JP7070942B2 - Terminal overheat detector - Google Patents

Description

The present invention detects the temperature of the terminal portion of the circuit breaker to prevent the connected electric wire and the circuit breaker from burning and spreading the fire to the building materials and peripheral devices around the circuit breaker. Regarding the target terminal overheat detection device.

The circuit breaker detects an accidental current such as an overcurrent, a short-circuit current, or an electric leakage current in an electric circuit, and when a predetermined operating condition is met, the circuit breaker operates to cut off the supply of power to the load side.

The circuit breaker is provided with terminals at the terminals of each pole in order to make an electrical connection with electric wires and load devices. For circuit breakers built into distribution boards such as residential distribution boards and control boards, electric wires are drawn in at the construction site, the electric wires are caulked at the crimp terminals, and the crimp terminals are connected by crimp terminals to the circuit breakers. It is connected to the terminal by screw tightening. At this time, if the screw tightening connection between the crimp terminal and the terminal of the circuit breaker is insufficient, abnormal overheating may occur in the terminal while using the circuit breaker.

In addition, even during long-term use, repeated expansion and contraction due to ambient vibration and temperature changes may cause the terminal screws attached to the terminals to loosen, resulting in regular maintenance and inspection (terminals). If the screws are not retightened), abnormal overheating may occur due to loosening of the screws.

Abnormal terminal overheating occurs when the contact resistance between the crimp terminal to which the electric wire is attached and the terminal increases due to the loosening of the terminal screw, and a large Joule heat is generated.

In addition, abnormal overheating also occurs due to an increase in contact resistance due to oxidation of the contact surface between the crimp terminal of the electric wire and the terminal of the circuit breaker, and an increase in contact resistance due to the pinching of foreign matter.

If such an abnormally overheated state continues, the parts constituting the circuit breaker and the connected electric wires may ignite, and there is a concern that the fire may spread to the building materials and peripheral devices around the circuit breaker.

However, a normal circuit breaker does not have a function of detecting abnormal overheating of these terminals. Generally, to prevent abnormal overheating of terminals, measures are taken to check connections during construction and perform regular maintenance and inspection (tightening of terminal screws, etc.). Although these preventive measures are effective in preventing abnormal overheating, it is not possible to notice abnormal overheating until the next maintenance and inspection, so it is not possible to completely prevent burnout accidents and fire spread accidents due to long-term use. Can not.

Therefore, by detecting abnormal overheating of the terminal and shutting off the power supply to the load side when abnormal overheating occurs, a circuit breaker with an overheat prevention device equipped with a function to prevent burning accidents due to abnormal overheating is cut off. The vessel is disclosed. (Patent Document 1, Patent Document 2)

Patent Document 1 discloses the following as a means of detecting abnormal overheating.
Bimetal plates 25 and 26 for overheat detection are fixed to the power supply side terminal and load side terminal of the circuit breaker, respectively, and a transmission plate that displaces following the displacement of the bimetal plate is suspended between the two bimetal plates. And, although it is always locked to the transmission plate, when it is overheated, the displacement of the transmission plate causes the locking relationship with the transmission plate to be released, so that the actuating rod moves to trip the circuit breaker. To prepare. Further, when the locking relationship between the transmission plate and the operating rod is released and the operating rod operates, the operating rod protrudes to the outside of the circuit breaker to display the operation, and the operating rod is pressed. An overheat prevention device that enables resetting of the circuit breaker is added to a general circuit breaker.

In Patent Document 2, it is made in view of the mechanical structure in Patent Document 1 described above, and abnormal overheating is electrically detected, and is cut off by an electric signal output by the detection of the abnormal overheating. Disclosed is what drives a tripping device that opens the contacts of the vessel.

Specifically, the mechanical operation disclosed in Patent Document 1 is made in view of the fact that it cannot be applied in many cases without changing the internal mechanism of the circuit breaker, and in particular, the prevention of overheating of the circuit breaker alone. In addition, the problem was that the circuit breakers in the power supply system could be centrally managed and used for overheat protection of other devices such as electromagnetic switches installed in the same circuit.

As a configuration for detecting abnormal overheating, a temperature-sensitive element whose electrical output changes according to the temperature of the wire connection terminal and an abnormal overheating are detected by comparing the electrical output of the temperature-sensitive element with a normal level. It is equipped with a judgment circuit.

