ES2443530T3 - Circuit breaker with temperature sensor - Google Patents

Abstract

An air circuit breaker composed of a base mold (110) provided inside a conduction unit (140) that constitutes a conduction circuit that connects a mobile contact point of a mobile contactor (142) and a point of stationary contact of a stationary contactor (144), a detection unit (120) that detects an accidental current and an opening / closing mechanism (130) that operates the mobile contactor (142) in response to a detection signal of the detection unit (120), the switch comprising a temperature sensor (150) for detecting a temperature and a temperature display (160), characterized by a nerve partition formed in the base mold to divide an internal space of the mold base for each power phase, and in which the temperature sensor (150) is fixedly inserted in a sensor insertion hole (115) formed in the nerve partition of the base mold (110), and in the that The temperature display (160) is adapted to indicate a value detected by the temperature sensor (150) as a temperature of the driving unit (140).

Description

Circuit breaker with temperature sensor

TECHNICAL FIELD

The following description generally refers to an air circuit breaker having a temperature sensor that can detect the temperature of an air circuit breaker by connecting a mobile contactor and a stationary contactor in order to prevent damage to the produced air circuit breaker. by abnormal heating of a conduction unit comprising a current conduction circuit.

PREVIOUS TECHNIQUE

Generally, a circuit breaker is an electrical protection device installed between an electrical source and charging units in order to protect the charging units, such as a motor and a transformer and an electric line, from an abnormal current (a large current produced by, ie, short circuit and a ground fault) generated in an electrical circuit such as a power transmission / distribution line and private power transformation facilities. In addition, the isolation insulated circuit breaker in a switch can manually open or close a power line under normal use, and open or close the line from a remote distance using an electric handling unit outside a metal container and automatically interrupt the line during overcurrent and short circuit to protect power installations and load units.

The air circuit breaker operates in such a way that a stationary contactor and a mobile contactor that is mobile to a closed position in which the mobile contactor contacts the stationary contactor to close the circuit and to an interrupted position ( obstacle) in which the mobile contactor separates from the stationary contactor to open the circuit.

The circuit breaker can be classified into an air circuit breaker, a hydraulic circuit breaker and a spring circuit breaker according to the handling procedure. The circuit breaker can also be classified into an air circuit breaker (ACB) to distinguish that they are blowing air, and a gas circuit breaker (GCB) to distinguish that they are blowing gas according to the means of extinction of the arc generated in the after the separation of the mobile contactor from the stationary contactor by manipulation of the switch.

FIG. 1 is a perspective view illustrating a schematic construction of a conventional air circuit breaker and FIG. 2 is a side view illustrating a schematic internal construction of the air circuit breaker.

With reference to FIG. 1 and 2, typical air circuit breakers may largely include a conduction unit (40) that constitutes a conduction circuit that connects a mobile contact point of a mobile contactor (42) and a stationary contact point of a stationary contactor (44), a base mold (10) provided with the conduction unit (40) inside, a detection unit (20) that detects an accidental current and an opening / closing mechanism (30) that the mobile contactor (42) operates in response to a detection signal from the detection unit (20). The air circuit breaker is mounted with a driving unit (40) for each phase, that is, a R phase driving unit (13), an S phase driving unit (14) and a driving unit T phase (15), as shown in FIG. one.

Now, the driving circuit of the air circuit breaker will be described with reference to FIG. 2. The stationary contactor (44) of the conduction unit (41) is connected to an upper terminal (46) by which the current is introduced into the switch, and the current introduced into the upper terminal (46) circulates at a lower terminal (47) by the mobile contactor (42). When the conduction circuit of the air circuit breaker is closed, current flows to the conduction unit (40) to increase the temperature of the air circuit breaker due to the heat generated from conductors that include the contact points.

When the temperature of the air circuit breaker increases, there is a high probability that the switch will operate erroneously due to the damage caused by the high temperature. As a result, IEC and KS (Korean standard) require that an increase in temperature of an air circuit breaker be limited, and a manufacturer makes a switch to meet the requirements of IEC or KS.

