JP2010153371A - Switch device - Google Patents

Abstract

<P>PROBLEM TO BE SOLVED: To provide a contactor for controlling a current flowing state between a power source and a load, in which a damage to a load-side unit is certainly prevented when a stationary contact and a movable contact are fused. <P>SOLUTION: The contactor (1A) is provided with an actuator (30) having a gas generation unit (31) and a gas operation mechanism (32). The gas generation unit (31) generates a high pressure gas by reacting a gas generation agent when the movable contact (13) and the stationary contact (12) are fused. The gas operation mechanism (32) is driven by the high pressure gas of the gas generation unit (31) to separate the movable contact (13) from the stationary contact (12). <P>COPYRIGHT: (C)2010,JPO&INPIT

Description

    The present invention relates to a switch device that controls an energized state, and particularly relates to measures for opening a contact.

    2. Description of the Related Art Conventionally, switch devices such as contactors and breakers that control an energization state between a power source and a load are known. In this switch device, when the contact of the movable contact and the contact of the fixed contact deteriorate, there is a possibility that the metal of the contact melts and the contacts adhere to each other. Patent Document 1 discloses a material excellent in welding resistance as a material of these contacts.

JP 2008-75117 A

    By the way, when a material having excellent welding resistance is used for the contact of the movable contact and the contact of the fixed contact as in the conventional case, the number of times of opening and closing between the fixed contact and the movable contact until the welding occurs is reduced. Can be increased. However, welding cannot be completely eliminated. For this reason, when welding occurs, the movable contact cannot be separated from the fixed contactor, and the load-side device may be damaged.

    The present invention has been made in view of such a point, and an object of the present invention is to reliably prevent damage to an apparatus when a fixed contact and a movable contact are welded.

    In the present invention, when the fixed contact (12) and the movable contact (13) are welded, the movable contact (13) is separated from the fixed contact (12) by the gas pressure type actuator (30). .

    Specifically, the first invention is a movable contact that opens and closes between a stationary contact (12) and a closed position in contact with the stationary contact (12) and an opened position away from the fixed contact (12). A switch device including a contact mechanism (20) having a contact (13) and a switching mechanism (25) for opening and closing the movable contact (13) is intended.

    Further, according to a first aspect of the present invention, there is provided a gas generator (31) for generating high-pressure gas when the contact state between the stationary contact (12) and the movable contact (13) is a predetermined state, and the gas generator An actuator (30) having a gas actuating mechanism (32) that is driven by the pressure of the high-pressure gas generated from (31) to separate the movable contact (13) from the fixed contact (12) is provided.

    In the first invention, when the movable contact (13) and the fixed contact (12) are welded, that is, the movable contact (13) cannot be separated from the fixed contact (12) by the switching mechanism (25). In this case, the gas generator (31) generates high-pressure gas. The gas operating mechanism (32) is driven by the high-pressure gas, and the movable contact (13) is pulled away from the fixed contact (12). As a result, the stationary contact (12) and the movable contact (13) are opened.

    In a second aspect based on the first aspect, the gas operating mechanism (32) is connected to the cylinder (36), the piston (37) accommodated in the cylinder (36), and the piston (37). And a rod (38) whose tip protrudes from the cylinder (36), and the gas generator (31) is a cylinder for moving the piston (37) and the rod (38) relative to the cylinder (36). (36) The high pressure gas is ejected into the interior.

    In the second invention, the gas generator (31) jets high-pressure gas into the cylinder (36). The injection of the high-pressure gas moves the piston (37) and the rod (38), and pulls the movable contact (13) away from the fixed contact (12).

    In a third aspect based on the first or second aspect, the switching mechanism (25) opens and closes the movable member (26) coupled to the movable contact (13) and the movable contact (13). A switching operation unit (25a) for moving the movable member (26) for movement, and the actuator (30) is configured such that the gas operating mechanism (32) is coupled to the movable member (26), and the gas The movable member (26) is moved to move the movable contact (13) away from the fixed contact (12) by the operation of the generator (31).

    In the third invention, when the gas generator (31) is operated, the movable member (26) connected to the movable contact (13) is moved, and the movable contact (13) is moved to the fixed contact (12 ).

    According to a fourth invention, in the first or second invention, the actuator (30) is configured such that the gas operating mechanism (32) is connected to the movable contact (13) and the gas generator (31) is operated. Thus, the movable contact (13) is moved in order to move the movable contact (13) away from the fixed contact (12).

    In 4th invention, if the said gas generator (31) act | operates, the said movable contact (13) will be moved and this movable contact (13) will be separated from a fixed contact (12).

    According to a fifth invention, in any one of the first to fourth inventions, a casing (15) in which the contact mechanism (20) and the switching mechanism (25) are housed is provided, and the actuator (30) However, it is set as the structure provided in the outer side of the said casing (15).

    In the fifth invention, the actuator (30) moves the movable contact (13) from the outside of the casing (15).

    A sixth invention includes a casing (15) in which the contact mechanism (20) and the switching mechanism (25) are housed in any one of the first to fourth inventions, and the actuator (30). However, it is set as the structure provided inside the said casing (15).

    In the sixth invention, the actuator (30) moves the movable contact (13) inside the casing (15).

    In a seventh aspect based on the second aspect, the rod (38) has a tip between the movable contact (13a) of the movable contact (13) and the fixed contact (12a) of the fixed contact (12). Between the movable contact (13a) and the fixed contact (12a), and the actuator (30) includes the gas generator (31). ) So that the rod (38) is inserted between the movable contact (13a) and the fixed contact (12a) so that the movable contact (13) is separated from the fixed contact (12). It is configured.

    In the seventh invention, when the movable contact (13) and the fixed contact (12) are welded, the gas generator (31) is operated, and the rod (38) of the gas operating mechanism (32) is the movable contact ( 13a) and the fixed contact (12a). The welded portion between the movable contact (13) and the fixed contact (12) is peeled off when the rod (38) enters between the movable contact (13a) and the fixed contact (12a).

    In an eighth aspect based on the seventh aspect, the rod (38) is formed of a non-conductive material.

    In the eighth invention, the rod (38) of non-conductive material enters between the movable contact (13a) and the fixed contact (12a).

    In a ninth aspect based on the seventh aspect, the rod (38) is made of a metal material.

    In the ninth invention, the rod (38) made of a metal material enters between the movable contact (13a) and the fixed contact (12a).

    In a tenth aspect based on the seventh aspect, the rod (38) is moved by the operation of the gas generator (31) so that the movable contact (13a) of the movable contact (13) and the fixed contact (12). The tip portion (38a) penetrating between the fixed contact (12a) of the metal material is formed of a metal material, and at least the surface on the proximal side of the tip portion (38a) of the metal material is formed of a non-conductive material. It has a configuration.

    In the tenth invention, when the gas generator (31) is activated, the tip (38a) of the metal material of the rod (38) passes between the movable contact (13a) and the fixed contact (12a), and the rod The base end side of the non-conductive material (38) is located between the movable contact (13a) and the fixed contact (12a).

    An eleventh aspect of the invention is that, in the ninth aspect of the invention, the rod (38) is formed to have a thickness thinner than a contact gap between the movable contact (13) and the fixed contact (12).

    In the eleventh invention, the rod (38) thinner than the contact gap between the movable contact (13) and the fixed contact (12) enters between the movable contact (13a) and the fixed contact (12a).

    In a twelfth aspect based on the first or second aspect, the actuator (30) includes a blocking mechanism (45) for preventing the gas operating mechanism (32) from returning to the initial state before driving after the gas operating mechanism (32) is driven. It has a configuration.

    In the twelfth invention, when the gas actuating mechanism (32) is driven, the movable contact (13) is held away from the fixed contact (12).

