ELECTRIC CIRCUIT BREAKER DEVICE

Abstract

An electric circuit breaker device includes: an igniter provided to a housing; a projectile disposed in an accommodating space formed in the housing, the projectile being to be projected along the accommodating space by energy received from the igniter; a conductor piece that is provided to the housing, forms a portion of an electric circuit, includes in a portion thereof a cutoff portion to be cut off by the projectile, and is disposed with the cutoff portion crossing the accommodating space; an arc-extinguishing region positioned on a side opposite to the projectile prior to actuation of the igniter with the cutoff portion interposed between the arc-extinguishing region and the projectile, and configured to receive the cutoff portion cut off by the projectile; a first coolant material disposed in the arc-extinguishing region; and a second coolant material disposed between the projectile and the cutoff portion in the accommodating space prior to actuation of the igniter.

Description

TECHNICAL FIELD

The present invention relates to an electric circuit breaker device.

BACKGROUND ART

An electric circuit may be provided with a breaker device configured to be actuated when an abnormality occurs in a device constituting the electric circuit or when an abnormality occurs in a system in which the electric circuit is mounted, thereby urgently interrupting the continuity of the electric circuit. Electric circuit breaker devices have been proposed in which, according to one aspect thereof, a projectile is moved at high speed by energy applied from an igniter or the like to forcibly and physically cut a conductor piece that forms a portion of an electric circuit (refer to Patent Documents 1 and 2 and the like, for example). Further, in recent years, electric circuit breaker devices applied to electric vehicles equipped with a high-voltage power source are becoming increasingly important.

CITATION LIST

Patent Literature

• Patent Document 1: WO 2020/093079
• Patent Document 2: U.S. Pat. No. 8,957,335

SUMMARY OF INVENTION

Technical Problem

In an electric circuit breaker device, an arc is likely to be generated when a conductor piece forming a portion of an electric circuit is cut. When an arc is generated, the electric circuit cannot be interrupted quickly, and thus the electric circuit breaker device must quickly extinguish the generated arc.

The technique of the present disclosure has been made in view of the circumstances described above, and an object thereof is to provide an electric circuit breaker device capable of quickly extinguishing an arc during actuation.

Solution to Problem

To solve the problems described above, in the present disclosure, in addition to a first coolant arranged in an arc-extinguishing region formed in a housing of an electric circuit breaker device and configured to receive a cutoff portion of a conductor piece, a second coolant material is arranged between a projectile and the cutoff portion in an accommodating space.

More specifically, an electric circuit breaker device according to the present disclosure includes: an igniter provided to a housing; a projectile disposed in an accommodating space, the accommodating space being formed in the housing and extending in one direction, the projectile being to be projected along the accommodating space by energy received from the igniter; a conductor piece that is provided to the housing, forms a portion of an electric circuit, includes in a portion thereof a cutoff portion to be cut off by the projectile that moves by the energy received from the igniter, and is disposed with the cutoff portion crossing the accommodating space; an arc-extinguishing region positioned within the accommodating space, on a side opposite to the projectile prior to actuation of the igniter with the cutoff portion interposed between the arc-extinguishing region and the projectile, and configured to receive the cutoff portion cut off by the projectile; a first coolant material disposed in the arc-extinguishing region; and a second coolant material disposed between the projectile and the cutoff portion in the accommodating space prior to actuation of the igniter.

Here, in the electric circuit breaker device according to the present disclosure, the second coolant material may be solid. The second coolant material may be formed from a shape retaining body. For example, the second coolant material may be formed from a metal fiber. In this case, the metal fiber forming the second coolant material may include at least any one of steel wool or copper wool.

Advantageous Effects of Invention

According to the present disclosure, it is possible to provide an electric circuit breaker device capable of quickly extinguishing an arc that is generated during actuation.

BRIEF DESCRIPTION OF DRAWINGS

FIG. 1 is a view illustrating an internal structure of a breaker device.

FIG. 2 is a top view of a conductor piece.

FIG. 3 is a view illustrating actuation situations of the breaker device.

FIG. 4 is a view schematically illustrating a testing device used in an electric circuit interruption test.

FIG. 5 shows graphs of results of the electric circuit interruption test.

DESCRIPTION OF EMBODIMENTS

An electric circuit breaker device according to an embodiment of the present disclosure will be described below with reference to the drawings. Note that the configurations, combinations thereof, and the like in the embodiment are examples, and various additions, omissions, substitutions, and other changes may be made as appropriate without departing from the spirit of the present disclosure. The present disclosure is not limited by the embodiments and is limited only by the claims.

Configuration

FIG. 1 is a view illustrating an internal structure of an electric circuit breaker device (hereinafter simply referred to as the “breaker device”) 1 according to an embodiment. The breaker device 1 is a device configured to interrupt an electric circuit included in a vehicle, an electric home appliance, or the like when an abnormality occurs in the electric circuit or in a system including a lithium battery (lithium ion battery, for example) of the electric circuit, thereby preventing great damage, for example. In the present specification, a cross section in the height direction illustrated in FIG. 1 (direction in which an accommodating space 13 described later extends) is referred to as a vertical cross section of the breaker device 1, and a cross section in a direction orthogonal to the vertical cross section is referred to as a transverse cross section of the breaker device 1. FIG. 1 illustrates a state prior to actuation of the breaker device 1.