Examples of the temperature-sensitive element include a thermista, a thermocouple using thermoelectromotive force, an infrared sensor for detecting radiated heat, and the like, and the temperature-sensing element is arranged near the terminal of the mold case. A form of embedding and arranging, a temperature sensor unit is configured by holding it on a resin-molded insulating support independently of the mold case and integrated, and the temperature sensor unit is used by using a groove for mounting an interpolar barrier. A form attached to the mold case, a form in which the temperature sensor unit is formed in a plate shape so that it can be attached by sandwiching it between the back surface and the board surface of the mold case, and a terminal used for insulating the breaker terminal part of the heat sensitive element. A temperature-sensitive element is embedded in an insulator such as ceramic with high thermal conductivity, which is attached to the cover, and inserted into a hole provided in the insulating support of the temperature sensor unit so that it can be moved in the length direction by a spring. Disclosed is a form in which the tip of an insulator is brought into contact with a breaker terminal portion while being held elastically.

Jitsukosho 56-25156 Gazette Japanese Unexamined Patent Publication No. 62-8419

As disclosed in Patent Document 1 and Patent Document 2, it is possible to add a function of detecting abnormal overheating of terminals to a normal circuit breaker. However, in Patent Document 1, in order to add the function of detecting abnormal overheating, it is necessary to separately provide a space for arranging a mechanical mechanism for detecting abnormal overheating on the entire back surface side of the circuit breaker. Since the outer shape of the circuit breaker changes drastically and the circuit breaker is significantly remodeled, there are problems such as an increase in man-hours and an increase in cost.

Further, in Patent Document 2, when arranging an electric device, it is necessary to separately provide a unit provided with a temperature sensor such as a temperature sensitive element and a determination circuit, and attach the unit to a circuit breaker. Since there are many parts for addition and it is necessary to introduce it as a temperature measurement system, it is complicated to add functions. Further, since an electric element such as a temperature-sensitive element is used, there is a problem that it is difficult to understand at first glance whether or not a failure has occurred in long-term use.

Therefore, the present invention has been made in view of the above problems, and whether or not an abnormal overheating of terminals can be detected with a simple configuration without the need for modification of a circuit breaker and a normal output can be obtained by a test operation. It is an object of the present invention to provide a terminal overheat detection device capable of confirming whether or not.

The terminal overheat detection device according to the present invention is configured to solve the above-mentioned problems, is a terminal overheat detection device that is attached to a terminal of an electric device to detect the temperature of the terminal, and is connected to the terminal. A connection portion through which the heat of the terminal is conducted, a thermal element in which one end is fixed to the connection portion and the other end is disposed in a displacementable manner in response to a change in heat, and the thermal element. A displacement transmission unit that is transmitted and reciprocates in response to a response, and a signal output unit that is driven when the displacement of the displacement transmission unit is transmitted and exceeds a predetermined threshold value. At the time of attachment to the circuit breaker, the connection portion is located between the terminal and the electric wire connected to the terminal, and a part of the connection portion is exposed to the outside to form the thermal element. The displacement transmission unit and the substantially square-shaped housing for accommodating the signal output unit are provided, while the displacement transmission unit is displaced by operating from the outside of the housing to drive the signal output unit. It is characterized by having a test operation unit, which constitutes a terminal overheat detection device.

According to this configuration, the displacement of the displacement transmission unit is transmitted by conducting the heat of the terminal overheat detection device to the terminal of the circuit breaker, and the signal output unit is driven when the displacement exceeds a predetermined threshold value. Since it is configured, it is possible to provide a terminal overheat detection device that can detect abnormal overheating of terminals with a simple configuration without the need to modify the circuit breaker.

Further, the connection portion in which the thermal element is arranged is arranged according to the number of terminals of the circuit breaker, while the displacement transmission portion is provided in common to each thermal element. The maximum displacement of each thermal element may be transmitted to the displacement transmission unit to drive the signal output unit.

According to this configuration, the signal output unit can be driven by capturing the heat generated by the terminal that generates the most heat from the plurality of terminals of the circuit breaker, so that it is not necessary to arrange a switch means for each terminal. Therefore, it is possible to collectively monitor a plurality of terminals with a small number of parts.

Further, a part of the connection portion is exposed to the outside, and the thermal element, the displacement transmission portion, and the substantially rectangular parallelepiped housing for accommodating the signal output portion are provided.

The displacement transmission unit may be displaced by operating from the outside of the housing to include a test operation unit for driving the signal output unit.

According to such a configuration, since the drive of the signal output unit can be confirmed by the test operation unit, it is possible to test whether or not the signal output unit can output a signal normally.

As described above, according to the present invention, it is possible to detect abnormal overheating of terminals with a simple configuration without the need to modify the circuit breaker, and it is possible to confirm whether or not a normal output can be obtained by a test operation. It is possible to provide a terminal overheat detection device that can be used.