    A thirteenth invention includes a casing (15) in which the contact mechanism (20) and the switching mechanism (25) are housed in the first or second invention, and the actuator (30) includes the casing (15 ) In the communication hole (15b) communicating between the inside and the outside of the), and a structure provided with a display member (50) which is configured to move with the driving of the gas operating mechanism (32) and to be visible from the outside. It is said.

    In the thirteenth aspect of the invention, when the gas operating mechanism (32) is driven, the display member (50) moves, and the display member (50) is viewed from the outside, so that the driving of the gas operating mechanism (32) is confirmed. The

    In a fourteenth aspect based on any one of the first to thirteenth aspects, the switching mechanism (25) is arranged so that the movable contact (13) is separated from the fixed contact (12) when an abnormal current flows. ) Is provided with a trip mechanism (60).

    In the fourteenth invention, even when the trip mechanism (60) does not function, the movable contact (13) is pulled away from the fixed contact (12) by the actuator (30). As a result, the stationary contact (12) and the movable contact (13) are opened.

    In a fifteenth aspect based on the fourteenth aspect, the gas generator (31) of the actuator (30) is configured such that the trip mechanism (60) operates and the fixed contact (12) and the movable contact (13) The high pressure gas is generated when the contact state is in a predetermined state.

    In the fifteenth invention, if the fixed contact (12) and the movable contact (13) are in contact with each other even though the trip mechanism (60) is originally operated, the gas generator (31) of the actuator (30) is contacted. ) Is activated and the movable contact (13) is pulled away from the fixed contact (12).

    In the present invention, when the fixed contact (12a) and the movable contact (13a) are welded, the pressure of the high-pressure gas is used to pull the movable contact (13) away from the fixed contact (12), and the contact mechanism (20) Is established. Thus, according to the present invention, since the pressure of the high-pressure gas is used, a large propulsive force can be obtained as the force for driving the gas operating mechanism (32). Therefore, when the fixed contact (12) and the movable contact (13) are welded, the movable contact (13) can be reliably pulled away from the fixed contact (12), so that damage to the device is ensured. Can be prevented.

    In particular, since the movable contact (13) is pulled away from the fixed contact (12) at the time of welding using the gas generator (31) that generates the high-pressure gas, for example, the movable contact using the force of a spring or a solenoid. Compared with the case where (13) is separated from the stationary contact (12), a large force can be obtained while being small. For this reason, the movable contact (13) can be reliably pulled away from the fixed contact (12) while avoiding an increase in the size of the contactor (1A) due to measures against welding.

    According to the second invention, the gas generator (31) injects the high-pressure gas into the cylinder (36) and moves the rod (38), so that the contact mechanism (20) can be opened instantaneously.

    According to the third invention, the gas actuating mechanism (32) moves the movable contact (13) by pushing the movable member (26), not directly moving the movable contact (13). As a result, the degree of freedom in structure can be improved as compared with the case where the gas operating mechanism (32) directly presses the movable contact (13).

    According to the fourth invention, since the gas actuating mechanism (32) directly moves the movable contact (13), the opening operation of the movable contact (13) is directly performed to improve the reliability of the emergency measure. Can be made.

    According to the fifth invention, since the actuator (30) is provided outside the casing (15), the gas operating mechanism (32) can be configured in a large size. Therefore, a large force can be generated in the gas operation mechanism (32).

    According to the sixth invention, since the actuator (30) is provided inside the casing (15), the dead space in the casing (15) can be used effectively. Therefore, it is possible to reduce the size of the entire apparatus.

    According to the seventh invention, the rod (38) is inserted between the fixed contact (12a) and the movable contact (13a), and the movable contact (13) is pulled away from the fixed contact (12). The welded part between (12a) and the movable contact (13a) can be directly peeled off. As a result, the movable contact (13) can be reliably pulled away from the fixed contact (12).

    According to the eighth aspect of the invention, since the rod (38) is formed of a non-conductive material, the movable contact is made when the rod (38) is inserted between the fixed contact (12a) and the movable contact (13a). A non-conducting state can be reliably established between the child (13) and the stationary contact (12).

    According to the ninth aspect, since the rod (38) is formed of a metal material, the rod (38) can be made robust, and the movable contact (13) and the fixed contact (12). Can be reliably separated from each other.

    According to the tenth aspect of the invention, the rod (38) has the distal end portion (38a) made of a metal material, and at least the surface on the proximal end side is made of a non-conductive material. The movable contact (13) and the stationary contact (12) can be brought into a non-conductive state while securing the above.

    According to the eleventh aspect of the invention, since the rod (38) is made thinner than the contact gap, when the actuator (30) is operated, the rod (38) is connected to the movable contact (13a) and the fixed contact (12a). Since it can be made to leave | separate reliably from either one, between a movable contact (13) and a stationary contact (12) can be made into a non-conduction state.

    According to the twelfth aspect, since the return prevention mechanism (45) is provided, the movable contact (13) is held away from the fixed contact (12) after the gas actuation mechanism (32) is driven. The For this reason, the movable contact (13) does not contact the fixed contact (12) again. Therefore, the contact mechanism (20) is not closed after the welding once occurs, and the device after the welding once can be surely protected.

    According to the thirteenth aspect, since the display member (50) that moves together with the gas operating mechanism (32) is provided, the user or the like confirms the position of the display member (50) from the outside of the casing (15). Thus, it can be confirmed whether or not the gas operating mechanism (32) is driven, that is, whether or not the gas generator (31) is operated. And a user etc. can judge whether it is in the state which can use an apparatus by whether the gas generator (31) act | operated.

    According to the fourteenth aspect of the present invention, since the trip mechanism (60) is provided, when the abnormal current flows even if the actuator (30) does not operate due to the high pressure gas generated from the gas generator (31), the switching mechanism. (25) can be established reliably.

    According to the fifteenth aspect of the invention, if the movable contact (13) is in contact with the fixed contact (12) even when the trip mechanism (60) is operated, the actuator (30) causes the movable contact (13) to move. It can be reliably pulled away from the stationary contact (12), and damage to the device can be reliably prevented.

FIG. 1 is a schematic structural diagram of a contactor according to Embodiment 1, FIG. 1 (A) is a schematic structural diagram before the operation of the gas generator, and FIG. 1 (B) is a schematic diagram after the operation of the gas generator. FIG. FIG. 2 is a schematic structural diagram of a contactor according to Modification 1 of Embodiment 1, FIG. 2 (A) is a schematic structural diagram before the operation of the gas generator, and FIG. 2 (B) is a gas generator. FIG. FIG. 3 is a schematic structural diagram of a contactor according to Modification 2 of Embodiment 1, FIG. 3 (A) is a schematic structural diagram before the operation of the gas generator, and FIG. 3 (B) is a gas generator. FIG. 4 is a schematic structural diagram of an actuator according to Modification 3 of Embodiment 1, FIG. 4 (A) is a schematic structural diagram before the operation of the gas generator, and FIG. 4 (B) is a schematic diagram of the gas generator. It is a schematic structure diagram after operation. FIG. 5 is a schematic structural diagram of a contactor according to Modification 4 of Embodiment 1, FIG. 5 (A) is a schematic structural diagram before operation of the gas generator, and FIG. 5 (B) is a gas generator. FIG. 6 is a schematic structural diagram of a contactor according to Modification 5 of Embodiment 1, FIG. 6 (A) is a schematic structural diagram before operation of the gas generator, and FIG. 6 (B) is a gas generator. FIG. FIG. 7 is a schematic structural diagram of a power supply including a contactor showing a sixth modification of the first embodiment. FIG. 8 is a schematic structural diagram of a contactor according to Modification 7 of Embodiment 1, FIG. 8 (A) is a schematic structural diagram before the operation of the gas generator, and FIG. 8 (B) is a gas generator. FIG. FIG. 9 is a schematic structural diagram illustrating a main part after the operation of the contactor according to the eighth modification of the first embodiment. FIG. 10 is a schematic structural diagram illustrating a main part after the operation of the contactor according to the ninth modification of the first embodiment. 11 is a schematic structural diagram of the breaker according to the second embodiment, FIG. 11 (A) is a schematic structural diagram before the operation of the gas generator, and FIG. 11 (B) is a schematic diagram after the operation of the gas generator. FIG. FIG. 12 is a schematic structural diagram of a breaker according to Modification 1 of Embodiment 2, FIG. 12 (A) is a schematic structural diagram before the operation of the gas generator, and FIG. 12 (B) is a schematic diagram of the gas generator. It is a schematic structure diagram after operation. FIG. 13 is a schematic structural diagram of a breaker according to Modification 2 of Embodiment 2, FIG. 13 (A) is a schematic structural diagram before the operation of the gas generator, and FIG. 13 (B) is a schematic diagram of the gas generator. It is a schematic structure diagram after operation. FIG. 14 is a schematic structural diagram of a breaker according to Modification 3 of Embodiment 2.

