (1) for wiring according to an embodiment of the present invention

3 to 6 , the wiring circuit breaker manufacturing system 1 according to an embodiment of the present invention includes a simulation unit 10 , a manufacturing unit 20 , a wiring circuit breaker 30 , and a database unit 500 .

The circuit breaker manufacturing system 1 for wiring according to an embodiment of the present invention acquires information for manufacturing the circuit breaker 30 for wiring through a trial manufacturing process (ie, a simulation process).

Specifically, the circuit breaker 30 for wiring should be manufactured in different standards according to the strength of the current to be passed through, the installation environment, and the like. Accordingly, in each work line, the circuit breaker 30 for wiring must be individually manufactured according to the specification of each circuit breaker 30 .

In particular, in order to configure different conduction and blocking performance of the circuit breaker 30 for wiring, the relative positional relationship between the crossbar 33 and the pressing member 35 must be adjusted.

Accordingly, the circuit breaker manufacturing system 1 for wiring according to an embodiment of the present invention acquires test result information for manufacturing the circuit breaker 30 for wiring through the simulation unit 10 . It will be understood that the test result information is information related to the positional relationship of the crossbar 33 , the bimetal 34 , and the pressing member 35 .

The test result information obtained through the simulation unit 10 is transmitted to the manufacturing unit 20 . In addition, information about the characteristics of the circuit breaker 30 for wiring to be manufactured (ie, manufacturing information) is input to the manufacturing unit 20 .

Accordingly, the manufacturing unit 20 matches and compares the obtained test result information and the information about the input characteristics. In addition, the manufacturing unit 20 manufactures the circuit breaker 30 for wiring according to the matched test result information. Accordingly, the relative positional relationship between the crossbar 33 , the bimetal 34 , and the pressing member 35 may be adjusted without a separate measurement process.

The above process may be performed by one process. That is, it will be understood that the circuit breaker 30 for wiring manufactured by the manufacturing unit 20 after the test result information is obtained from the simulation unit 10 is the same.

(1) Description of the simulation unit 10

The simulation unit 10 collects various test information required for manufacturing the circuit breaker 30 for wiring, and collects and calculates test result information using the collected test information.

The test information and test result information collected and calculated by the simulation unit 10 are utilized to calculate the expected information required for the manufacturing unit 20 to actually manufacture the circuit breaker 30 for wiring.

The simulation unit 10 tests and manufactures the circuit breaker 30 for wiring. That is, the simulation unit 10 tests and manufactures the circuit breaker 30 for wiring, and calculates test information and test result information for manufacturing the circuit breaker 30 for wiring to be actually shipped by the manufacturing unit 20 .

To this end, the simulation unit 10 may include arbitrary components for manufacturing the circuit breaker 30 for wiring in addition to various components to be described later. In particular, the simulation unit 10 may include any component related to adjusting the spacing between the pressing member 35 and the crossbar 33 .

Each of the units 100 and 200 of the simulation unit 10 to be described below may be electrically connected to each other. Each piece of information collected or calculated in each of the units 100 and 200 may be transmitted to the other units 100 and 200 .

In addition, the simulation unit 10 is electrically connected to the database unit 500 . Each information collected or calculated by the simulation unit 10 may be transmitted to the database unit 500 .

The simulation unit 10 may collect, calculate, and store test information and test result information about the circuit breaker 30 for wiring of various standards.

Hereinafter, the circuit breaker 30 for wiring manufactured by the simulation unit 10 will be described as "test-manufactured".

In the illustrated embodiment, the simulation unit 10 includes a test information collecting unit 100 and a test result information calculating unit 200 .

The test information collection unit 100 collects various test information while the simulation unit 10 tests and manufactures the circuit breaker 30 for wiring.

The test information collected by the test information collecting unit 100 is transmitted to the test result information calculating unit 200 . The test information collecting unit 100 is electrically connected to the test result information calculating unit 200 .

The test information collected by the test information collection unit 100 is transmitted to the database unit 500 . The test information collection unit 100 is electrically connected to the database unit 500 .

The test information collection unit 100 may collect information about the unique standard of the circuit breaker 30 for wiring. For example, the test information collection unit 100 may collect information related to the load of the opening/closing mechanism unit 32 , information related to a distance to which the crossbar 33 moves when the opening/closing mechanism unit 32 is operated, and the like.

In addition, the test information collection unit 100 may collect arbitrary information that may be collected in the process of manufacturing the circuit breaker 30 for a test. As an example, the test information collection unit 100 collects information on the degree of curvature of the bimetal 34 during the trial manufacturing process, the interval between the crossbar 33 and the pressing member 35, and the magnitude and time of the applied current. can be collected

The test information collection unit 100 may include various types of components for collecting the information. In the illustrated embodiment, the test information collection unit 100 includes an opening/closing mechanism information collection module 110 , a current application module 120 , and an image information collection module 130 .

The opening/closing mechanism information collection module 110 collects opening/closing mechanism information, which is information on the intrinsic characteristics of the circuit breaker 30 for test production. That is, the opening/closing mechanism information may be different for each circuit breaker 30 for wiring.

The opening/closing mechanism information may include information on various conditions required for the circuit breaker 30 for wiring to perform a trip operation. In the illustrated embodiment, the opening/closing mechanism information includes load information and distance information.

The opening/closing mechanism information collected by the opening/closing mechanism information collection module 110 is transferred to and stored in the test result information storage module 510 of the database unit 500 . The opening/closing mechanism information collection module 110 is electrically connected to the test result information storage module 510 .

As will be described later, when the manufacturing information of the opening/closing mechanism part of the circuit breaker 30 to be manufactured is input to the manufacturing unit 20, the manufacturing information input module 310 matches the input opening/closing mechanism manufacturing information with the pre-stored opening/closing mechanism unit information. In addition, the manufacturing information input module 310 manufactures the circuit breaker 30 for wiring by using the interval information corresponding to the matched opening and closing mechanism information.

That is, the opening/closing mechanism information functions as a kind of key data.

In addition, the opening/closing mechanism information collection module 110 may be provided in any form capable of transmitting the collected information to other modules or units.

In an embodiment, the opening/closing mechanism information collection module 110 may be provided in the form of a load cell or a distance measuring unit that can be electrically connected to the outside.

In the illustrated embodiment, the opening/closing mechanism information collection module 110 includes a load information collection unit 111 and a distance information collection unit 112 .

The load information collecting unit 111 collects load information, which is information about a force required to rotate the opening/closing mechanism part 32 or the crossbar 33 . That is, the load information may be defined as information related to the load of the opening/closing mechanism part 32 .

The load information collection unit 111 may be provided in any form capable of collecting load information. In an embodiment, the load information collection unit 111 may be provided in the form of a load cell capable of measuring the magnitude of the force applied to the rotating member.

The load information collected by the load information collection unit 111 is transmitted to the test result information storage module 510 of the database unit 500 . The load information collection unit 111 and the test result information storage module 510 are electrically connected.

The distance information collecting unit 112 collects distance information, which is information about a distance at which the opening/closing mechanism 32 rotated by the crossbar 33 moves or rotates to complete the trip operation.

The distance information collecting unit 112 may be provided in any form capable of collecting distance information. In an embodiment, the distance information collection unit 112 may be provided in the form of a ruler capable of measuring the displacement of the rotating member.

In another embodiment, the distance information collecting unit 112 may be provided in the form of a camera capable of collecting image information about the rotation of the opening/closing mechanism unit 32 .

The distance information collected by the distance information collection unit 112 is transmitted to the test result information storage module 510 of the database unit 500 . The distance information collection unit 112 and the test result information storage module 510 are electrically connected.

The current application module 120 applies a current to the circuit breaker 30 to be tested. The current application module 120 is electrically connected to the circuit breaker 30 to be tested.