However, there are many cases in which the temperature of a switch rises due to abnormal heating of the driving unit (40), even if the air circuit breaker meets the requirements. When the air circuit breaker generates heat above the normal requirement, the switch itself is damaged and chaos in the power transmission / distribution line is planted because it stops interrupting the accidental current. Therefore, it is essential that the temperature of the conduction unit in the air circuit breaker is monitored in real time to prevent damage caused by abnormal heating.

One of the procedures for monitoring the temperature of the driving unit in the air circuit breaker is to measure the temperature by intermittently photographing an upper terminal and a lower terminal using an infrared thermal imaging camera from outside the air circuit breaker. However, this procedure suffers from the disadvantage that it is difficult to measure an internal temperature of the air circuit breaker, but an external temperature is measurable.

An installation of a temperature sensor to check the temperature of the conduction unit of the air circuit breaker can be considered a possible solution, but it is not so easy to install a temperature sensor in the upper terminal and the lower terminal where the current circulates , so that there has been no air circuit breaker mounted with a temperature sensor that can detect abnormal heating in real time.

EP-A1-1 107 274 discloses a circuit breaker with a current supply information measurement unit that includes contact templates for temperature detection, and the detected temperature is displayed by a display.

TECHNICAL SOLUTION

The present invention has been disclosed to solve the aforementioned disadvantages and it is an object of the present invention to provide an air circuit breaker having a temperature sensor that can monitor the temperature of the air circuit breaker at all times, thus preventing the damage of the air circuit breaker caused by abnormal heating of a driving unit that constitutes a driving circuit in which a mobile contactor and a stationary contactor are connected.

The foregoing and other objectives, features, aspects and advantages of the present invention will be more apparent from the following detailed description of the present invention when taken in conjunction with the accompanying drawings.

In a general aspect, an air circuit breaker is provided by the present invention as defined in the attached claim 1.

Implementations of this aspect may include one or more of the following features. The temperature sensor can be electrically connected to the temperature display via an external connector.

The air circuit breaker may additionally include an elastic member connected to the temperature sensor, so that the temperature sensor is fixedly inserted into a sensor insertion hole.

The temperature display may include an input terminal electrically connected to the temperature sensor, a compensation unit that compensates respectively the temperature of the mobile contactor of the driving unit, the temperature of the upper terminal connected to the stationary contactor of the driving unit and the temperature of the lower terminal connected to the mobile contactor based on the value detected by the temperature sensor, and a display indicating the respective compensated temperatures.

The temperature display can additionally include an output terminal to take out the value detected by the temperature sensor and the compensated temperatures.

The air circuit breaker may additionally include a warning device to notify the outside that the value detected by the temperature sensor has exceeded a predetermined reference temperature, if the value detected by the temperature sensor exceeds a predetermined reference temperature .

The warning device may include a temperature adjustment unit to adjust the reference temperature, an overheat detection unit to determine whether or not the value detected by the temperature sensor has exceeded the reference temperature set by the adjustment unit of temperature, and an overheating notification unit to notify that the value detected by the temperature sensor has exceeded the reference temperature as a result of the determination by the overheat detection unit that the value detected by the temperature sensor has exceeded the reference temperature.

The temperature adjustment unit is a DIP switch (dual line encapsulation, from Dual Inline Package) that can select a desired reference temperature level from reference temperature levels classified in various stages.

The overheating detection unit may include an analog-to-digital converter (ADC) that converts the value detected by the temperature sensor into a digital value, and the overheating notification unit may include a digital display that indicates the temperature converted to the value digital by the ADC.

The overheat detection unit can generate a control signal in response to the temperature converted to the digital value by the ADC, and the digital display can include a plurality of LEDs (Light Emitting Devices) to show the temperature turning the plurality of LEDs on and off in response to the control signal generated by the overheat detection unit.

The plurality of LEDs may include a group of 7-segment LED-based displays in which respective segments are turned on and off to display the digital numbers in response to the control signal of the overheat detection unit.

ADVANTAGE EFFECTS

The air circuit breaker having a temperature sensor according to the present invention can allow the temperature of the air circuit breaker to be monitored at all times by means of the temperature sensor and temperature display, thus preventing damage to it caused by heating abnormal of a driving unit that constitutes a driving circuit and that prevents an accidental current caused by an erroneous operation of the air circuit breaker.