    Hereinafter, embodiments of the present invention will be described in detail with reference to the drawings.

<Embodiment 1>
In the first embodiment, as shown in FIG. 1, the switch device according to the present invention constitutes a contactor (1A).

    The contactor (1A) is provided in an electric circuit (2A) that connects a power source and a load (power device) supplied with power from the power source, and includes a box-shaped casing (15). The casing (15) is a resin casing. A convex portion (15a) is formed on the upper surface of the casing (15).

    A first connection terminal (21) and a second connection terminal (21) to which the electric circuit (2A) is connected are provided on the casing (15). The first connection terminal (21) and the second connection terminal (21) are arranged on the side of the projection (15a). Further, one of the first and second connection terminals (21) is connected to a power source, and the other is connected to a load.

    The casing (15) is provided with a contact mechanism (20) and a switching mechanism (25) of the contact mechanism (20).

    The contact mechanism (20) is electrically connected to the first fixed contact (12) electrically connected to the first connection terminal (21) and the second connection terminal (21). A second fixed contact (12) and a movable contact (13) for opening and closing the electric circuit (2A) are provided.

    Each of the fixed contacts (12) is fixed to the casing (15) and extends inward from the lower side of each of the connection terminals (21). A fixed contact (12a) is provided on the upper surface of the inner end of each of the fixed contacts (12). Each of the fixed contacts (12) is arranged such that a predetermined interval exists between the inner end portions.

    The said movable contact (13) is arrange | positioned inside a convex part (15a), and is provided above each fixed contact (12). Movable contacts (13a) are provided at both ends of the movable contact (13). The movable contact (13) has a closed position where the left and right movable contacts (13a) are in contact with the left and right fixed contacts (12a), and the left and right movable contacts (13a) are separated from the left and right fixed contacts (12a). It is comprised so that it may move between open positions. In the closed position, the current between the two fixed contacts (12, 12) is energized (ON state), and in the open position, the current between the two fixed contacts (12, 12) is not energized (OFF). State).

    The switching mechanism (25) is configured to move the movable contact (13) between a closed position and an open position. The switching mechanism (25) includes a movable iron core (26) which is a movable member, and a switching operation unit (25a) for moving the movable iron core (26). The switching operation unit (25a) includes a fixed iron core ( 27), an exciting coil (28), and a bobbin (29).

    The movable iron core (26) has an upper end surface connected to the lower surface of the movable contact (13). The movable iron core (26) is provided above the fixed iron core (27). The fixed iron core (27) is fixed to the bottom surface of the casing (15). The exciting coil (28) is wound around a bobbin (29). That is, the switching operation part (25a) is configured as an electromagnet. Furthermore, the switching operation part (25a) includes a pair of return springs (19). The return spring (19) is provided between the movable iron core (26) and the bobbin (29), and is configured to separate the movable iron core (26) from the fixed iron core (27) when switching to a non-energized state. Yes.

    The switching mechanism (25) is configured to attract the movable iron core (26) by exciting the fixed iron core (27) when a current flows through the exciting coil (28) by an external signal. And when the said movable iron core (26) is drawn near to a stationary iron core (27), in connection with it, a movable contact (13) will be moved to the bottom face side of a casing (15), and will move to a closed position. As a result, the electric circuit (2A) is energized, and power is supplied from the power source to the load.

    On the other hand, the switching mechanism (25) is configured such that when the current flowing through the exciting coil (28) is stopped by an external signal, the movable iron core (26) is separated from the fixed iron core (27) by the return spring (19). ing. And when the said movable iron core (26) leaves | separates from a fixed iron core (27), in connection with it, a movable contact (13) will move away from the bottom face of a casing (15), and will move to an open position. As a result, the electric circuit (2A) is deenergized, and power supply from the power supply to the load is stopped.

    By the way, in the contactor (1A), when opening and closing between the pair of fixed contacts (12) and the movable contact (13) is repeated, the fixed contact (12a) and the movable contact (13a) deteriorate, The movable contact (13a) and the fixed contact (12a) may be welded.

    Therefore, in this embodiment, when the movable contact (13a) and the fixed contact (12a) are welded, an actuator (30) for separating the movable contact (13) from the fixed contact (12) is provided. Yes. The actuator (30) includes a gas generator (31) and a gas operation mechanism (32), and is provided outside the casing (15). Specifically, the actuator (30) is provided outside the casing (15), and is specifically disposed at the bottom of the casing (15).

    The gas generator (31) is constituted by, for example, an electric detonator. The gas generator (31) includes an explosive (gas generating agent). When the contact state between the fixed contact (12) and the movable contact (13) is a predetermined state, the explosive explosion (gas It is configured to generate a high-pressure gas with the reaction of the generating agent.

    The gas actuating mechanism (32) is configured to be driven by the pressure of the high-pressure gas generated from the gas generator (31) to separate the movable contact (13) from the fixed contact (12). . The gas actuating mechanism (32) includes a cylinder (36), a piston (37) accommodated in the cylinder (36), and a pair connected to the piston (37) and protruding from the cylinder (36). Rods (38, 38).

    The cylinder (36) is formed in a bottomed cylindrical shape having an upper end opened, and is attached to the bottom surface of the casing (15).

    The piston (37) is slidably moved in the cylinder (36) and defines a gas chamber (34) in the cylinder (36).

    One end of the rod (38) is connected to the upper surface of the piston (37), and the rod (38) protrudes upward from the upper surface of the piston (37). The rod (38) is provided so as to pass through an insertion hole formed in the bottom of the casing (15) and the upper end as the other end abuts the lower surface of the movable iron core (26) in the closed position.

    A gas generator (31) is provided on the lower side of the cylinder (36), and the gas generator (31) moves the piston (37) and the rod (38) relative to the cylinder (36). Therefore, the high pressure gas is jetted into the gas chamber (34) in the cylinder (36).

    The contactor (1A) is provided with a controller (40). The controller (40) is connected to the gas generator (31) and to the switching mechanism (25) and the electric circuit (2A). The controller (40) has a current flowing through the electrical circuit (2A) even though a signal to switch the electrical circuit (2A) from the energized state to the non-energized state is input to the switching mechanism (25). In addition, the gas generator (31) is configured to operate. That is, when the movable contact (13a) and the fixed contact (12a) are welded and the movable contact (13) is not separated from the fixed contact (12) by the switching mechanism (25), the controller (40) The gas generator (31) is configured to operate.

−Contactor (1A) switching operation−
Next, the switching operation of the contactor (1A) will be described.

    When the contactor (1A) is operating normally, as shown in FIG. 1 (A), when the exciting coil (28) of the switching operation part (25a), which is an electromagnet, is excited, the movable iron core (26) It is sucked into the fixed iron core (27). As a result, the movable contact (13) moves to the closed position, the movable contact (13) contacts the fixed contact (12), the electric circuit (2A) is energized, and power is supplied to the load. .