Specifically, the current application module 120 is electrically connected to the heater 36 of the circuit breaker 30 to be tested, and applies an overcurrent to the heater 36 for a preset time. The magnitude of the overcurrent and the time at which the overcurrent is applied to the bimetal 34 , that is, the preset time may be predetermined.

Heat generated by the heater 36 to which the overcurrent is applied is transferred to the bimetal 34 . Accordingly, the bimetal 34 and the pressing member 35 coupled to the bimetal 34 are curved toward the crossbar 33 . At this time, the pressing member 35 is coupled to the bimetal 34 movably in a direction toward the crossbar 33 and in a direction opposite to the crossbar 33 .

When the current application module 120 blocks the application of the overcurrent, that is, when the overcurrent is not passed through the bimetal 34 , the bimetal 34 is cooled. Accordingly, the bimetal 34 returns to a state before the overcurrent is applied (hereinafter, referred to as an “initial state”).

The above process is collected as image information by the image information collection module 130 and transmitted to the test result information calculating unit 200 . The test result information calculating unit 200 calculates the first interval information G1 , which is information on the distance between the bimetal 34 and the pressing member 35 , by using the image information.

The calculated first interval information G1 is accumulated and stored in the database unit 500 . Accordingly, when the manufacturing unit 20 manufactures the circuit breaker 30 for wiring, the distance between the bimetal 34 and the pressing member 35 or the distance between the pressing member 35 and the crossbar 33 can be adjusted without a separate energization process. can

The image information collection module 130 collects image information about the trial manufacturing process of the circuit breaker 30 for wiring. The image information collected by the image information collection module 130 may be in the form of a moving image or a still image.

The image information collected by the image information collection module 130 may include information on a relative positional relationship between the crossbar 33 , the bimetal 34 , and the pressing member 35 .

That is, the image information collection module 130 may collect information about the position before and after the bimetal 34 is heated and curved. In addition, the image information collection module 130 may collect information on the relative position of the end of the pressing member 35 movably coupled to the bimetal 34 and the bimetal 34 .

The image information collection module 130 may collect image information in real time and continuously while the simulation unit 10 is operating. The image information collected by the image information collection module 130 is mapped with time and stored.

The image information collected by the image information collection module 130 may be plural. That is, as will be described later, the circuit breaker 30 for wiring according to an embodiment of the present invention is provided with three bimetals 34a, 34b, and 34c. Accordingly, the image information collection module 130 may collect image information on the curvature and restoration of each of the bimetals 34a, 34b, and 34c, respectively.

The image information collection module 130 may be provided in any form capable of collecting image information. In an embodiment, the image information collection module 130 may be provided in the form of a vision camera or an infrared camera (IR camera).

The image information collected by the image information collection module 130 is transmitted to the test result information calculating unit 200 . The image information collection module 130 and the test result information calculating unit 200 are electrically connected.

The test result information calculating unit 200 calculates test result information by using the collected test information. The calculated test result information may be utilized as expected information required to actually manufacture the circuit breaker 30 for wiring together with the collected test information.

The test result information calculating unit 200 may receive test information necessary for calculating the test result information from the test information collecting unit 100 . The test result information calculating unit 200 is electrically connected to the test information collecting unit 100 .

The test result information calculating unit 200 may transmit the calculated test result information to the database unit 500 . The test result information calculating unit 200 is electrically connected to the database unit 500 .

The test result information calculating unit 200 may be provided in any form capable of inputting, calculating, and outputting information. In an embodiment, the test result information calculating unit 200 may be provided in the form of a central processing unit (CPU), a microprocessor, or the like.

The test result information calculating unit 200 may calculate arbitrary information related to the operation method or performance of the test-manufactured circuit breaker 30 for wiring.

As an example, the test result information calculating unit 200 includes information on the relative distance between the crossbar 33 , the bimetal 34 and the pressing member 35 , information on the speed at which the bimetal 34 is curved, and the bimetal 34 . It may include information on the speed of returning to this initial state, and the like.

In the illustrated embodiment, the test result information calculation unit 200 includes an interval information calculation module 210 and a speed information calculation module 220 .

The interval information calculation module 210 calculates interval information, which is information about the relative distance (ie, interval) between the crossbar 33 , the bimetal 34 , and the pressing member 35 using the collected image information and time information. do.

The interval information calculated by the interval information calculation module 210 may be expressed as a numerical value of a specific unit. In an embodiment, the calculated spacing information may be expressed in mm or um.

The interval information calculation module 210 may calculate interval information according to a time at which each image information is collected. The calculated interval information is mapped to each time. That is, the interval information calculation module 210 may calculate interval information at a specific time.

The interval information calculation module 210 may calculate a plurality of the interval information. The calculated plurality of interval information may be divided into first interval information G1 , second interval information G2 , and third interval information G3 according to a member forming the interval.

The first gap information G1 may be defined as information on an optimal distance between the bimetal 34 and an end of the pressing member 35 . That is, in the embodiment shown in FIG. 5 , the first interval information G1 is one end of the pressing member 35 toward the crossbar 33 , and the crossbar 33 of the bimetal 34 . It can be defined as information about the spacing between the surfaces.

The second gap information G2 may be defined as information on an optimal distance between the crossbar 33 and an end of the pressing member 35 . That is, in the embodiment shown in FIG. 5 , the second gap information G2 is defined as information on the distance between the one end of the pressing member 35 and the one surface or one corner of the crossbar 33 . can be

The third interval information G3 may be defined as information on an optimal distance between the bimetal 34 and the crossbar 33 . That is, in the embodiment shown in FIG. 5 , the third interval information G3 may be defined as information on the interval between the one surface of the bimetal 34 and the one surface or the one corner of the crossbar 33 . there is.

Accordingly, it will be understood that the sum of the first interval information G1 and the second interval information G2 is equal to the third interval information G3.

The interval information calculated by the interval information calculation module 210 is transmitted to the speed information calculation module 220, respectively. The interval information calculation module 210 is electrically connected to the speed information calculation module 220, respectively.

The interval information calculated by the interval information calculation module 210 is transmitted to the database unit 500 . The interval information calculation module 210 is electrically connected to the database unit 500 .

The velocity information calculation module 220 calculates velocity information, which is information about the bending velocity of the bimetal 34 , by using the collected image information and time information.

The speed information calculated by the speed information calculation module 220 may be expressed as a numerical value of a specific unit. In an embodiment, the calculated speed information may be expressed in mm/s units or um/s units.

The speed information calculation module 220 may calculate speed information for a time before the current is energized, that is, from a state in which the bimetal 34 is not curved to a maximum curve.

The speed information calculated by the speed information calculation module 220 is transmitted to the database unit 500 . The speed information calculation module 220 and the database unit 500 are electrically connected.

(2) Description of the production unit 20

The manufacturing unit 20 calculates expected information for manufacturing the circuit breaker 30 for actual wiring by using various information collected and calculated by the simulation unit 10 . The manufacturing unit 20 manufactures the circuit breaker 30 for wiring according to the calculated expected information.

In this case, as described above, the manufacturing unit 20 may perform an operation for adjusting the relative positional relationship between the crossbar 33 , the bimetal 34 , and the pressing member 35 .

The manufacturing unit 20 is electrically connected to the simulation unit 10 . Each information collected and calculated by the simulation unit 10 may be transmitted to the manufacturing unit 20 . Specifically, each information collected and calculated by the simulation unit 10 may be transmitted to the manufacturing unit 20 through the database unit 500 .

The manufacturing unit 20 manufactures the circuit breaker 30 for actual wiring. That is, the manufacturing unit 20 manufactures the circuit breaker 30 for wiring to be actually shipped by using various information collected, calculated and accumulated by the simulation unit 10 .