The warning device can immediately notify a user of a fault when the temperature detected by the temperature sensor has exceeded the reference temperature in order to allow the user to deal with the accidental situation.

The user can be allowed to adjust the reference temperature based on the current temperature in response to the load and accurately check the state of the air circuit breaker at all times.

As a result, the air circuit breaker can protect electrical systems from overload produced by overcurrent that exceeds a critical value, protect the user from the risk of fire caused by overheating inside the air circuit breaker and prolong the life of the circuit breaker. air stably using the switch.

DESCRIPTION OF THE DRAWINGS

FIG. 1 is a perspective view illustrating a schematic configuration of a conventional air circuit breaker. FIG. 2 is a side view illustrating a schematic internal configuration of the air circuit breaker of FIG. 1. FIG. 3 is a perspective view illustrating a schematic configuration of an air circuit breaker having a temperature sensor according to an exemplary implementation. FIG. 4 is a schematic configuration of a temperature sensor according to an exemplary implementation. FIG. 5 is a perspective view illustrating a state of the temperature sensor that is coupled to an elastic member according to an exemplary implementation. FIG. 6 is a perspective view illustrating a front base mold formed with a sensor insertion hole for mounting a temperature sensor to the air circuit breaker according to an exemplary implementation. FIG. 7 is a perspective view illustrating a rear base mold coupled to the front base mold in FIG. 5. FIG. 8 is a side view schematically illustrating an air circuit breaker having a temperature sensor according to an exemplary implementation. FIG. 9 is a plan view illustrating a temperature display according to an example implementation. FIG. 10 is a schematic block diagram illustrating the configuration of a warning device according to an exemplary implementation. FIG. 11 is a plan view illustrating a temperature adjustment unit according to an exemplary implementation.

BEST MODE

The objective, the construction to achieve the objective and an operational effect of the air circuit breaker according to the present invention will be clearly understood by the following description of the implementations of the present invention made with reference to the attached drawings.

FIG. 3 is a perspective view illustrating a schematic configuration of an air circuit breaker having a temperature sensor according to an exemplary implementation, FIG. 4 is a schematic configuration of a temperature sensor according to an exemplary implementation, FIG. 5 is a perspective view illustrating a state of the temperature sensor that is coupled to an elastic member according to an exemplary implementation, FIG. 6 is a perspective view illustrating a front base mold formed with a sensor insertion hole for mounting a temperature sensor to the air circuit breaker according to an exemplary implementation, FIG. 7 is a perspective view illustrating a rear base mold coupled to the front base mold in FIG. 5, FIG. 8 is a side view schematically illustrating an air circuit breaker having a temperature sensor according to an exemplary implementation, FIG. 9 is a plan view illustrating a temperature display according to an exemplary implementation, FIG. 10 is a schematic block diagram illustrating the configuration of a warning device according to an exemplary implementation and FIG. 11 is a plan view illustrating a temperature adjustment unit according to an exemplary implementation.

First, the configuration of an air circuit breaker having a temperature sensor will be described. A base mold (110) may include a front base mold (112) and a rear base mold (117) and be provided inside a driving unit (140).

FIG. 6 refers to the front base mold (112) and FIG. 7 refers to the rear base mold (117). The base mold (110) is formed so that it has an internal space in places where each phase is located (phase R, S, T). The base mold (110) can be made of insulation material such as plastic and the like.

Each phase (phase R, phase S, phase T) of the 3 phase alternating current switch is provided with the conduction unit (140) as shown in FIG. 3.

The conduction unit (140) may include a mobile contactor (142) having a mobile contact point and a stationary contactor (144) having a stationary contact point as shown in FIG. 8. The stationary contactor (144) can be connected to an upper terminal (146) in which the current is introduced, and the mobile contactor (142) can be connected to a lower terminal (147) to constitute a conduction circuit.

A detection unit (120) may be provided on a front surface of the base mold (110) to detect an accidental current such as overcurrent or short-circuited current.