The schematic diagram of the state which attached the terminal superheat detection apparatus which shows the embodiment of this invention to a circuit breaker is shown. The schematic diagram of the mounting method of the said terminal superheat detection device is shown. The above terminal overheat detection device is shown. The internal assembly drawing of the above-mentioned terminal superheat detection apparatus is shown. FIG. 4 shows a cross-sectional view AA (assembly structure of the switch means) shown in FIG. The appearance of the test operation means of the terminal superheat detection device is shown. FIG. 6 shows a cross-sectional view BB (assembled structure of test operating means) shown in FIG. The structure for detecting the connection failure of the terminal in the conventional example is shown.

Next, an embodiment of the present invention will be described in detail with reference to the drawings.

FIG. 1 shows a schematic configuration diagram of a state in which the terminal superheat detection device 2 according to the present embodiment is attached to the circuit breaker 1. FIG. 2 shows a schematic view of how to attach the terminal superheat detection device. FIG. 3 shows a terminal overheat detection device. FIG. 4 shows an internal assembly drawing of the terminal overheat detection device. FIG. 5 shows the assembly structure of the switch means of the terminal overheat detection device. FIG. 6 shows a test operation means of the terminal overheat detection device. FIG. 7 shows the assembly structure of the test operating means. FIG. 8 shows a structure for detecting a terminal connection failure in the conventional example.

First, the basic structure of the circuit breaker 1 shown in FIGS. 1 and 2 will be described. In FIGS. 1 and 2, the circuit breaker 1 is composed of a circuit breaker housing whose outer shell is a mold case. The circuit breaker housing includes a base 101 on which the internal parts of the circuit breaker are mounted, and a cover 102 that covers the base and covers the internal parts. Inside the circuit breaker 1, a fixed contact (not shown) integrated with the terminal 12 and a movable contact (not shown) for turning on / off the electric circuit on the power supply side and the electric circuit on the load side are provided. Is arranged. Further, the opening / closing mechanism (not shown) that drives the fixed contact and the movable contact to open / close, and the opening / closing mechanism that acts on the opening / closing mechanism by detecting an abnormal current flowing in the electric circuit to pull the opening / closing mechanism. A tripping device unit (not shown) for opening and driving the fixed contact and the movable contact is provided.

The circuit breaker 1 is provided with a plurality of terminals 12 connected to an external conductor corresponding to the power supply of each pole, and each of them is exposed to the outside.

An electric wire 3 is connected to the terminal 12 from the outside. A crimp terminal 31 is attached to the tip of the electric wire 3 by caulking, and the crimp terminal 31 is screwed and fixed to the terminal 12 by a terminal screw 11.

Next, the terminal superheat detection device 2 attached to the circuit breaker 1 will be described with reference to FIGS. 1 and 2. The heat conductive terminal 21 which is a connection portion of the terminal overheat detection device 2 which is connected to the terminal 12 and conducts the heat of the terminal 12 has a through hole through which the terminal screw 11 of the circuit breaker 1 is passed. The heat conductive terminal 21 is tightened and fixed by the terminal screw 11 so as to be sandwiched between the crimp terminal 31 and the terminal 12 of the electric wire 3. At the time of mounting, the terminal overheat detection device 2 is located on the mounting surface of the circuit breaker 1, that is, between the bottom surface of the circuit breaker 1 and the electric wire 3 connected to the terminal 12.

Next, the configuration of the terminal overheat detection device 2 having a function of detecting abnormal overheating of the terminal 12 will be described with reference to FIGS. 3, 4, and 5.

As shown in FIGS. 3, 4 and 5, the terminal overheat detection device 2 is connected to the heat conduction terminal 21 which is a connection portion connected to the terminal 12 of each pole of the circuit breaker 1 to conduct heat of the terminal 12. The first is a displacement transmission unit that is arranged in the vicinity of the thermal element 22 fixed to the thermal conductive terminal 21 and the thermal element 22, and the displacement of the thermal element 22 is transmitted and reciprocally displaced in response to the response. And the second actuator 24, which is also a displacement transmission unit and is arranged in the vicinity of the first actuator 23 and reciprocates in response to the reciprocating displacement of the first actuator 23, and the displacement transmission. The micro switch 25, which is a signal output unit that is driven when the displacement of the unit is transmitted and exceeds a predetermined threshold, and these thermal elements 22, the first operating body 23, the second operating body 24, and the micro switch. It is configured to include a housing 26 for accommodating 25.