To this end, the manufacturing unit 20 may include arbitrary components for manufacturing the circuit breaker 30 for wiring in addition to various components to be described later. In particular, the fabrication unit 20 may include any component related to adjusting the spacing between the crossbar 33 , the bimetal 34 , and the pressing member 35 .

Each of the parts 300 and 400 of the manufacturing unit 20 to be described below may be electrically connected to each other. Each piece of information input, collected, or calculated in each of the units 300 and 400 may be transmitted to the other units 300 and 400 .

In the illustrated embodiment, the manufacturing unit 20 includes a circuit breaker manufacturing unit 300 and a manufacturing result information calculating unit 400 .

The circuit breaker manufacturing unit 300 receives information for actually manufacturing the circuit breaker 30 for wiring, that is, the circuit breaker 30 for wiring that has undergone a trial manufacturing process in the simulation unit 10, and based on the input information, the circuit breaker 30 for wiring ) is actually produced.

In the illustrated embodiment, the circuit breaker manufacturing unit 300 includes a manufacturing information input module 310 , a gap adjustment module 320 , a welding module 330 , an image information collection module 340 , an adhesion module 350 , and a test module ( 360).

The manufacturing information input module 310 receives information related to the standard of the circuit breaker 30 for wiring that is to be manufactured. In addition, the manufacturing information input module 310 receives information on conditions to be satisfied in the manufacturing process of the circuit breaker 30 for wiring.

That is, the manufacturing information may be defined as information about a manufacturing process of the circuit breaker 30 for wiring and a condition to be satisfied by the completed circuit breaker 30 for wiring. The production information may include any information related thereto.

As an example, the manufacturing information includes information on the time required for manufacturing the circuit breaker 30 for wiring, information on the size and energization time of the current to be energized through the circuit breaker 30 for wiring, information on the target overcurrent trip time, and in the test process. Information on the magnitude of the current to be applied may be included.

In this case, the information on the target overcurrent trip time may include an intermediate value of a preset condition.

In this case, the preset condition may be defined as a condition for a trip time at which the circuit breaker 30 for wiring may be determined to operate normally. The preset condition may be expressed as a period of time.

For example, the preset condition may be set to 80 seconds to 120 seconds. In the above example, the information on the target overcurrent trip time may be set to 100 seconds.

Accordingly, it will be understood that the information on the target overcurrent trip time is information for determining that the circuit breaker 30 for wiring operates normally, that is, as intended during design, among the values derived from the test results.

The manufacturing information may include information on various conditions required for the circuit breaker 30 for wiring to perform a trip operation. In an embodiment, the opening/closing mechanism manufacturing information includes load manufacturing information and distance manufacturing information.

The load manufacturing information and the distance manufacturing information may be defined as opening/closing mechanism manufacturing information.

As described above, the load production information may be information about the load of the opening/closing mechanism unit 32 . In addition, the distance manufacturing information may be information on a distance at which the crossbar 33 is rotated when the opening/closing mechanism unit 32 is operated.

The opening/closing mechanism manufacturing information input to the manufacturing information input module 310 is transmitted to the information comparison module 530 of the database unit 500 . The manufacturing information input module 310 is electrically connected to the database unit 500 .

The information comparison module 530 matches the opening/closing mechanism unit information stored in the test result information storage module 510 with the input opening/closing mechanism unit manufacturing information. In addition, the information comparison module 530 transmits the interval information corresponding to the matched opening and closing mechanism unit information to the interval adjustment module 320 .

The production information input module 310 may receive production information in an automatic or manual manner.

For example, the manufacturing information input module 310 may be provided in the form of a barcode scanner, and may receive manufacturing information in the form of scanning a barcode provided in the circuit breaker 30 test manufactured by the simulation unit 10 . .

In an embodiment in which the production information input module 310 receives production information in a manual manner, the production information input module 310 may receive production information input by a worker.

In the above embodiment, the production information input module 310 may be provided in any form capable of receiving information. For example, the production information input module 310 may be provided with a touch panel, a button that is pressed, or an LCD or LED panel that can select a preset standard.

The gap adjustment module 320 is operated according to the gap information stored in the database unit 500 to move the pressing member 35 in a direction toward the crossbar 33 or in a direction opposite thereto.

Accordingly, the first gap information G1 that is the gap between the bimetal 34 and the end of the pressing member 35 may also be adjusted. As a result, the second interval information G2, which is the interval between the crossbar 33 and the end of the pressing member 35, can be adjusted.

The gap adjusting module 320 may be provided in any form that is physically or electrically operated to move the pressing member 35 in a direction toward or opposite to the crossbar 33 .

In an embodiment, the interval adjusting module 320 may be provided as a servo motor.

The interval adjustment module 320 receives interval information matched by the information comparison module 530 and stored in the test result information storage module 510 . The interval adjustment module 320 is electrically connected to the test result information storage module 510 .

The welding module 330 couples the pressing member 35 whose position has been adjusted and the bimetal 34 . In an embodiment, the welding module 330 may couple the pressing member 35 and the bimetal 34 by welding the contact or adjacent portions of the pressing member 35 and the bimetal 34 .

The welding module 330 may include an additional member for checking a welding state. The additional member may inspect the welding state of the bimetal 34 and the pressing member 35 . It will be understood that the inspection process is performed after the welding portion of the bimetal 34 and the pressing member 35 is sufficiently cooled.

The image information collection module 340 collects image information about the circuit breaker 30 for wiring in a state in which the welding operation is completed by the welding module 330 . The image information collected by the image information collection module 340 may be in the form of a moving image or a still image.

The image information collected by the image information collection module 340 may include information on a relative positional relationship between the crossbar 33 , the bimetal 34 , and the pressing member 35 .

The image information collected by the image information collection module 340 may be plural. That is, as will be described later, the circuit breaker 30 for wiring according to an embodiment of the present invention is provided with three bimetals 34a, 34b, and 34c. In addition, a plurality of pressing members 35 are also provided and coupled to the plurality of bimetals 34a, 34b, and 34c, respectively.

Accordingly, the image information collection module 340 may collect image information on the relative positions of each of the pressing members 35 coupled to each of the bimetals 34a, 34b, and 34c, respectively.

The image information collection module 340 may be provided in any form capable of collecting image information. In one embodiment, the image information collection module 340 may be provided in the form of a vision camera or an infrared camera (IR camera).

The image information collected by the image information collection module 340 is transmitted to the production result information calculating unit 400 . The image information collection module 340 and the production result information calculating unit 400 are electrically connected.

After the welding inspection is completed, the bonding module 350 reconnects the bimetal 34 and the pressing member 35 . Accordingly, the coupling state between the bimetal 34 and the pressing member 35 may be more firmly maintained.

In an embodiment, the adhesive module 350 may further couple the bimetal 34 and the pressing member 35 by applying an adhesive or the like to the bonding portion between the bimetal 34 and the pressing member 35 .

The test module 360 applies a current for testing the circuit breaker 30 for wiring that has been manufactured. That is, the test module 360 checks whether the circuit breaker 30 for wiring manufactured through the above process operates as intended (that is, as designed) when an actual current is energized.

The test module 360 is electrically connected to the bimetal 34 . An overcurrent for testing may be applied to the bimetal 34 by the testing module 360 .

The manufacturing result information calculating unit 400 calculates manufacturing result information by using each information collected in the manufacturing process of the circuit breaker 30 for wiring. The calculated manufacturing result information is calculated and classified information collected during the actual manufacturing of the circuit breaker 30 for wiring, and may be utilized to determine the manufacturing result of the circuit breaker 30 for wiring.

In addition, the calculated result information may be accumulated and stored and utilized as a database related to the manufacture of the circuit breaker 30 for wiring. Furthermore, the calculated result information may be used as a basis for correcting the stored test result information according to an actual situation.