    In addition, when the contactor (1A) is operating normally, if the excitation coil (28) of the switching operation part (25a), which is an electromagnet, is demagnetized, the movable iron core (26) is applied by the spring force of the return spring (19). Is farther from the fixed iron core (27). As a result, the movable contact (13) moves to the open position, the movable contact (13) moves away from the fixed contact (12), the electric circuit (2A) is de-energized, and power supply to the load is stopped. To do.

    On the other hand, when the fixed contact (12a) and the movable contact (13a) are welded, the signal for switching the electric circuit (2A) from the energized state to the non-energized state is input to the switching mechanism (25). Current continues to flow in the electric circuit (2A). At that time, the current flow of the electric circuit (2A) is detected, and the controller (40) operates the gas generator (31) of the actuator (30). When this gas generator (31) is activated, the explosive explodes and high-pressure gas generated by the explosion is injected into the gas chamber (34). The pressure in the gas chamber (34) is increased by the high-pressure gas, the piston (37) moves, and the rod (38) moves in a protruding manner. Then, as shown in FIG. 1B, the gas actuating mechanism (32) pushes and moves the movable iron core (26) upward to pull the movable contact (13) away from the fixed contact (12). As a result, the electric circuit (2A) is de-energized and power supply to the load is stopped.

-Effect of Embodiment 1-
In the present embodiment, when the fixed contact (12a) and the movable contact (13a) are welded, the pressure of the high-pressure gas generated by the reaction of the gas generating agent is used to move the fixed contact (12) to the movable contact ( 13) Pull apart to open the contact mechanism (20). Thus, in this Embodiment 1, since the pressure of the high pressure gas generated by the reaction of the gas generating agent is used, a large propulsive force can be obtained as the force for driving the gas operating mechanism (32). Therefore, when the fixed contact (12) and the movable contact (13) are welded, the movable contact (13) can be reliably pulled away from the fixed contact (12). Damage can be reliably prevented.

    In particular, since the movable contact (13) is pulled away from the fixed contact (12) during welding using the pressure of the high-pressure gas generated by the reaction of the gas generating agent, for example, the movable contact can be performed using the force of a spring or solenoid. Compared with the case where the child (13) is pulled away from the stationary contact (12), a large force can be obtained while being small. For this reason, the movable contact (13) can be reliably pulled away from the fixed contact (12) while avoiding an increase in the size of the contactor (1A) due to measures against welding.

    Further, since the gas generator (31) injects high-pressure gas into the cylinder (36) and moves the rod (38), the contact mechanism (20) can be opened instantly.

    Further, the gas actuating mechanism (32) does not move the movable contact (13) directly, but moves the movable contact (13) by pushing the movable member (26). As a result, the degree of freedom in structure can be improved as compared with the case where the gas operating mechanism (32) directly presses the movable contact (13).

    Moreover, since the said actuator (30) is provided in the outer side of the casing (15), a gas action mechanism (32) can be comprised large sized. Therefore, a large force can be generated in the gas operation mechanism (32).

    The gas actuating mechanism (32) presses the movable contact (13) in the direction in which the movable contact (13) moves by the switching mechanism (25). As a result, the propulsive force of the gas actuating mechanism (32) can be effectively used as a force for pulling the movable contact (13) away from the fixed contact (12).

    In addition, since the actuator (30) only needs to operate reliably once in an emergency, the actuator (30) can be configured with an actuator that generates high-pressure gas in association with the explosive explosion (reaction of the gas generating agent). However, a powerful actuator can be used.

<Modification 1 of Embodiment 1>
In the first modification of the first embodiment, as shown in FIG. 2, the actuator (30) is movable instead of the actuator (30) of the first embodiment moving the movable member (26) of the switching mechanism (25). The contact (13) is moved directly.

    Specifically, the movable contact (13) is provided below each fixed contact (12). A movable contact (13a) is provided on the upper surface of the movable contact (13). A fixed contact (12a) is provided on the lower surface of each fixed contact (12).

    The actuator (30) is provided on the upper side of the movable contact (13). The actuator (30) is provided on the convex portion (15a) of the casing (15), and the gas generator (31) is accommodated in the base end portion (upper end portion in FIG. 2) of the small cylinder (36). .

    The rod (38) of the gas actuation mechanism (32) of the actuator (30) extends from the lower surface of the piston (37) and projects below the cylinder (36). Further, as shown in FIG. 2A, the rod (38) is in contact with the upper surface of the movable contact (13) in the closed position in a state before the operation of the gas generator (31).

    In the first modification, when the gas generator (31) is operated by the controller (40), the pressure of the gas chamber (34) is increased by the high-pressure gas generated by the explosive explosion. As the pressure of the gas chamber (34) increases, the gas operating mechanism (32) moves the movable contact (13) downward and moves from the fixed contact (12) as shown in FIG. 2 (B). Pull the contact (13) apart. As a result, the power supply and the load are not energized.

    In the first modification, as in the first embodiment, the movable contact (13) is moved to the open position in the non-energized state by the gas operating mechanism (32). That is, the gas operating mechanism (32) presses the movable contact (13) in the direction in which the movable contact (13) moves by the switching mechanism (25). As a result, the propulsive force of the gas actuating mechanism (32) can be effectively used as a force for pulling the movable contact (13) away from the fixed contact (12).

    Therefore, according to the first modification, the gas actuating mechanism (32) directly moves the movable contact (13), so the opening operation of the movable contact (13) is performed directly, and the reliability of the emergency measure is increased. Can be improved.

    Moreover, since the said gas generator (31) is attached to the upper side of the casing (15), handling of this gas generator (31) can be made easy. Other configurations, operations, and effects are the same as those in the first embodiment.

<Modification 2 of Embodiment 1>
As shown in FIG. 3, the second modification of the first embodiment replaces the actuator (30) of the first modification of the first embodiment with the actuator (30) instead of moving the movable contact (13) in the opening direction. The rod (38) is inserted into the welding location between the movable contact (13) and the stationary contact (12).

    Specifically, two actuators (30) are provided. The tip of the rod (38) of the gas actuation mechanism (32) in each actuator (30) is formed in a needle shape or a blade shape, for example.

    3A, the right actuator (30) is provided so that the tip of the rod (38) is positioned at the height of the contact surface between the right movable contact (13a) and the fixed contact (12a). The left actuator (30) is provided such that the tip of the rod (38) is positioned at the height of the contact surface between the left movable contact (13a) and the fixed contact (12a).

    Further, each actuator (30) is provided in the horizontal direction, and the rod (38) is provided such that the axis extends in the direction of the contact surface between the movable contact (13a) and the fixed contact (12a), and the rod The tip of (38) is configured to be positioned laterally between the movable contact (13a) and the fixed contact (12a).

    Further, the rod (38) of each actuator (30) is formed of a metal material, and is formed to be thinner than the contact gap between the movable contact (13) and the fixed contact (12). .

    In other words, the rod (38) can be configured to be robust by being formed of a metal material, while contacting the movable contact (13a) and the fixed contact (12a) when the actuator (30) is actuated. There is a risk that the power supply and the load remain energized. Therefore, when the thickness of the rod (38) is made thinner than the contact gap between the movable contact (13) and the fixed contact (12) and the actuator (30) is operated, the rod (38) (13a) and the fixed contact (12a) are surely separated from either one, and the power source and the load are not energized. The configuration of the other actuator (30) is the same as that of the first modification.

    In the second modification, when the movable contact (13a) and the fixed contact (12a) are welded, the controller (40) changes the state from the state before the operation of each gas generator (31) shown in FIG. The gas generator (31) is activated. In each actuator (30), the pressure in the gas chamber (34) is increased by the high-pressure gas generated by the explosion of the explosive. As the pressure in the gas chamber (34) increases, the rod (38) protrudes and moves as shown in FIG. 3 (B), and the tip of the rod (38) moves between the movable contact (13a) and the fixed contact ( 12a). As a result, the movable contact (13) is separated from the fixed contact (12), and the power source and the load are not energized.