An opening / closing mechanism (130) is provided on a front surface of the base mold (110) to operate the mobile contactor (142) of the driving unit in response to a detection signal from the detection unit (120) .

A temperature sensor (150) may include a sensor unit (152) for measuring temperatures, an electric guidance line (154) extended from the sensor unit (152) and a connector (156) connected to the guidance line

(154) to access a temperature display (160), as illustrated in FIG. 4. Although the temperature sensor (150) can be directly connected to the temperature display (160), a connector (160) of the temperature sensor (150) is preferably connected to a connection terminal (172) of an external connector

(170) since the air circuit breaker is normally mounted with the external connector (170) as shown in FIG. 8. In other words, the external connector (170) is connected to an input terminal (162) of the temperature display (160) to allow the temperature sensor (150) and the temperature display

(160) are electrically connected.

The temperature sensor (150) can be arranged inside the air circuit breaker to measure the temperature of the driving unit (140). As it is difficult to directly measure the temperature of the driving unit (140), a nearby temperature that is considered as the temperature of the driving unit (140) can be measured. For this purpose, experimental data on the relationship between the temperature of the conduction unit (140) and a temperature where the temperature sensor (150) is installed can be obtained. As a result, the temperature where the temperature sensor (150) is located can be considered the temperature of the conduction unit (140) based on the experimental data.

The temperature sensor (150) in the three-phase air circuit breaker (R, S, T) can be installed in a base mold between phase R and phase S, and in a base mold between phase S and the T phase. This is because, as described above, a precise temperature cannot be measured due to the circulating air in the interior space if the temperature sensor (150) is arranged in the interior space since each base mold ( 110) has the interior space per phase. Therefore, as depicted in FIG. 6, two sensor insertion holes (115) insertable by the temperature sensor (150) can be formed in the first rib partition (113) of a front base mold formed between the R phase and the S phase and in a second Nerve partition (114) of the front base mold formed between phase S and phase T, and the temperature sensor (150) can be inserted into the two holes. The sensor insertion hole (115) can be formed deep enough to allow temperature measurement inside the switch. The sensor insertion hole (115) can be formed on an inlet side thereof with a guide groove (116) to prevent the electrical lines of the temperature sensor (150) from being interfered with other elements of the switch.

Preferably, the temperature sensor (150) can be formed such that a sensor unit (152) is inserted into a rubbery elastic member (158) to partially expose the elastic member (158) as shown in FIG. 5. The temperature sensor (150) coupled to the elastic member (158) can be fixedly inserted into the sensor insertion hole (115) as illustrated in FIG. 3 and 8.

The temperature display (160) electrically connected to the temperature sensor (150) is a device for displaying the measurement values by compensating the values for the temperature of the driving unit (140), so that a user can monitor the temperature inside of the real-time air circuit breaker.

With reference to FIG. 9, the temperature display (160) may include an input terminal (162) electrically connected to the temperature sensor (150), a compensator (not shown) that compensates the value measured by the temperature sensor (150) by the temperature of the driving unit and a display unit (164) showing the compensated temperature of the driving unit.

The compensator (not shown) can operate in such a way that the value measured by the temperature sensor (150) is considered the temperature of the driving unit using the experimental data. At this time, preferably, the values measured by the temperature sensor (150) are considered respectively the temperature of the mobile contactor (142) in the driving unit, the temperature of the upper terminal (146) and the temperature of the lower terminal and displayed on the display unit (164).

Preferably, the temperature display (160) may additionally include an output terminal to take the measured temperatures outside, whereby the internal temperature of the air circuit breaker can be monitored in real time from the site where the location is located. switch and also from a remote distance.

MODE FOR THE INVENTION

Meanwhile, with reference to FIG. 10, the air circuit switch having a temperature sensor may additionally include a warning device (200) that warns that the value detected by the temperature sensor (150) has exceeded a predetermined reference temperature if the detected value by the temperature sensor (150) it is higher than the predetermined reference temperature. The warning device (200) can comprise any structure, preferably in plural structure, to notify the imminent danger to users in real time and wirelessly notify a user at a remote site.