The manufacturing result information calculating unit 400 may receive information necessary for calculating the result information from the circuit breaker manufacturing unit 300 . The manufacturing result information calculating unit 400 is electrically connected to the circuit breaker manufacturing unit 300 .

The production result information calculating unit 400 may transmit the calculated result information to the database unit 500 . The manufacturing result information calculating unit 400 is electrically connected to the database unit 500 .

The manufacturing result information calculating unit 400 may be provided in any form capable of inputting, calculating, and outputting information. In an embodiment, the manufacturing result information calculating unit 400 may be provided in the form of a central processing unit (CPU), a microprocessor, or the like.

The manufacturing result information calculating unit 400 may calculate arbitrary information related to the manufacturing process, operating state, or performance of the circuit breaker 30 for wiring.

As an example, the manufacturing result information calculating unit 400 includes information on the relative distance between the crossbar 33 , the bimetal 34 and the pressing member 35 , information on the speed at which the bimetal 34 is curved, and the bimetal 34 . It may include information on the speed of returning to this initial state, and the like.

In the illustrated embodiment, the production result information calculation unit 400 includes an interval result information calculation module 410 . That is, in the illustrated embodiment, the manufacturing result information includes interval result information.

The interval result information calculation module 410 uses the collected image information and information about the time at which the image information was collected, the relative distance (ie, the interval) between the crossbar 33 , the bimetal 34 and the pressing member 35 . ), the interval result information is calculated.

The interval result information calculated by the interval result information operation module 410 may be expressed as a numerical value of a specific unit. In an embodiment, the calculated interval result information may be expressed in mm or um.

The interval result information calculation module 410 may calculate interval result information according to the time at which the image information, which is the basis thereof, is collected. The calculated interval result information is mapped to each time. That is, the interval result information calculation module 410 may calculate interval result information at a specific time.

The interval result information calculation module 410 may calculate a plurality of interval result information. The calculated plurality of interval result information may be divided into first interval result information G1 , second interval result information G2 , and third interval result information G3 according to a member forming the interval.

The first gap result information G1 may be defined as information on an optimal distance between the bimetal 34 and the end of the pressing member 35 . That is, referring back to FIG. 5 , the first interval result information G1 is one end of the pressing member 35 toward the crossbar 33 and one of the surfaces of the bimetal 34 facing the crossbar 33 . It can be defined as information about the gap between one side.

The second gap result information G2 may be defined as information on an optimal distance between the crossbar 33 and the end of the pressing member 35 . That is, again referring to FIG. 5 , the second interval result information G2 is defined as information on the interval between the one end of the pressing member 35 and the one surface or one corner of the crossbar 33 . can

The third interval result information G3 may be defined as information on an optimal distance between the bimetal 34 and the crossbar 33 . That is, again referring to FIG. 5 , the third interval result information G3 may be defined as information on the interval between the one surface of the bimetal 34 and the one surface or the one corner of the crossbar 33 . .

Accordingly, it will be understood that the sum of the first interval result information G1 and the second interval result information G2 is equal to the third interval result information G3.

The interval result information calculated by the interval result information operation module 410 is transmitted to the database unit 500 . The interval result information calculation module 410 and the database unit 500 are energably connected.

The database unit 500 stores the collected test information and the calculated test result information. The stored test information and test result information may be utilized as background data for the manufacturing unit 20 to manufacture the circuit breaker 30 for actual wiring.

In addition, the database unit 500 stores the image information collected in the actual manufacturing process of the circuit breaker 30 for wiring and the manufacturing result information calculated using the same. The stored manufacturing result information may be utilized to correct previously stored test result information.

The database unit 500 is electrically connected to the test information collecting unit 100 and the test result information calculating unit 200 , respectively. The collected test information and the calculated test result information may be transmitted to the database unit 500 .

The database unit 500 is electrically connected to the circuit breaker manufacturing unit 300 and the manufacturing result information calculating unit 400 , respectively. The input manufacturing information and the calculated interval result information may be transmitted to the database unit 500 .

The database unit 500 may be provided in any form capable of inputting, calculating, storing, and outputting information. In an embodiment, the database unit 500 may be provided in the form of a central processing unit (CPU) including a hard disk, a micro SD card, an SSD, a flash memory, and the like, a microprocessor.

Each module (510, 520, 530) of the database unit 500 described below and each unit (511, 512, 513, 521, 522) included in each module (510, 520, 530) is energized with each other can be connected

In the illustrated embodiment, the database unit 500 includes a test result information storage module 510 , a result information storage module 520 , and an information comparison module 530 .

The test result information storage module 510 receives and stores the test information collected by the test information collection unit 100 . The test result information storage module 510 is electrically connected to the test information collection unit 100 .

The test result information storage module 510 receives and stores the test result information calculated by the test result information calculating unit 200 . The test result information storage module 510 is electrically connected to the test result information calculating unit 200 .

Each piece of information stored by the test result information storage module 510 may be utilized to calculate information for manufacturing the circuit breaker 30 for wiring according to the manufacturing information input by the information comparison module 530 . In addition, each piece of information stored by the test result information storage module 510 may be modified based on the information stored in the result information storage module 520 by the information comparison module 530 .

The test result information storage module 510 is electrically connected to the information comparison module 530 .

In the illustrated embodiment, the test result information storage module 510 includes an opening/closing mechanism information storage unit 511 , an interval information storage unit 512 , and a speed information storage unit 513 .

The opening/closing mechanism information storage unit 511 receives and stores the opening/closing mechanism information collected by the opening/closing mechanism information collection module 110 . The opening/closing mechanism information storage unit 511 is electrically connected to the opening/closing mechanism information collection module 110 .

As described above, the opening/closing mechanism information includes load information and distance information. Accordingly, it will be understood that the opening/closing mechanism information stored in the opening/closing mechanism information storage unit 511 may also include load information and distance information.

The opening/closing mechanism information is mapped and stored with the corresponding interval information. Accordingly, the opening/closing mechanism information stored in the opening/closing mechanism information storage unit 511 may be utilized as key data for identifying the circuit breaker 30, which is an actual manufacturing target.

The interval information storage unit 512 receives and stores the interval information calculated by the interval information calculation module 210 of the test result information calculation unit 200 . The interval information storage unit 512 is electrically connected to the interval information calculation module 210 .

As described above, the interval information may be divided into the first interval information G1, the second interval information G2, and the third interval information G3. Accordingly, the interval information stored in the interval information storage unit 512 may also be divided into the first interval information G1 , the second interval information G2 , and the third interval information G3 .

The interval information storage unit 512 may store the received interval information by mapping it with time. That is, the interval information stored in the interval information storage unit 512 may be in a form in which interval information at a specific time point is continuously stored according to the passage of time.

The interval information storage unit 512 may store the received interval information by mapping it with corresponding opening/closing mechanism information.

The speed information storage unit 513 receives and stores the speed information calculated by the speed information calculation module 220 of the test result information calculation unit 200 . The speed information storage unit 513 is electrically connected to the speed information calculation module 220 .

The speed information storage unit 513 may store the received speed information by mapping it with the corresponding opening/closing mechanism information.

The result information storage module 520 receives and stores the manufacturing information input to the circuit breaker manufacturing unit 300 . The result information storage module 520 is electrically connected to the circuit breaker manufacturing unit 300 .

The result information storage module 520 receives and stores the production result information calculated by the production result information calculating unit 400 . The result information storage module 520 is electrically connected to the production result information calculation unit 400 .

The result information storage module 520 is electrically connected to the information comparison module 530 . The result information stored in the result information storage module 520 may be used as basis data for the information comparison module 530 to correct the test information stored in the test result information storage module 510 .