The thermal element 22 fixed to the heat conductive terminal 21 is configured by using a bimetal that receives heat conduction from the heat conduction terminal 21 connected to the terminal 12 and is quantitatively displaced. In FIGS. 4 and 5, the thermal element 22 is fixed to the heat conductive terminal 21 by screw tightening, but is not limited to screw tightening, and may be fixed by welding or rivets.

The first actuating body 23 is urged to abut on the position restricting portion 261 of the housing 26 by an elastic member (not shown) that urges the first actuating body 23, and has a constant gap with the thermal element 22. Is arranged in a state of being provided.

As shown in FIG. 5, the second actuating body 24 is urged by the elastic member 241 so as to abut on the micro switch 25. The second operating body 24 is the first operating body that rotates in the A direction shown in FIG. 5 in response to the displacement of the thermal element 22 when the thermal element 22 is displaced by heat conduction from the heat conduction terminal 21. In conjunction with 23, it rotates in the B direction shown in FIG. 5 against the elastic member 241. When the terminal 12 is abnormally overheated, that is, when the magnitude of the displacement of the thermal element 22 exceeds a certain amount, the contact operation portion of the microswitch 25 is operated by the second actuating body 24, so that the microswitch 25 is operated. Is operated to output a signal notifying the abnormal overheating of the terminal 12.

When the heat generated by the terminal 12 subsides, the displacement of the thermal element 22 becomes smaller. As the displacement of the thermal element 22 becomes smaller, the first actuating body 23 and the second actuating body 24 have an elastic member (not shown) for urging the first actuating body 23 or a second actuating body 24. The elastic member 241 that urges the terminal 12 rotates to the position before the terminal 12 generates heat. When the abnormal overheating of the terminal 12 has subsided, that is, when the magnitude of the displacement of the thermal element 22 becomes a certain amount or less, the contact operation unit of the micro switch 25 is operated by the second operating body 24. The micro switch 25 is operated so as not to output a signal notifying the abnormal overheating of the terminal 12.

The heat generated by the terminal 12 is thermally conducted through the heat conductive terminal 21. Since the thermal element 22 is quantitatively displaced according to the amount of heat, the first operating body 23 and the second operating body 24 rotate according to the displacement amount of the thermal element 22. Therefore, the amount of heat generated by the terminal 12, the amount of displacement of the thermal element 22, and the amount of rotation of the first operating body 23 and the second operating body 24 are correlated with each other. Therefore, when the terminal 12 is abnormally overheated, That is, when the magnitude of the displacement of the thermal element 22 exceeds a certain amount and when the terminal 12 is not abnormally overheated, that is, when the magnitude of the displacement of the thermal element 22 is a certain amount or less, the micro It can be configured so that the state of the contact operation unit of the switch 25 is switched.

With such a configuration, the heat conduction terminal 21 of the terminal overheat detection device 2 is attached to the terminal 12 of the existing circuit breaker with the terminal screw 11, so that the terminal overheat detection device does not require modification of the circuit breaker 1. 2 can be attached. Further, by configuring the contact operation unit of the micro switch 25 to be operated when the displacement of the thermal element 22 fixed to the heat conductive terminal 21 exceeds a certain amount, the terminal can be easily configured. Twelve abnormally overheated states can be output.

Note that, in FIGS. 4, 5 and 6, the micro switch 25 is configured to be operated via the first actuating body 23 and the second actuating body 24, but the present invention is not limited to this, and for example, a thermal element. 22 may be configured to operate the micro switch 25 by directly contacting the contact operation portion of the micro switch 25.

Further, in the present embodiment, the operation of the contact operation unit of the micro switch 25 is configured to change from the state of being in contact with the contact operation unit to the state of not being in contact with the contact operation unit when the thermal element 22 is displaced. Needless to say, the structure may be such that when the moving element 22 is displaced, the state of contact is changed from the state of non-contact.

Next, a terminal overheat detection device 2 capable of collectively monitoring a plurality of terminals 12 and detecting abnormal overheating by the terminal 12 that generates the most heat will be described with reference to FIGS. 4 and 5.
The first actuating body 23 shown in FIG. 4 is rotatably fixed to the housing 26 so as to extend over the terminals 12 of each pole.

With such a configuration, among the thermal elements 22 fixed to the terminal 12 of the pole over which the first actuator 23 extends, only the thermal element 22 displaced at the highest temperature is the first actuator. 23 interlocks and rotates in the A direction shown in FIG. 5 against an elastic member (not shown) that urges the first actuating body 23, and the first actuating body 23 rotates the second actuating body 24. Can operate the contact operation portion of the micro switch 25 by rotating in the B direction shown in FIG. 5 against the elastic member 241. Therefore, it is possible to collectively monitor the heat generation state of the plurality of terminals 12 over which the first operating body 23 extends, and it is possible to detect abnormal overheating based on the terminal 12 that generates the most heat. As a result, abnormal overheating of each terminal 12 can be detected with a smaller number of parts than when the terminal overheating detection device 2 is arranged at each terminal 12.