As shown in FIG. 9, the warning device (200) mounted together with the temperature display (160) can warn outside that the value detected by the temperature sensor (150) has exceeded a predetermined reference temperature if the value detected by the sensor Temperature (150) is higher than the default reference temperature, they can visually notify the user by way of an LED lamp

(167) and can audibly alert through a loudspeaker. The warning device (200) may include a temperature adjustment unit (210), an overheating detection unit (220) and an overheating notification unit (230), as illustrated in FIG. 10.

The temperature adjustment unit (210) can be manipulated by a user and set a reference temperature that compares with the values detected by the temperature sensor (150). In other words, the temperature adjustment unit (210) can select (turn on) number 1 of a DIP switch (dual line encapsulation, of the Dual Inline Package) in which the reference temperature level is classified as number 1 to number 4 per stage, and adjust the reference temperature by turning off the other numbers, as illustrated in FIG. 11. To be more specific, the temperature adjustment unit can select a desired reference temperature level from the reference temperature levels classified in various stages using the DIP switch.

The superheat detection unit (220) can determine whether or not the value detected by the temperature sensor (150) has exceeded the reference temperature set by the temperature adjustment unit (210). The superheat detection unit (220) may additionally include an ADC (analog-digital converter. 225) that converts an analog temperature value detected by the temperature sensor (150) into a digital value. Subsequently, the superheat detection unit (220) can determine whether or not the temperature digitally converted by the ADC (225) has exceeded the reference temperature set by the temperature adjustment unit (210).

The superheat detection unit (220) can generate a control signal in response to the temperature digitally converted by the ADC (225). The control signal can serve as a signal to control a digital display (described later. 235), in which the digital display (235) shows the temperature in response to the control signal.

As a result of the determination by the superheat detection unit (220), if the value detected by the temperature sensor (150) has exceeded the set reference temperature, the overheat notification unit (230) can notify the fact to the Exterior. The overheat notification unit

(230) may include a warning sound generator (not shown) that generates a warning sound, or a light on-off unit (not shown) that turns on or off a light to notify the user that the circuit breaker of air has overheated by the temperature inside the switch that has exceeded the set reference temperature.

The overheating notification unit (230) may additionally include a digital display (235), and the digital display (235) may display the temperature digitally converted by the ADC (225) of the overheating detection unit (220) to allow The user is informed of the temperature inside the air circuit breaker.

The digital display (235) can display the temperature using a single-color LED, a three-color LED or a group of 7-segment LED-based displays.

The digital display (235) mounted with the single-color LED, the tricolor LED or the group of 7-segment LED-based displays will now be described in detail.

The digital display (235) can be mounted with a plurality of single-color LEDs (red, green, including blue) and turn on or off a plurality of predetermined LEDs of the plurality of single-color LEDs in response to the signal of control generated by the overheat detection unit (220), or turn on or off the default color LED (red, green or blue) to display the temperature. The digital display (235) can have a tricolor LED and turn on or off a predetermined color LED of the tricolor LED in response to the control signal generated by the superheat detection unit (220) to display the temperature. Turning the default color on or off using the single-color LED or the tri-color LED in the description above is applicable to a case where colors are predefined by classifying temperatures by stage.

The digital display (235) can have at least one or more 7-segment LED-based displays, and turn on or off a relevant segment of the 7-segment LED-based display according to the control signal generated by the overheat detection unit (220) to show temperatures in digital numbers.

To be more specific, the digital display (235) can serve to notify the user of the precise status within the air circuit breaker, even if the warning sound generator or the light on-off unit of the notification unit overheating (230) stop working properly. The digital display (235) can notify the user of a current temperature inside the air circuit breaker to allow the user to set a reference temperature based on a temperature proportional to a volume of current load, if the user adjusts the temperature reference inside the air circuit breaker by means of the temperature adjustment unit (210).

INDUSTRIAL APPLICABILITY

The warning device (200) thus configured and mounted on the air circuit breaker can interrupt the power supply to charging systems when an overcurrent is generated that exceeds a critical value within the air circuit breaker, and monitor the temperature inside of the switch at all times to protect the user from dangerous fire, thus allowing the user to use the switch stably for a long time.