In the illustrated embodiment, the result information storage module 520 includes an opening/closing mechanism manufacturing information storage unit 521 and an interval result information storage unit 522 .

The opening/closing mechanism manufacturing information storage unit 521 receives and stores the opening/closing mechanism manufacturing information input to the manufacturing information input module 310 . The opening/closing mechanism manufacturing information storage unit 521 is electrically connected to the manufacturing information input module 310 .

As described above, the opening/closing mechanism manufacturing information may include load information and distance information. Accordingly, it will be understood that the opening/closing mechanism manufacturing information stored in the opening/closing mechanism manufacturing information storage unit 521 may also include load information and distance information.

The opening/closing mechanism manufacturing information stored in the opening/closing mechanism manufacturing information storage unit 521 may be utilized as key data for identifying the actually manufactured circuit breaker 30 for wiring.

That is, the stored opening/closing mechanism manufacturing information is compared and matched with the opening/closing mechanism information stored in the opening/closing mechanism information storage unit 511 by the information comparison module 530 . Accordingly, interval information corresponding to the corresponding opening/closing mechanism manufacturing information may be selected and transmitted to the interval adjusting module 320 .

The interval result information storage unit 522 receives and stores the interval result information calculated by the interval result information calculation module 410 of the production result information calculation unit 400 . The interval result information storage unit 522 is electrically connected to the interval result information operation module 410 .

As described above, the interval result information may be divided into the first interval result information G1, the second interval result information G2, and the third interval result information G3. Accordingly, the interval result information stored in the interval result information storage unit 522 may also be divided into the first interval result information G1 , the second interval result information G2 , and the third interval result information G3 .

Also, the interval result information storage unit 522 may store the received interval result information by mapping it with a corresponding time. That is, the interval result information stored in the interval result information storage unit 522 may be in a form in which interval result information at a specific time point is continuously stored over time.

The information comparison module 530 matches the input manufacturing information and the stored test result information. The information comparison module 530 transmits the interval information corresponding to the input production information to the interval adjustment module 320 .

Also, the information comparison module 530 compares the result information stored in the result information storage module 520 with the test result information stored in the test result information storage module 510 . As a result of the comparison, when the result information and the test result information are different from each other, the information comparison module 530 corrects the test result information based on the result information.

The information comparison module 530 may access and modify each piece of information stored in the test result information storage module 510 . The information comparison module 530 is electrically connected to the test result information storage module 510 .

The information comparison module 530 may access each result information stored in the result information storage module 520 . The information comparison module 530 is electrically connected to the result information storage module 520 .

This is because the test result information stored in the test result information storage module 510 is a simulation result, and the result information stored in the result information storage module 520 is information collected during actual production.

Accordingly, in the circuit breaker manufacturing system 1 according to an embodiment of the present invention, the relative positions of the crossbar 33 , the bimetal 34 , and the pressing member 35 can be determined without a process of applying an overcurrent in advance.

In addition, based on the result information collected in the process of actually manufacturing the circuit breaker 30 for wiring according to the determined position, test result information, which is a result of simulation manufacturing, may be continuously modified.

Accordingly, the actual manufacturing process of the circuit breaker 30 for wiring may be simplified, and the reliability and accuracy of the underlying data (ie, test result information) for this may be improved.

(3) Description of the circuit breaker (30) for wiring

Referring back to FIG. 3 , a circuit breaker 30 for wiring according to an embodiment of the present invention is illustrated.

In the illustrated embodiment, the circuit breaker 30 for wiring includes a frame 31 , an opening/closing mechanism part 32 , a cross bar 33 , a bimetal 34 , and a pressing member 35 .

The frame 31 forms the outer shape of the circuit breaker 30 for wiring. A space is formed inside the frame 31 , and various components for operating the circuit breaker 30 for wiring may be mounted.

In the illustrated embodiment, the opening and closing mechanism 32 and the crossbar 33 are rotatably coupled to the frame 31 . In addition, the bimetal 34 and the pressing member 35 are accommodated in the inner space of the frame 31 .

The opening/closing mechanism part 32 is rotationally moved by rotation of the crossbar 33 . By rotation of the opening/closing mechanism part 32, the fixed contact (not shown) and the movable contact (not shown) that were in contact are spaced apart, and the circuit breaker 30 for wiring and an external power source or load are cut off.

A crossbar 33 is positioned adjacent to the opening/closing mechanism 32 . The crossbar 33 is rotatably coupled to the frame 31 . When the crossbar 33 is rotated, the opening/closing mechanism part 32 is pressed or pressed. Accordingly, the opening/closing mechanism part 32 may be rotated to perform a trip operation.

A bimetal 34 is positioned adjacent to the crossbar 33 . The bimetal 34 may be formed of a plurality of metal materials having different coefficients of thermal expansion.

A heater 36 is located adjacent to the bimetal 34 . The heater 36 is energized with the outside. Heat generated by applying an overcurrent to the heater 36 is transferred to the bimetal 34 , and the bimetal 34 is curved toward the crossbar 33 .

A plurality of bimetals 34 may be provided. In the illustrated embodiment, three bimetals 34 are provided, including a first bimetal 34a, a second bimetal 34b, and a third bimetal 34c. The number of bimetals 34 may be changed according to the number of phases of the current passed through the circuit breaker 30 for wiring.

A pressing member 35 is coupled to the bimetal 34 . The pressing member 35 is moved together with the bimetal 34 . When the bimetal 34 is bent toward the crossbar 33 , the pressing member 35 is also moved toward the crossbar 33 together to press the crossbar 33 . Accordingly, the crossbar 33 is rotated and as a result a trip operation can be performed.

A plurality of pressing members 35 may be provided. The plurality of pressing members 35 may be respectively coupled to each of the plurality of bimetals 34 . In one embodiment, the pressing member 35 may be provided as a rivet member.

The circuit breaker manufacturing system 1 according to an embodiment of the present invention may collect test data in advance and utilize the collected data for actual manufacturing of the circuit breaker 30 for wiring.

Accordingly, the conditions for the trip operation to be performed (that is, the magnitude of the overcurrent and the energization time) can be accurately and easily adjusted. In addition, the reliability of the trip operation can also be improved.

The first gap information G1, the second gap information G2, and the third gap information G3, which are the gaps between the crossbar 33, the bimetal 34 and the pressing member 35, are adjusted to achieve the above effect As described above.

3. Description of the control method of the circuit breaker manufacturing system (1) according to an embodiment of the present invention

The control method of the circuit breaker manufacturing system 1 according to an embodiment of the present invention may be performed through the above-described configuration.

In particular, in the circuit breaker manufacturing system 1 for wiring according to an embodiment of the present invention, the bimetal 34 is bent by applying a current during the trial manufacturing process, and then, in the actual manufacturing process, the bimetal 34 and pressure are applied without a separate current passing process. The relative positional relationship of the members 35 can be precisely adjusted.

Hereinafter, a control method of the circuit breaker manufacturing system 1 for wiring according to an embodiment of the present invention will be described in detail with reference to FIGS. 7 to 14 .

In the embodiment shown in FIG. 7 , the control method of the circuit breaker manufacturing system 1 for wiring includes the steps of the simulation unit 10 collecting test information related to the trial manufacturing of the wiring breaker 30 ( S100 ), the simulation unit 10 . ) calculating test result information using the collected test information (S200), the database unit 500 storing the collected test information and the calculated test result information (S300), the manufacturing unit 20 is stored Step (S400) of manufacturing the circuit breaker 30 for wiring according to the test information and the test result information, between the pressing member 35 and the bimetal 34 of the circuit breaker 30 for which the interval result information calculation module 410 is manufactured Calculating the interval result information, which is information about the optimal distance between the pressing member 35 and the bimetal 34 of the circuit breaker 30 for wiring manufactured by the manufacturing unit 20 by using the image information about the distance (S500) , the database unit 500 stores the input opening/closing mechanism unit manufacturing information and the calculated interval result information (S600) and the information comparison module 530 compares the stored test result information and the stored result information, and in the stored result information and correcting the stored test result information according to (S700).