Note that, in FIGS. 4 and 5, the microswitch 25 is configured to be operated via the first actuating body 23 and the second actuating body 24, but the present invention is not limited to this, and for example, the first actuating body is not limited to this. The micro switch 25 may be operated by the 23 directly in contact with the operation unit 251 of the micro switch 25.

Next, FIGS. 5 and 6 show the terminal overheat detection device 2 capable of testing that the micro switch 25 can output a signal normally by intentionally operating the micro switch 25 which is a switch means by the test operation means. And FIG. 7 will be used for explanation.

As shown in FIG. 6, in the housing 26 in which the microswitch 25 is arranged, the test operation means 27 is inserted on the surface in the vicinity of the microswitch 25.

As shown in FIG. 7, one end side of the test operating means 27 is exposed to the outside of the housing 26, and the other end side of the test operating means 27 is the inside of the housing 26 so that the operating means of the micro switch 25 can be operated. It is inserted together with the test elastic member 271 toward. In the case of the present embodiment, the other end side of the test operating means 27 is arranged so as to rotate the second operating body 24.

When one end side of the test operation means 27 exposed to the outside of the housing 26 is operated, the other end side of the test operation means 27 is the operation part of the micro switch 25, and the magnitude of the displacement of the thermal element 22 is constant. Operate in the same way as when the amount is exceeded. For example, in the case of FIGS. 5, 6 and 7, when one end side of the test operating means 27 is pushed, the test operating means 27 moves toward the inside of the housing 26 against the elastic member 271 for testing. The other end side of the test operating means 27 is configured to rotate the second actuating body 24 in the B direction shown in FIG.

With such a configuration, the operation unit of the micro switch 25 can be intentionally operated by operating the test operation means 27. As a result, the normal operation of the micro switch 25 can be confirmed by the presence or absence of the signal output of the micro switch 25 when the test operation means 27 is operated, so that the terminal overheating that enables the test operation confirmation of the micro switch 25 can be easily performed. The detection device 2 can be provided.

Note that, in FIGS. 5, 6 and 7, the second operating body 24 is rotated by pressing the test operating means 27, but the present invention is not limited to this, and the test operating means 27 is used in some way. Needless to say, the operation unit of the micro switch 25 may be operated by the operation. For example, the test operating means is not limited to the push button type, but may be a slide button type, and the test operating means 27 is not limited to the configuration in which the second operating body 24 is rotated, and the first operating body 23 is rotated. It may be configured to be operated or the operation unit of the micro switch 25 may be directly operated.

The present invention is not limited to the above embodiment, and various modifications can be made without departing from the gist of the present invention.

1 Circuit breaker 11 Terminal screw 12 Terminal 2 Terminal overheat detection device 21 Heat conduction terminal 22 Thermal element 23 First actuator 24 Second actuator 241 Elastic member 25 Switch means (micro switch)
26 Housing 261 Position control unit 27 Test operating means 271 Test elastic member 3 Wire 31 Crimping terminal

Claims (2)

A terminal overheat detection device that is attached to the terminal of a circuit breaker to detect the temperature of the terminal.
A connection portion that is connected to the terminal and conducts heat of the terminal,
A thermal element in which one end is fixed to the connection portion and the other end is freely displaced in response to a change in heat.
A displacement transmission unit that transmits the displacement of the thermal element and reciprocates in response to the reaction.
A signal output unit that is driven when the displacement of the displacement transmission unit is transmitted and exceeds a predetermined threshold value.
When attached to the circuit breaker, the connection is located between the terminal and the wire connected to the terminal , and further.
A part of the connection portion is exposed to the outside, and the thermal element, the displacement transmission portion, and a substantially rectangular parallelepiped housing for accommodating the signal output portion are provided.
A terminal overheat detection device including a test operation unit that displaces the displacement transmission unit by operating from the outside of the housing and drives the signal output unit .
While the connection portion in which the thermal element is arranged is arranged corresponding to the number of terminals of the circuit breaker, while the connection portion is arranged.
The displacement transmission unit is provided in common with each of the thermal elements, whereby the displacement transmission unit is provided in common.
The maximum displacement in each of the thermal elements is transmitted to the displacement transmission unit,
The terminal overheat detection device according to claim 1, wherein the signal output unit is driven.

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