As the present concept can be implemented in several ways without departing from the spirit or essential characteristics thereof, it should also be understood that the implementations described above are not limited by any of the details of the above description, unless otherwise specified, but which must be interpreted widely within its scope as defined in the appended claims and, therefore, it is envisaged that all changes and modifications that are within the measures and limits of the claims, or, therefore, the equivalence of such measures and limits, are encompassed by the appended claims.

Claims (11)

1. An air circuit breaker composed of a base mold (110) provided inside a conduction unit (140) that constitutes a conduction circuit that connects a mobile contact point of a mobile contactor (142) and a stationary contact point of a stationary contactor (144), a detection unit (120) that detects an accidental current and an opening / closing mechanism (130) that operates the mobile contactor (142) in response to a detection signal of the detection unit (120), the switch comprising a temperature sensor (150) to detect a temperature and a temperature display (160), characterized by a nerve partition formed in the base mold to divide an internal space of the base mold for each power phase, and in which the temperature sensor (150) is fixedly inserted in a sensor insertion hole (115) formed in the nerve partition of the base mold (110), and in which the temperature display (160) is adapted to indicate a value detected by the temperature sensor (150) as a temperature of the unit of driving (140).

2.

 The switch according to claim 1, characterized in that the temperature sensor (150) is electrically connected to the temperature display (160) by means of an external connector (170).

3.

 The switch according to claim 1, further characterized by an elastic member (158) connected to the temperature sensor (150), so that the temperature sensor (150) is fixedly inserted in a sensor insertion hole (115) .

Four.

 The switch according to claim 1, characterized in that the temperature display (160) includes an input terminal electrically connected to the temperature sensor (150), a compensation unit that compensates respectively the temperature of the mobile contactor (142) of the control unit. conduction (140), the temperature of the upper terminal connected to the stationary contactor (144) of the conduction unit (140) and the temperature of the lower terminal connected to the mobile contactor (142) based on the value detected by the temperature sensor (150 ); and a display unit (164) indicating the respective compensated temperatures.

5.

 The switch according to claim 4, characterized in that the temperature display (160) additionally includes an output terminal for taking out the value detected by the temperature sensor (150) and the compensated temperatures.

6.

 The switch according to claim 1, further characterized by a warning device (200) for warning outside that the value detected by the temperature sensor (150) has exceeded a predetermined reference temperature, if the value detected by the sensor temperature (150) exceeds a predetermined reference temperature

7.

 The switch according to claim 6, characterized in that the warning device (200) includes a temperature adjustment unit (210) for adjusting the reference temperature, an overheating detection unit (220) determining whether the value detected by the sensor of temperature (150) has exceeded or not the reference temperature set by the temperature adjustment unit (210); and an overheating notification unit (230) to notify that the value detected by the temperature sensor (150) has exceeded the reference temperature as a result of the determination by the overheating detection unit

(230) that the value detected by the temperature sensor (150) has exceeded the reference temperature.

8.

The switch according to claim 7, characterized in that the temperature adjustment unit (210) is a DIP switch (dual line encapsulation, of the Dual Inline Package) which can select a desired reference temperature level from reference temperature levels classified in various stages.

9.

 The switch according to claim 7, characterized in that the overheating detection unit

(220) includes an analog-digital converter (ADC. 225) that converts the value detected by the temperature sensor (150) into a digital value, and the overheating notification unit (230) comprises a digital display (235) that indicates the temperature converted to the digital value by the ADC (225). 10. The switch according to claim 9, characterized in that the overheating detection unit (220) generates a control signal in response to the temperature converted to the digital value by the ADC (225), and the digital display (235) includes a plurality of LEDs (light emitting devices, from Light Emitting Devices) to show the temperature by turning the plurality of LEDs on and off in response to the control signal generated by the superheat detection unit (220). 11. A switch according to claim 10, characterized in that the plurality of LEDs includes a group of 7-segment LED-based displays in which respective segments are turned on and off to display digital numbers in response to the control signal of the overheat detection unit (220).