(1) Description of the step (S100) in which the simulation unit 10 collects test information related to the test manufacturing of the circuit breaker 30 for wiring

It is a step (S100) in which the test information collection unit 100 of the simulation unit 10 collects test information related to the trial manufacturing or trial manufacturing of the circuit breaker 30 for wiring. The collected test information is transmitted to the test result information calculating unit 200 and used as basis data for calculating the test result information.

Hereinafter, this step ( S100 ) will be described in detail with reference to FIG. 8 .

First, the opening/closing mechanism information collection module 110 collects test information of the opening/closing mechanism 32 provided in the circuit breaker 30 for wiring (S110).

As described above, the opening/closing mechanism information collection module 110 includes a load information collection unit 111 and a distance information collection unit 112 . Accordingly, the opening/closing mechanism information collection module 110 may collect both load information and distance information of the opening/closing mechanism unit 32 .

The current application module 120 applies a current to the circuit breaker 30 for wiring (S120). That is, the current application module 120 applies a current for bending the bimetal 34 to the bimetal 34 .

The image information collection module 130 collects image information on the position of the bimetal 34 ( S130 ).

That is, when the heat generated by the heater 36 is transferred by the applied current to heat the bimetal 34 , the bimetal 34 is curved toward the crossbar 33 .

At this time, the image information collection module 130 is located at the position of the bimetal 34 and the pressing member 35 from the time when the bimetal 34 starts to curve when a current is applied until the curve of the bimetal 34 is completed. collect video information about

The opening/closing mechanism information and image information collected by the test information collecting unit 100 are transmitted to the test result information calculating unit 200 and the database unit 500 , respectively. The test information collecting unit 100 is electrically connected to the test result information calculating unit 200 and the database unit 500 , respectively.

(2) Description of the step (S200) in which the simulation unit 10 calculates test result information using the collected test information

It is a step (S200) in which the test result information calculating unit 200 of the simulation unit 10 calculates test result information using the collected test information. The calculated test result information is transmitted to and stored in the database unit 500 .

The stored test result information is used as basis data for the manufacturing unit 20 to adjust the gap between the pressing member 35 and the bimetal 34 . In addition, the stored test result information may be accumulated and used as big data to improve the accuracy of manufacturing the circuit breaker 30 for wiring.

Hereinafter, this step ( S200 ) will be described in detail with reference to FIG. 9 .

First, the interval information calculation module 210 calculates interval information using the collected test information, that is, image information (S210).

As described above, the interval information calculated by the interval information calculation module 210 may be divided into the first interval information G1, the second interval information G2, and the third interval information G3.

In this case, the interval information calculation module 210 may calculate the first interval information G1 , the second interval information G2 , and the third interval information G3 according to time. That is, the interval information calculated by the interval information calculation module 210 may reflect the position of the bimetal 34 according to current conduction and interruption in real time.

The first to third interval information G1 , G2 , and G3 calculated by the interval information calculation module 210 are transmitted to the database unit 500 . The interval information calculation module 210 and the database unit 500 are electrically connected.

Next, the speed information calculation module 220 calculates speed information using the collected test information, that is, image information and time information (S220).

The speed information calculated by the speed information calculation module 220 may be calculated based on the calculated interval information.

Specifically, the speed information calculation module 220 uses the amount of change of the third interval information G3 while the current is energized and the bimetal 34 is curved toward the crossbar 33 to obtain the speed information of the bimetal 34 . Calculate.

The calculated speed information may be utilized to adjust the relative positions of the bimetal 34 and the pressing member 35 .

The speed information calculated by the speed information calculation module 220 is transmitted to the database unit 500 . The speed information calculation module 220 and the database unit 500 are electrically connected.

(3) Description of the step (S300) of the database unit 500 storing the collected test information and the calculated test result information

The database unit 500 receives the collected test information and the calculated test result information, and stores it (S300). The test information and test result information stored in the database unit 500 are used as background data when the manufacturing unit 20 actually manufactures the circuit breaker 30 for wiring.

Hereinafter, this step ( S300 ) will be described in detail with reference to FIG. 10 .

The test result information storage module 510 of the database unit 500 , specifically, the opening/closing mechanism information storage unit 511 stores the collected load information or distance information of the opening/closing mechanism unit 32 ( S310 ).

As described above, the opening/closing mechanism information includes load information and distance information. Accordingly, information stored in the opening/closing mechanism information storage unit 511 may also include load information and distance information.

Accordingly, the step (S310) is a step (S311) of the opening and closing mechanism information storage unit 511 storing the collected load information and a step (S312) of the opening and closing mechanism information storage unit 511 storing the collected distance information (S312). can be distinguished.

The test result information storage module 510 of the database unit 500, specifically the interval information storage unit 512, stores the interval information calculated by the interval information calculation module 210 (S320).

The stored interval information may be divided into first to third interval information G1, G2, and G3. In addition, the first to third interval information G1 , G2 , and G3 may be classified and accumulated and stored according to a time when image information serving as a basis thereof is acquired.

The test result information storage module 510 of the database unit 500, specifically, the speed information storage unit 513 stores the speed information calculated by the speed information calculation module 220 (S330).

(4) Description of the step (S400) of manufacturing the circuit breaker 30 for wiring according to the test information and test result information stored by the manufacturing unit 20

It is a step (S400) of the manufacturing unit 20 manufacturing the circuit breaker 30 for wiring according to the test information stored in the database unit 500, the test result information, and the input opening/closing mechanism unit manufacturing information.

Hereinafter, this step ( S400 ) will be described in detail with reference to FIG. 11 .

The manufacturing information input module 310 of the circuit breaker manufacturing unit 300 receives the opening and closing mechanism manufacturing information for the specification of the opening and closing mechanism unit 32 of the circuit breaker 30 for wiring (S410).

The input opening/closing mechanism unit manufacturing information may include load information or distance information of the opening/closing mechanism unit 32 .

The manufacturing information input module 310 matches the input opening/closing mechanism manufacturing information with the test information stored in the test result information storage module 510 of the database unit 500 (S420).

Specifically, the manufacturing information input module 310 matches the opening/closing mechanism information matching the input opening/closing mechanism manufacturing information among the plurality of opening/closing mechanism information stored in the opening/closing mechanism information storage unit 511 .

As described above, the process may be performed by the information comparison module 530 of the database unit 500 .

When the input opening/closing mechanism unit manufacturing information matches any one of a plurality of pre-stored opening/closing mechanism unit information, interval information according to the matched opening/closing mechanism unit information may be calculated. The calculated interval information is transmitted to the interval adjustment module 320 .

The gap adjustment module 320 adjusts the distance between the pressing member 35 and the bimetal 34 provided in the circuit breaker 30 for wiring according to the calculated gap information (ie, the calculated gap information) (S430).

In this case, the above process may be performed in a state in which the bimetal 34 is curved by the current applied from the simulation unit 10 . That is, since the relative positions of the crossbar 33 , the bimetal 34 , and the pressing member 35 are determined through the above-described process, a cooling process for returning the bimetal 34 to its pre-curved state is not required.

When the position of the pressing member 35 is adjusted, the welding module 330 couples the pressing member 35 and the bimetal 34 ( S440 ). In an embodiment, the welding module 330 may weld the pressing member 35 and the bimetal 34 between the pressing member 35 and the bimetal 34 to combine the pressing member 35 and the bimetal 34 .