    Therefore, since the pressure of the high-pressure gas generated by the reaction of the gas generating agent is used, a large driving force can be obtained as a force for driving the gas operating mechanism (32). As a result, the rod (38) can be surely inserted between the movable contact (13a) of the movable contact (13) and the fixed contact (12a) of the fixed contact (12). 13) can be pulled away from the stationary contact (12).

    Moreover, a small thing can be used for the gas action mechanism (32) inserted in a welding location. Therefore, the contactor (1A) can be prevented from being enlarged by providing the gas operation mechanism (32).

    The rod (38) is inserted between the fixed contact (12a) and the movable contact (13a), and the movable contact (13) is pulled away from the fixed contact (12). The welded part with the contact (13a) can be peeled off directly. As a result, the movable contact (13) can be reliably pulled away from the fixed contact (12).

    Further, since the rod (38) is made of a metal material, the rod (38) can be made robust and the movable contact (13) and the stationary contact (12) can be reliably separated. Can be made.

    In addition, since the rod (38) is thinner than the contact gap, when the actuator (30) is actuated, the rod (38) is surely secured from either the movable contact (13a) or the fixed contact (12a). Therefore, the movable contact (13) and the stationary contact (12) can be in a non-conductive state. Other operations and effects are the same as those of the first modification of the first embodiment.

    In the second modification, two actuators (30) are provided, but one actuator (30) may be provided.

<Modification 3 of Embodiment 1>
As shown in FIG. 4, the third modification of the first embodiment is to return the actuator (30) after the operation, instead of the actuator (30) of the first modification of the first embodiment being in a free state after the operation. It is intended to be restrained.

    Specifically, the actuator (30) includes a return prevention mechanism (45) that prevents the gas actuation mechanism (32) driven by the pressure of the gas chamber (34) from returning to the position before the drive. The return prevention mechanism (45) is formed on the tongue (45a) protruding from the outer peripheral surface of the piston (37) and the cylinder (36), and the tongue (45a) is fitted when the piston (37) moves. And a stepped portion (45b).

    The tongue piece (45a) is formed integrally with the piston (37), and extends from the cylinder head side end (the upper end in FIG. 4) of the piston (37) to the head side (the upper side in FIG. 4) of the cylinder (36). ing. The piston (37) is made of an elastically deformable material (for example, resin).

    The step portion (45b) is formed on the rod side on the inner surface of the cylinder (36).

    The piston (37) is held by the tongue piece (45a) being hooked on the taper surface on the head side (upper part) of the cylinder (36). When the gas generator (31) is operated from this state, the piston (37) moves and the tongue piece (45a) is deformed inward, and as shown in FIG. 4 (B), the piston (37) is stopped simultaneously. The tongue (45a) spreads and fits into the step (45b).

    Therefore, according to the third modification, since the return prevention mechanism (45) of the gas operating mechanism (32) is provided, the movable contact (13) is fixed to the fixed contact ( 12) is kept away from. For this reason, the movable contact (13) does not contact the fixed contact (12) again. Therefore, the contact mechanism (20) is not closed after the welding once occurs, and the load-side device after the welding once can be reliably protected. Other configurations, operations, and effects are the same as those of the first modification of the first embodiment.

<Modification 4 of Embodiment 1>
In the fourth modification of the first embodiment, as shown in FIG. 5, the actuator (30) of the first modification of the first embodiment pushes the rod (38) to move the movable contact (13). The movable contact (13) is moved by retracting the rod (38) of the actuator (30).

    Specifically, the rod (38) of the gas actuation mechanism (32) in the actuator (30) is formed at the shaft (46) whose base end is connected to the piston (37) and at the tip of the shaft (46). And a locking portion (47). The movable iron core (26) is formed with a housing chamber (42) for housing the locking portion (47). A through hole through which the shaft portion (46) passes is formed in the central portion of the movable contact (13) and the upper portion of the accommodation chamber (42) in the movable iron core (26). Further, a gas chamber (34) is formed inside the cylinder (36) on the rod (38) side, and the gas generator (31) of the actuator (30) faces the gas chamber (34). Is attached to the cylinder (36).

    Therefore, when the gas generator (31) is operated by the controller (40) from the state before the operation of the gas generator (31) shown in FIG. 5 (A), the actuator (30) has the high pressure generated by the explosive explosion. The pressure in the gas chamber (34) containing the gas increases. As the pressure in the gas chamber (34) increases, the piston (37) and the rod (38) are driven upward as shown in FIG. 5 (B), and the movable iron core (26 ) Is pulled upward. As a result, the movable contact (13) is separated from the fixed contact (12), and the power source and the load are not energized. Other configurations, operations, and effects are the same as those of the first modification of the first embodiment.

<Modification 5 of Embodiment 1>
As shown in FIG. 6, the fifth modification of the first embodiment is provided with a display member (50) for the operation of the actuator (30) instead of the actuator (30) of the first embodiment not performing the operation display. It is a thing.

    Specifically, a communication hole (15b) that communicates the inside and the outside of the casing (15) is provided in the lower portion of the casing (15). On the other hand, the display member (50) is formed in a plate shape and is inserted into the communication hole (15b). The inner end surface of the display member (50) is connected to the outer surface of the rod (38), and the outer end surface of the display member (50) is exposed to the outside of the casing (15). The display member (50) is provided so as to be visible from the outside of the casing (15).

    The communication hole (15b) is formed in a slit shape extending in the vertical direction. The width of the communication hole (15b) is slightly wider than the thickness of the display member (50). Further, the height of the communication hole (15b) is slightly larger than the value obtained by adding the moving distance of the rod (38) when the actuator (30) is operated to the vertical width of the display member (50). Is formed.

    Therefore, when the gas generator (31) is operated and the gas operating mechanism (32) is driven, the display member (50) is moved upward together with the gas operating mechanism (32) as shown in FIG. Moving. For this reason, users etc. confirmed whether the gas operation mechanism (32) was driven by checking the position of the display member (50) from the outside of the casing (15), that is, the gas generator (31) was activated. It can be confirmed whether or not.

    Further, the user or the like can recognize that the gas generator (31) is not operating when the display member (50) is positioned on the lower side (see FIG. 6 (A)). When the display member (50) is positioned on the upper side (see FIG. 6 (B)), it can be recognized that the gas generator (31) has been activated. Then, the user or the like can determine whether or not the contactor (1A) can be used depending on whether or not the gas generator (31) is activated.

    The display member (50) may be a part of the gas operation mechanism (32).

    Further, the display member (50) may not be connected to the gas operation mechanism (32). For example, a protrusion that contacts the display member (50) during driving of the gas operating mechanism (32) is provided on the outer surface of the rod (38), and the display member (50) is moved along with the driving of the gas operating mechanism (32). You may make it move outside. The user or the like can recognize whether or not the gas generator (31) has been activated by confirming whether or not the display member (50) has moved outward from the outside of the casing (15). . Other configurations, operations, and effects are the same as those in the first embodiment.

<Modification 6 of Embodiment 1>
As shown in FIG. 7, the sixth modification of the first embodiment replaces the contactor (1A) with the contactor (1A) instead of providing the contactor (1A) between the power source and the load in the electric circuit (2A). ) Is provided inside the power supply (51).

    Specifically, the power source (51) includes a plurality of batteries (52) connected in series by a connecting member (53). The contactor (1A) is provided between the connection members (53) between the two batteries (52). The contactor (1A) switches between the two batteries (52) between a conducting state and a non-conducting state. In the contactor (1A), when the fixed contact (12) and the movable contact (13) are welded, the pressure of the gas chamber (34) that contains the gas generated by the reaction of the gas generating agent is used. Then, the movable contact (13) is pulled away from the fixed contact (12) so that the battery (52) is not energized. Other configurations, operations, and effects are the same as those in the first embodiment.