The image information collection module 340 collects image information on the relative position between the coupled pressing member 35 and the bimetal 34 , that is, the distance between the pressing member 35 and the bimetal 34 ( S450 ).

In this case, the image information collected by the image information collection module 340 may be image information about a state in which the bimetal 34 is not curved.

Before the above process, the bonding module 350 bonds the welding portion between the pressing member 35 and the bimetal 34, and the test module 360 applies an electric current to the bimetal 34 for the purpose of the test to bend the bimetal 34. can be performed.

In the above embodiment, the image information collection module 340 may collect image information in a state in which the bimetal 34 that has been bent by the current applied by the test module 360 is restored to its initial state.

(5) A circuit breaker for wiring manufactured by the manufacturing unit 20 using image information about the distance between the pressing member 35 and the bimetal 34 of the circuit breaker 30 for which the interval result information calculation module 410 is manufactured Description of the step (S500) of calculating the interval result information, which is information about the optimal distance between the pressing member 35 and the bimetal 34 of (30)

By using the image information on the distance between the pressing member 35 and the bimetal 34 provided in the circuit breaker 30 for wiring that the manufacturing result information calculation unit 400 has a gap result information calculation module 410 that has been manufactured, it is manufactured It is a step (S500) of calculating the interval result information, which is information on the optimal distance between the pressing member 35 and the bimetal 34 of the circuit breaker 30 for wiring.

Hereinafter, this step ( S500 ) will be described in detail with reference to FIG. 12 .

The interval result information calculation module 410 of the manufacturing result information calculation unit 400 uses the image information on the distance between the pressing member 35 and the bimetal 34 to be between the pressing member 35 and the bimetal 34 . Interval result information, which is information about the optimal distance, is calculated (S510).

That is, the interval result information calculation module 410 calculates interval information on the manufacturing result of the circuit breaker 30 for wiring.

The interval result information operation module 410 transmits the calculated interval result information to the result information storage module 520 of the database unit 500 (S520). The transmitted interval result information is stored in the interval result information storage unit 522 of the result information storage module 520 .

(6) Description of the step (S600) of the database unit 500 storing the input opening and closing mechanism unit manufacturing information and the calculated interval result information

It is a step (S600) of the database unit 500 storing the opening and closing mechanism unit manufacturing information input to the circuit breaker manufacturing unit 300 and the interval result information calculated by the manufacturing result information calculating unit 400 ( S600 ).

Hereinafter, this step ( S600 ) will be described in detail with reference to FIG. 13 .

The opening/closing mechanism manufacturing information storage unit 521 provided in the result information storage module 520 of the database unit 500 receives and stores the manufacturing information input to the manufacturing information input module 310 ( S610 ). The opening/closing mechanism manufacturing information storage unit 521 is electrically connected to the manufacturing information input module 310 .

The stored opening/closing mechanism manufacturing information is matched with the opening/closing mechanism information stored in the opening/closing mechanism information storage unit 511 of the test result information storage module 510 to function as key data for identifying the interval information.

In addition, the interval result information storage unit 522 provided in the result information storage module 520 of the database unit 500 receives and stores the interval result information calculated by the interval result information calculation module 410 ( S620 ). The interval result information storage unit 522 is electrically connected to the interval result information operation module 410 .

The stored interval result information is used as basis data for the information comparison module 530 to correct the interval information stored in the interval information storage unit 512 of the test result information storage module 510 .

(8) Description of the step (S700) of the information comparison module 530 comparing the stored test result information and the stored result information, and correcting the stored test result information according to the stored result information

The information comparison module 530 of the database unit 500 compares the test result information stored in the test result information storage module 510 with the result information stored in the result information storage module 520 , and the test result information storage module 510 . It is a step of correcting or correcting the test result information stored in (S700).

Hereinafter, this step ( S700 ) will be described in detail with reference to FIG. 14 .

First, the information comparison module 530 compares the opening and closing mechanism manufacturing information stored in the opening and closing mechanism manufacturing information storage unit 521 of the result information storage module 520 to the opening and closing mechanism information storage unit 511 of the test result information storage module 510 . ) is matched with the plurality of opening and closing mechanism information stored in (S710).

In this case, the opening/closing mechanism part manufacturing information is information on the opening/closing mechanism part 32 of the circuit breaker 30 for wiring manufactured in the process through the above-described process. In addition, the opening/closing mechanism information is information about the opening/closing mechanism unit 32 of the circuit breaker 30 for wiring tested and manufactured in the previous process and the process through the above-described process.

That is, the information comparison module 530 matches the opening/closing mechanism part manufacturing information of the circuit breaker 30 for wiring manufactured in this process with the pre-stored opening/closing mechanism part information.

Accordingly, the information comparison module 530 may identify which of the circuit breaker 30 for wiring manufactured in the process corresponds to which of the circuit breaker 30 for wiring of various standards.

When the opening/closing mechanism manufacturing information matches any one of the plurality of opening/closing mechanism information, the information comparison module 530 compares the stored interval result information with the stored interval information (S720).

As described above, the plurality of opening/closing mechanism information is stored by being mapped to a plurality of interval information, respectively. That is, any one opening/closing mechanism unit information matching the opening/closing mechanism unit manufacturing information among the plurality of opening/closing mechanism unit information is mapped to any one interval information among the plurality of interval information.

Similarly, the opening/closing mechanism manufacturing information is also mapped and stored with the opening/closing mechanism manufacturing information of the manufactured circuit breaker 30 for wiring.

Accordingly, as the opening/closing mechanism manufacturing information and the opening/closing mechanism information are matched, the interval result information and the interval information may also be matched. The information comparison module 530 compares the matched interval result information with the interval information.

When the stored interval result information and the stored interval information are different, the information comparison module 730 corrects the stored interval information according to the stored interval result information (S730).

That is, the information comparison module 730 compares the matched interval result information with the interval information, and if there is a difference, corrects the interval information based on the interval result information.

This is, the interval information is information collected during the test manufacturing process of the circuit breaker 30 for wiring by the simulation unit 10, and the interval result information is collected as a result of the actual manufacturing of the circuit breaker 30 for wiring by the manufacturing unit 20 due to information.

That is, the information comparison module 730 corrects the test data based on the actual data. Accordingly, the interval information stored in the test result information storage module 510 may more accurately reflect the state of the actually manufactured circuit breaker 30 .

As described above, according to the circuit breaker manufacturing system 1 and the control method thereof according to the present embodiment, the relative positions between the crossbar 33 , the bimetal 34 , and the pressing member 35 without passing current during the manufacturing process. can be adjusted.

In addition, the test result information collected through the simulation, that is, the trial manufacturing process, may be utilized in the actual manufacturing of the circuit breaker 30 for wiring. The collected test result information is accumulated and stored in the database unit 500, so that reliability of data can be improved.

Furthermore, since the test result information stored in the database unit 500 is continuously modified using the result information collected in the actual manufacturing process, the reliability and accuracy of the test result information can be improved.

Although the above has been described with reference to the preferred embodiment of the present invention, those of ordinary skill in the art can variously modify and change the present invention within the scope without departing from the spirit and scope of the present invention described in the claims below. You will understand that you can.

1: Circuit breaker manufacturing system for wiring
10: simulation unit
20: Production Department
30: circuit breaker for wiring
31: frame
32: opening and closing mechanism
33: crossbar
34: bimetal (bimetal)
34a: first bimetal
34b: second bimetal
34c: third bimetal
35: pressure member
36: heater
100: test information collection unit
110: opening and closing mechanism information collection module
111: load information collection unit
112: distance information collection unit
120: current application module
130: image information collection module
200: test result information calculation unit
210: interval information calculation module
220: speed information calculation module
300: circuit breaker manufacturing unit
310: production information input module
320: gap adjustment module
330: welding module
340: image information collection module
350: adhesive module
360: test module
400: production result information calculation unit
410: interval result information operation module
500: database unit
510: test result information storage module
511: opening and closing mechanism information storage unit
512: interval information storage unit
513: speed information storage unit
520: result information storage module
521: opening and closing mechanism manufacturing information storage unit
522: interval result information storage unit
530: information comparison module
1000: circuit breaker for wiring according to the prior art
1100: bimetal according to the prior art
1200: rivets according to the prior art
1300: crossbar according to the prior art
G1: first interval (result) information
G2: 2nd interval (result) information
G3: 3rd interval (result) information

Claims (22)

a simulation unit that calculates test result information related to the test manufacturing of a circuit breaker; and
and a manufacturing unit for manufacturing the circuit breaker using the test result information calculated in the simulation unit,
The circuit breaker for wiring,
a crossbar provided to be movable;
a bimetal positioned spaced apart from the crossbar and curved in a direction toward the crossbar by receiving a current; and
and a pressing member coupled to the bimetal and moving toward the crossbar together with the bimetal to press the crossbar,
The test result information is
Including spacing information, which is information about the optimal distance between the end of the pressing member and the bimetal,
Circuit breaker manufacturing system for wiring. According to claim 1,
The simulation unit,
a current application module connected to the circuit breaker to be energized and applying the current to the circuit breaker for a preset time; and
and an image information collection module that collects image information on the position of the bimetal that is curved toward the crossbar by the heat generated by the electric current,
Circuit breaker manufacturing system for wiring. 3. The method of claim 2,
The simulation unit,
an interval information calculation module for calculating the interval information using the collected image information; and
and a speed information calculation module for calculating speed information on the speed at which the bimetal is bent by using the interval information and the preset time,
Circuit breaker manufacturing system for wiring. 4. The method of claim 3,
Further comprising a database unit operably connected to the simulation unit to store the test result information calculated by the simulation unit,
The database unit,
an interval information storage unit for storing the calculated interval information; and
a speed information calculation unit for storing the calculated speed information;
Circuit breaker manufacturing system for wiring. According to claim 1,
The circuit breaker for wiring,
and an opening/closing mechanism to which the crossbar is connected and rotated by rotation of the crossbar;
The simulation unit,
and an opening/closing mechanism information collection module configured to sense one or more information of load information on the load of the opening/closing mechanism and distance information on a rotation distance of the crossbar according to rotation of the opening/closing mechanism;
Circuit breaker manufacturing system for wiring. According to claim 1,
The circuit breaker for wiring,
and an opening/closing mechanism to which the crossbar is connected and rotated by rotation of the crossbar;
The production unit,
and a manufacturing information input module for receiving the opening and closing mechanism manufacturing information for the load of the opening and closing mechanism and the rotation distance of the crossbar;
Circuit breaker manufacturing system for wiring. 7. The method of claim 6,
The production unit,
a spacing adjusting module for adjusting an optimal distance between the end of the pressing member and the bimetal according to the calculated test result information; and
Containing a welding module for welding the pressing member and the bimetal,
Circuit breaker manufacturing system for wiring. 8. The method of claim 7,
The production unit,
Including an image information collection module for detecting image information about the position of the welding pressing member and the bimetal,
Circuit breaker manufacturing system for wiring. 9. The method of claim 8,
The production unit,
and an interval result information calculation module for calculating interval result information for the shortest distance between the bimetal and the end of the pressing member coupled using the collected image information,
Circuit breaker manufacturing system for wiring. 10. The method of claim 9,
Further comprising a database unit connected to the energization with the manufacturing unit, storing the interval result information calculated by the manufacturing unit,
The database unit,
an opening/closing mechanism manufacturing information storage unit configured to store the inputted opening/closing mechanism manufacturing information; and
an interval result information storage unit for storing the calculated interval result information;
Circuit breaker manufacturing system for wiring. 11. The method of claim 10,
The database unit,
Comprising an information comparison module comparing the interval information calculated by the simulation unit with the interval result information, and correcting the interval information calculated according to the interval result information,
Circuit breaker manufacturing system for wiring. (a) collecting test information related to the test manufacturing of the circuit breaker by the simulation unit;
(b) calculating test result information using the test information collected by the simulation unit;
(c) storing the collected test information and the calculated test result information in a database unit; and
(d) manufacturing the circuit breaker for wiring according to the stored test information and the test result information,
The test information is
It is provided in the circuit breaker and includes image information on the position of the bimetal that is curved toward the crossbar by the heat generated by the application of current,
The test result information is
Including interval information, which is information about the optimal distance between the pressure member of the test-manufactured circuit breaker and the bimetal,
Control method of circuit breaker manufacturing system for wiring. 13. The method of claim 12,
The step (a) is,
(a1) collecting, by an opening/closing mechanism information collection module, load information on the load of the opening/closing mechanism and distance information on the rotation distance of the crossbar according to the rotation of the opening/closing mechanism; and
(a2) comprising the step of collecting the image information of the bimetal by an image information collection module,
Control method of circuit breaker manufacturing system for wiring. 13. The method of claim 12,
The step (b) is,
(b1) calculating, by an interval information calculation module, the interval information using the collected image information; and
(b2) the speed information calculation module comprising the step of calculating speed information using the calculated interval information and preset time information, which is a time when a current is applied to the circuit breaker,
Control method of circuit breaker manufacturing system for wiring. 13. The method of claim 12,
Step (c) is,
(c1) storing, by the opening/closing mechanism information storage unit, load information or distance information of the opening/closing mechanism unit; and
(c2) the interval information storage module comprising the step of storing the calculated interval information,
Control method of circuit breaker manufacturing system for wiring. 13. The method of claim 12,
Step (d) is,
(d1) receiving manufacturing information of the opening/closing mechanism part of the circuit breaker for wiring to which the manufacturing information input module is to be manufactured; and
(d2) including the step of matching the opening and closing mechanism part manufacturing information input by the manufacturing information input module with the test information stored in the database unit,
Control method of circuit breaker manufacturing system for wiring. 17. The method of claim 16,
Step (d) is,
After step (d2),
(d3) comprising the step of adjusting the distance between the bimetal and the pressing member provided in the circuit breaker according to the calculated gap information by the gap adjustment module,
Control method of circuit breaker manufacturing system for wiring. 18. The method of claim 17,
Step (d) is,
After step (d3),
(d4) welding the welding module to the pressing member and the bimetal; and
(d5) comprising the step of collecting image information on the distance between the bimetal and the pressing member to which the image information collection module is coupled,
Control method of circuit breaker manufacturing system for wiring. 13. The method of claim 12,
After step (d),
(e) the optimal distance between the pressing member and the bimetal of the circuit breaker for wiring manufactured by the manufacturing unit using image information on the distance between the bimetal and the pressing member of the circuit breaker for which the interval result information calculation module is manufactured Including the step of calculating interval result information that is information about,
Control method of circuit breaker manufacturing system for wiring. 20. The method of claim 19,
After step (e),
(f) the database unit comprising the step of storing the input opening and closing mechanism manufacturing information and the calculated interval result information,
Control method of circuit breaker manufacturing system for wiring. 21. The method of claim 20,
The step (f) is,
(f1) storing the opening/closing mechanism manufacturing information storage unit inputted with the opening/closing mechanism manufacturing information; and
(F2) an interval result information calculation unit comprising the step of storing the calculated interval result information,
Control method of circuit breaker manufacturing system for wiring. 21. The method of claim 20,
After step (f),
(g) comparing the stored test result information with the stored result information, by an information comparison module, and correcting the stored test result information according to the stored result information,
Control method of circuit breaker manufacturing system for wiring.

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