<Modification 7 of Embodiment 1>
As shown in FIG. 8, the seventh modification of the first embodiment is different from the first embodiment in which the actuator (30) is provided outside the casing (15), and the actuator (30) is arranged inside the casing (15). It is intended to be provided.

    Specifically, the actuator (30) is configured such that a piston (37) and a rod (38) are housed in a small cylinder (36) and a gas generator (31) is housed. . For example, two or more actuators (30) are provided, the cylinder (36) is installed on the bottom surface in the casing (15), and the tip (upper end) of the rod (38) is on the lower surface of the movable iron core (26). It is in contact. The actuator (30) may be only one.

    Therefore, when the movable contact (13a) and the fixed contact (12a) are welded, the controller (40) operates the gas generator (31) of the actuator (30). When the gas generator (31) is operated, high-pressure gas is injected into the gas chamber (34), the pressure in the gas chamber (34) increases, and the rod (38) moves. Then, as shown in FIG. 8B, the gas actuating mechanism (32) pushes and moves the movable iron core (26) upward to pull the movable contact (13) away from the fixed contact (12). As a result, the electric circuit (2A) is de-energized and power supply to the load is stopped.

    According to the seventh modification, since the actuator (30) is provided inside the casing (15), the dead space in the casing (15) can be used effectively. Therefore, it is possible to reduce the size of the entire apparatus. Other configurations, operations, and effects are the same as those in the first embodiment.

<Modification 8 of Embodiment 1>
As shown in FIG. 9, in the eighth modification of the first embodiment, at least a part of the rod (38) is non-conductive instead of the second modification of the first embodiment in which the rod (38) is formed of a metal material. It is made of a functional material.

    Specifically, the rod (38) has a tip (38a) penetrating the fixed contact (12a) and the movable contact (13a) formed of a metal material. The base end portion (38b) closer to the base end side than the tip end portion (38a) of the rod (38), that is, the piston (37) side is formed of a non-conductive material. For example, the base end portion (38b) of the rod (38) is formed of ceramic or an insulating material.

    Therefore, when the actuator (30) is actuated, the tip (38a) of the rod (38) passes through the fixed contact (12a) and the movable contact (13a), and the fixed contact (12a) and the movable contact (13a) ) To the outside. And the base end part (38b) of the said rod (38) is located between a stationary contact (12a) and a movable contact (13a). As a result, the non-conductive state of the electric circuit (2A) is maintained even if the base end (38b) of the rod (38) of the nonconductive material is in contact with the fixed contact (12a) and the movable contact (13a). The

    According to the present modification 8, the rod (38) can be kept non-conductive between the movable contact (13) and the fixed contact (12) while ensuring the robustness of the rod (38). Other configurations, operations, and effects are the same as those of the second modification of the first embodiment.

    In the present modification 8, the base end portion (38b) of the rod (38) is formed of a non-conductive material. However, the rod (38) may be entirely formed of a non-conductive material. Further, only the surface of the base end portion (38b) of the rod (38) may be formed of a non-conductive material.

<Modification 9 of Embodiment 1>
As shown in FIG. 10, the modified example 9 of the first embodiment is different from the modified example 3 of the first embodiment in that the blocking mechanism (45) is replaced by a tongue (45a) of the piston (37) and a step portion (45) of the cylinder (36). 45b), a blocking mechanism (45) is formed on the rod (38).

    Specifically, the blocking mechanism (45) is constituted by a flange formed at the tip of the rod (38). That is, the blocking mechanism (45), which is the tip of the rod (38), passes through the fixed contact (12a) and the movable contact (13a), and the base end portion is the fixed contact (12a) and the movable contact (13a). Located between and. As a result, the movable contact (13) is held away from the fixed contact (12) after the actuator (30) is actuated. For this reason, the movable contact (13) does not contact the fixed contact (12) again.

    The rod (38) is entirely formed of a nonconductive material such as ceramic. Other configurations, operations, and effects are the same as those of the third modification of the first embodiment.

<Embodiment 2>
In the second embodiment, as shown in FIG. 11, the switch device of the first embodiment constitutes a contactor (1A), and the switch device according to the present invention constitutes a breaker (1B). It is.

    As shown in FIG. 11, the breaker (1B) includes a box-shaped resin casing (15).

    The casing (15) is provided with a first connection terminal (21) and a second connection terminal (21) to which an electric circuit (2A) connecting a power source and a load is connected. One of the first connection terminal (21) and the second connection terminal (21) is connected to a power source, and the other is connected to a load.

    The casing (15) is provided with a contact mechanism (20) and a switching mechanism (25) of the contact mechanism (20).

    The contact mechanism (20) includes a fixed contact (12) electrically connected to the first connection terminal (21) and a movable contact electrically connected to the second connection terminal (21). (13) The movable contact (13) is electrically connected to the second connection terminal (21) via a conductive fixing member (11a) fixed to the casing (15) and a wire (11b).

    The stationary contact (12) is fixed to the casing (15). One end of the fixed contact (12) is connected to the first connection terminal (21), and a fixed contact (12a) is provided on the other end of the fixed contact (12). The fixed contact (12a) is provided on the upper surface of the fixed contact (12) in FIG.

    The base end of the movable contact (13) is fixed to the casing (15), the tip is located above the fixed contact (12), and moves up and down in FIG. 11 with the base end as a fulcrum. It is configured to be possible. A movable contact (13a) is provided at the tip of the movable contact (13). The movable contact (13a) is provided on the lower surface of the movable contact (13) in FIG.

    The movable contact (13) moves between a closed position where the movable contact (13a) contacts the fixed contact (12a) and an open position where the movable contact (13a) separates from the fixed contact (12a). Is configured to do. In the closed position, the fixed contact (12) and the fixed member (11a) are energized (ON state), and in the open position, the fixed contact (12) and the fixed member (11a) are not energized. It becomes a state (OFF state).

    The switching mechanism (25) is configured to move the movable contact (13) between a closed position and an open position. Also, the casing (15) is provided with a trip mechanism (60) for pulling the movable contact (13) away from the fixed contact (12) in the event of an abnormal current (overload or overcurrent due to a short circuit). ing.

    The switching mechanism (25) includes a switching operation part (25a), a return spring (19), and a stopper (62). The switching operation portion (25a) is configured by a link mechanism instead of the electromagnet of the first embodiment, and is configured by pin-connecting an operation lever (63), a connection link (64), and an operation link (65) in order. Yes.

    The operation lever (63) is formed in a semicircular arc shape, and a knob (63a) protruding upward is formed. The base end of the operating lever (63) is pin-coupled to the casing (15) to form a rotation fulcrum (63b), and the operating link (65) is connected to the tip via the connection link (64). Yes.

    The operating link (65) is formed in an L shape, the tip is in contact with the upper surface of the movable contact (13), and the base end is inserted into the stopper (62). The base end side of the central portion of the operating link (65) is pin-connected to the casing (15) and is configured as a rotation fulcrum (65a), and the operation lever (63) is located on the tip side from the rotation fulcrum (65a). Are connected via a connection link (64).

    The stopper (62) is provided between the movable contact (13) and the fixed member (11a), and a hole (62a) into which the base end of the operating link (65) is inserted is formed in the upper part. Has been.

    The return spring (19) presses the movable contact (13) from below so as to pull the movable contact (13) away from the fixed contact (12).

    The trip mechanism (60) is made of bimetal. The trip mechanism (60) is connected to the movable contact (13) and the wire (11b) is connected to connect the movable contact (13) and the fixed member (11a). When an abnormal current flows, the trip mechanism (60) is thermally deformed such that the upper end of the trip mechanism (60) is bent toward the stopper (62) side of the switching operation portion (25a). The trip mechanism (60) is configured to move the stopper (62) to the right side in FIG. 11 when thermally deformed. As a result, the operating link (65) is detached from the stopper (62), the movable contact (13) is separated from the fixed contact (12), and the electric circuit (2A) is in a non-energized state.

    By the way, in the breaker (1B), when the fixed contact (12a) of the fixed contact (12) and the movable contact (13a) of the movable contact (13) are deteriorated, the movable contact (13a) and the fixed contact ( 12a) may be welded. In the second embodiment, an actuator (30) is provided to pull the movable contact (13) away from the fixed contact (12) when the movable contact (13a) and the fixed contact (12a) are welded. Yes.

    The actuator (30) is configured similarly to the second modification of the first embodiment. That is, the actuator (30) includes a rod (38), and the rod (38) is configured to be inserted between the movable contact (13a) and the fixed contact (12a).

    The actuator (30) is controlled by a controller (40). The controller (40) is configured to operate the gas generator (31) when a predetermined time elapses after the current flowing through the electric circuit (2A) becomes a predetermined value or more. In other words, if an abnormal current is flowing even though the trip mechanism (60) is activated, the controller (40) has welded the movable contact (13a) and the fixed contact (12a). And the actuator (30) is operated. Other configurations are the same as those of the second modification of the first embodiment.

-Breaker (1B) switching operation-
Next, the switching operation of the breaker (1B) will be described.

    When the breaker (1B) is operating normally, as shown in FIG. 11 (A), the operation lever (63) is operated to move the movable contact (13) to the closed position. In this state, the movable contact (13) contacts the fixed contact (12), the electric circuit (2A) is energized, and power is supplied to the load. At that time, since the base end portion of the operating link (65) is inserted into the hole (62a) of the stopper (62), the movable contact (13) is maintained in the closed position.

    If an abnormal current flows in the electric circuit (2A) from this normal state, the trip mechanism (60) is deformed, the stopper (62) is displaced, and the base end of the operating link (65) is connected to the stopper (62). It comes off from the hole (62a). As a result, the movable contact (13) is moved to the open position by the return spring (19), and the electric circuit (2A) is turned off.

    When an abnormal current flows through the electric circuit (2A), the controller (40) detects this abnormal current. The controller (40) activates the gas generator (31) when a predetermined time has elapsed after the current flowing through the electric circuit (2A) becomes equal to or greater than a predetermined value. In other words, if an abnormal current is flowing even though the trip mechanism (60) is activated, the controller (40) has welded the movable contact (13a) and the fixed contact (12a). And the actuator (30) is operated. That is, the gas generator (31) is operated, and high-pressure gas is injected into the gas chamber (34). The pressure in the gas chamber (34) is increased by the high-pressure gas, the piston (37) moves, and the rod (38) moves in a protruding manner. Then, as shown in FIG. 11B, the rod (38) is inserted between the movable contact (13a) and the fixed contact (12a), and the movable contact (13) is pulled away from the fixed contact (12). . As a result, the electric circuit (2A) is de-energized and power supply to the load is stopped.

-Effect of Embodiment 2-
In the present embodiment, when the fixed contact (12a) and the movable contact (13a) are welded, the pressure of the high-pressure gas generated by the reaction of the gas generating agent is used to move the fixed contact (12) to the movable contact. (13) is pulled apart and the power supply and load are not energized. Thus, in Embodiment 2, since the pressure of the high pressure gas generated by the reaction of the gas generating agent is used, a large propulsive force can be obtained as the force for driving the gas operating mechanism (32). Therefore, when the fixed contact (12) and the movable contact (13) are welded and the trip mechanism (60) stops functioning, the movable contact (13) can be securely removed from the fixed contact (12). Since they can be separated, damage to the load side device can be reliably prevented.

    In particular, since the movable contact (13) is pulled away from the fixed contact (12) during welding using the pressure of the high-pressure gas generated by the reaction of the gas generating agent, for example, the movable contact can be performed using the force of a spring or solenoid. Compared with the case where the child (13) is pulled away from the stationary contact (12), a large force can be obtained while being small. For this reason, the movable contact (13) can be reliably pulled away from the fixed contact (12) while avoiding an increase in the size of the breaker (1B) due to measures against welding.

    Since the trip mechanism (60) is provided, the switching mechanism (25) can be reliably opened when an abnormal current flows. Other effects are the same as those of the second modification of the first embodiment.

<Modification 1 of Embodiment 2>
As shown in FIG. 12, in the first modification of the second embodiment, the second embodiment inserts the rod (38) of the actuator (30) between the movable contact (13a) and the fixed contact (12a). Instead, the actuator (30) directly presses the movable contact (13).

    Specifically, the cylinder (36) of the actuator (30) is disposed between the end of the fixed contact (12) and the return spring (19) so that the axial direction is directed in the vertical direction. The rod (38) of the actuator (30) discharges from the upper part of the cylinder (36).

    Therefore, when the gas generator (31) of the actuator (30) is operated, high-pressure gas is injected into the gas chamber (34), the piston (37) is operated, and the rod (38) is moved to FIG. Push up the movable contact (13) as shown. As a result, the movable contact (13) is pulled away from the fixed contact (12), and the electric circuit (2A) is turned off.

    According to the first modification, the actuator (30) directly moves the movable contact (13), thereby moving the movable contact (13) to a position away from the fixed contact (12). That is, the pressure of the gas generated by the reaction of the gas generating agent is directly transmitted to the movable contact (13). As a result, the movable contact (13) can be reliably pulled away from the fixed contact (12).

    The gas actuating mechanism (32) presses the movable contact (13) in the direction in which the movable contact (13) moves by the switching mechanism (25). As a result, the propulsive force of the gas actuating mechanism (32) can be effectively used as a force for pulling the movable contact (13) away from the fixed contact (12). Other configurations, operations, and effects are the same as those of the second embodiment.

<Modification 2 of Embodiment 2>
As shown in FIG. 13, the second modification of the second embodiment is provided with a display member (50) for operating the actuator (30) in place of the actuator (30) of the second embodiment not performing the operation display. It is a thing.

    Specifically, a communication hole (15b) that communicates the inside and the outside of the casing (15) is provided in the upper part of the casing (15). On the other hand, the display member (50) is formed in a rod shape and is inserted into the communication hole (15b). The display member (50) is provided such that the lower end surface is in contact with the upper surface of the rod (38), and the upper end surface of the display member (50) is exposed to the outside of the casing (15). The display member (50) is provided so as to be visible from the outside of the casing (15).

    Therefore, when the gas generator (31) is operated and the gas operating mechanism (32) is driven, the display member (50) is moved with the movement of the rod (38) as shown in FIG. Move up. For this reason, users etc. confirmed whether the gas operation mechanism (32) was driven by checking the position of the display member (50) from the outside of the casing (15), that is, the gas generator (31) was activated. It can be confirmed whether or not.

    Further, the user or the like can recognize that the gas generator (31) is not operating when the display member (50) is positioned on the lower side (see FIG. 13A). When the display member (50) is positioned on the upper side (see FIG. 13B), it can be recognized that the gas generator (31) has been activated. Then, the user or the like can determine whether or not the contactor (1A) can be used depending on whether or not the gas generator (31) is activated.

    The display member (50) may be a part of the gas operation mechanism (32). Other configurations, operations, and effects are the same as those of the second embodiment.

<Modification 3 of Embodiment 2>
As shown in FIG. 14, the third modification of the second embodiment is different from the first modification of the second embodiment in that the actuator (30) is provided inside the casing (15). 15) is provided outside.

    Specifically, in the actuator (30), the cylinder (36) is disposed outside the casing (15), the rod (38) protrudes from the cylinder (36), and the upper end extends below the movable contact (13). ing. When the gas generator (31) of the actuator (30) is operated, the rod (38) pushes the movable contact (13) upward to move it, and the movable contact (13) is moved from the fixed contact (12). Pull apart. As a result, the electric circuit (2A) is de-energized and power supply to the load is stopped.

    According to the third modification, since the actuator (30) is provided outside the casing (15), the gas operating mechanism (32) can be configured in a large size. Therefore, a large force can be generated in the gas operation mechanism (32). Other configurations, operations, and effects are the same as those of the first modification of the second embodiment.

<Another Modification of Embodiment 2>
The second embodiment may be configured as follows.

    The actuator (30) of the second embodiment may be restrained from returning after being actuated, as shown in the third modification of the first embodiment (see FIG. 4). That is, the actuator (30) of the second embodiment may include the blocking mechanism (45) shown in the third modification of the first embodiment.

    The breaker (1B) of the second embodiment may be provided inside the power source (51) as shown in the sixth modification of the first embodiment (see FIG. 7). That is, the breaker (1B) may be provided between the connection members (53) between the two batteries (52).

    In the actuator (30) of the second embodiment, at least a part of the rod (38) may be formed of a non-conductive material, as shown in Modification 8 (see FIG. 9) of the first embodiment. That is, the rod (38) has a distal end portion that penetrates the fixed contact (12a) and the movable contact (13a) made of a metal material, and a proximal end portion proximal to the distal end of the rod (38) That is, the piston (37) side is formed of a non-conductive material. For example, the base end portion of the rod (38) may be formed of ceramic or an insulating material. Further, at that time, only the surface of the base end portion of the rod (38) may be formed of a non-conductive material.

    In the actuator (30) of the second embodiment, the blocking mechanism (45) may be formed on the rod (38) as shown in the modified example 9 (see FIG. 10) of the first embodiment. That is, the blocking mechanism (45) may be configured by a flange formed at the tip of the rod (38).

    In the actuator (30) of the second embodiment, the movable contact (13) is moved directly, but the movable member (26) of the switching mechanism (25) may be moved. That is, the switching mechanism (25) of Embodiment 2 moves the movable member (26) connected to the movable contact (13) and the movable member (26) to open and close the movable contact (13). For example, the rod (38) of the actuator (30) may be connected to the movable member (26).

<Other embodiments>
Each of the above embodiments may be configured as follows.

    The controller (40) in each of the above embodiments may be provided in the casing (15), and conversely, may be provided outside the casing (15).

    The gas generator (31) of the actuator (30) of each of the above embodiments and each modification of each embodiment includes a gunpowder (gas generating agent), and a high pressure accompanying explosion of the gunpowder (reaction of the gas generating agent). Gas is generated. The gas generator (31) may be a gas cylinder. That is, the gas generator (31) is composed of a gas cylinder filled with high pressure gas. When the fixed contact (12a) and the movable contact (13a) are welded, the gas cylinder is opened and the high pressure gas is supplied to the cylinder (36 ).

    The contactor (1A) of the first embodiment and the breaker (1B) of the second embodiment are provided between the power source and the load and between the load and the load of the electric circuit. May be provided. For example, the contactor (1A) and the breaker (1B) may be provided in a wiring between an electric lamp that is a load.

    In addition, the above embodiment is an essentially preferable illustration, Comprising: It does not intend restrict | limiting the range of this invention, its application thing, or its use.

    As described above, the present invention is useful for a switch device that controls the energization state of an electric circuit.

1A Contactor 1B Breaker 12 Fixed Contact 12a Fixed Contact 13 Movable Contact 13a Movable Contact 15 Casing 20 Contact Mechanism 25 Switching Mechanism 30 Actuator 31 Gas Generator 32 Gas Actuation Mechanism 34 Gas Chamber 36 Cylinder 37 Piston 38 Rod 38a Tip 38b Base end 40 Controller 45 Blocking mechanism 50 Display member 60 Trip mechanism

Claims (15)

A contact mechanism having a fixed contact (12) and a movable contact (13) that opens and closes to a closed position in contact with the fixed contact (12) and an open position away from the fixed contact (12) ( 20)
A switching device comprising a switching mechanism (25) for opening and closing the movable contact (13),
A gas generator (31) that generates high-pressure gas when the contact state between the stationary contact (12) and the movable contact (13) is in a predetermined state, and high-pressure gas generated from the gas generator (31) A switch device comprising an actuator (30) having a gas actuating mechanism (32) driven by the pressure of the gas to move the movable contact (13) away from the fixed contact (12). In claim 1,
The gas actuating mechanism (32) includes a cylinder (36), a piston (37) accommodated in the cylinder (36), and a rod connected to the piston (37) and protruding from the cylinder (36). (38)
The gas generator (31) is configured to inject high-pressure gas into the cylinder (36) to move the piston (37) and the rod (38) relative to the cylinder (36). Switch device. In claim 1 or 2,
The switching mechanism (25) includes a movable member (26) connected to the movable contact (13) and a switching operation for moving the movable member (26) to open and close the movable contact (13). Part (25a),
In the actuator (30), the gas operating mechanism (32) is coupled to the movable member (26), and the movable contactor (13) is moved from the fixed contactor (12) by the operation of the gas generator (31). A switch device configured to move the movable member (26) for separation. In claim 1 or 2,
In the actuator (30), the gas actuating mechanism (32) is connected to the movable contact (13), and the movable contact (13) is fixed to the fixed contact (12) by the operation of the gas generator (31). A switch device configured to move the movable contact (13) so as to be separated from the switch. In any one of Claims 1-4,
A casing (15) in which the contact mechanism (20) and the switching mechanism (25) are housed;
The switch device according to claim 1, wherein the actuator (30) is provided outside the casing (15). In any one of Claims 1-4,
A casing (15) in which the contact mechanism (20) and the switching mechanism (25) are housed;
The switch device, wherein the actuator (30) is provided inside the casing (15). In claim 2,
The rod (38) has a tip positioned laterally between the movable contact (13a) of the movable contact (13) and the fixed contact (12a) of the fixed contact (12), and the movable contact (13a) and the fixed contact (12a) provided so that the axis extends in the direction of the contact surface,
In the actuator (30), the rod (38) is inserted between the movable contact (13a) and the fixed contact (12a) by the operation of the gas generator (31), and the movable contact (13) Is configured to be separated from the fixed contact (12). In claim 7,
The switch device, wherein the rod (38) is formed of a non-conductive material. In claim 7,
The switch device, wherein the rod (38) is made of a metal material. In claim 7,
The rod (38) penetrates between the movable contact (13a) of the movable contact (13) and the fixed contact (12a) of the fixed contact (12) by the operation of the gas generator (31). A switch device characterized in that the distal end portion (38a) is formed of a metal material, and at least the surface of the proximal end side of the distal end portion (38a) of the metal material is formed of a non-conductive material. In claim 9,
The switch device according to claim 1, wherein the rod (38) is formed with a thickness smaller than a contact gap between the movable contact (13) and the fixed contact (12). In claim 1 or 2,
The actuator (30) includes a blocking mechanism (45) that prevents the gas operating mechanism (32) from returning to the initial state before driving after the gas operating mechanism (32) is driven. In claim 1 or 2,
A casing (15) in which the contact mechanism (20) and the switching mechanism (25) are housed;
The actuator (30) is located in a communication hole (15b) that communicates the inside and outside of the casing (15), moves with the driving of the gas operation mechanism (32), and is configured to be visible from the outside. A switch device comprising a display member (50). In any one of Claims 1-13,
A switch device comprising a trip mechanism (60) that moves the switching mechanism (25) so that the movable contact (13) moves away from the fixed contact (12) when an abnormal current flows. In claim 14,
The gas generator (31) of the actuator (30) has a high pressure when the trip mechanism (60) operates and the contact state between the fixed contact (12) and the movable contact (13) is in a predetermined state. A switch device configured to generate gas.

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