The breaker device 1 includes a housing 10 as an outer shell member, an igniter 20, a projectile 40, a conductor piece 50, a first coolant material 60, and a second coolant material 70. The housing 10 includes the accommodating space 13 that extends in a direction from a first end portion 11 on an upper end side to a second end portion 12 on a lower end side. This accommodating space 13 is a space formed in a straight line, making the projectile 40 movable, and extends along a vertical direction of the breaker device 1. As illustrated in FIG. 1, the accommodating space 13 formed inside the housing 10 accommodates the projectile 40. However, in the present specification, the vertical direction of the breaker device 1 merely indicates a relative positional relationship among the elements in the breaker device 1 for convenience of description of the embodiment.

Housing

The housing 10 includes a housing body 100, a top holder 110, and a bottom container 120. The housing body 100 is bonded to the top holder 110 and the bottom container 120, thereby forming the housing 10 that is integral.

The housing body 100 has, for example, a substantially prismatic outer shape. However, the shape of the housing body 100 is not particularly limited. The housing body 100 includes a cavity portion formed therethrough along the vertical direction. This cavity portion forms a portion of the accommodating space 13. Furthermore, the housing body 100 includes an upper surface 101 to which a flange portion 111 of the top holder 110 is fixed and a bottom surface 102 to which a flange portion 121 of the bottom container 120 is fixed. In the present embodiment, an upper tubular wall 103 having a tubular shape is provided erected upward from the upper surface 101 on the outer circumferential side of the upper surface 101 in the housing body 100. In the present embodiment, the upper tubular wall 103 has a rectangular tubular shape, for example, but may have other shapes. On the outer circumferential side of the lower surface 102 in the housing body 100, a lower tubular wall 104 having a tubular shape is provided suspended downward from the lower surface 102. In the present embodiment, the lower tubular wall 104 has a rectangular tubular shape, for example, but may have other shapes. The housing body 100 configured as described above can be formed from an insulating member such as a synthetic resin, for example. For example, the housing body 100 may be formed from nylon, which is a type of polyamide synthetic resin.

Top Holder

Next, the top holder 110 will be described. The top holder 110 is, for example, a cylindrical member having a stepped cylindrical tubular shape with a hollow inside. The top holder 110 includes a small diameter cylinder portion 112 positioned on the upper side (first end portion 11 side), a large diameter cylinder portion 113 positioned on the lower side, a connection portion 114 connecting these, and the flange portion 111 extending outward from a lower end of the large diameter cylinder portion 113. For example, the small diameter cylinder portion 112 and the large diameter cylinder portion 113 are coaxially disposed, and the large diameter cylinder portion 113 has a diameter slightly larger than that of the small diameter cylinder portion 112.

The contour of the flange portion 111 in the top holder 110 has a substantially quadrangular shape that fits inside the upper tubular wall 103 in the housing body 100. For example, the flange portion 111 may be integrally fastened to the upper surface 101 in the housing body 100 using a screw or the like, or may be fixed thereto by a rivet or the like, in a state of being disposed inside the upper tubular wall 103. Further, the top holder 110 may be bonded to the housing body 100 in a state where a sealant is applied between the upper surface 101 of the housing body 100 and a lower surface of the flange portion 111 in the top holder 110. This can increase airtightness of the accommodating space 13 formed in the housing 10. Further, instead of the sealant or in combination with the sealant, an O-ring may be interposed between the upper surface 101 of the housing body 100 and the flange portion 111 of the top holder 110 to increase the airtightness of the accommodating space 13.

The cavity portion formed inside the small diameter cylinder portion 112 in the top holder 110 functions as an accommodating space for accommodating a portion of the igniter 20 as illustrated in FIG. 1. Further, the cavity portion formed inside the large diameter cylinder portion 113 in the top holder 110 communicates with the cavity portion of the housing body 100 positioned below, and forms a portion of the accommodating space 13. The top holder 110 configured as described above can be formed from an appropriate metal member, such as stainless steel or aluminum, having excellent strength and durability, for example. However, a material for forming the top holder 110 is not particularly limited. Also, for the shape of the top holder 110, the above aspect is an example and other shapes may be adopted.

Bottom Container

Next, the bottom container 120 will be described. The bottom container 120 has a substantially tubular bottomed shape with a hollow inside, and includes a side wall portion 122, a bottom wall portion 123 connected to a lower end of the side wall portion 122, and a flange portion 121 connected to an upper end of the side wall portion 122. The side wall portion 122 has, for example, a cylindrical tubular shape. The flange portion 121 extends outward from the upper end of the side wall portion 122. The contour of the flange portion 121 in the bottom container 120 has a substantially quadrangular shape that fits inside the lower tubular wall 104 in the housing body 100. For example, the flange portion 121 may be integrally fastened to the lower surface 102 in the housing body 100 using a screw or the like, or may be fixed thereto by a rivet or the like, in a state of being disposed inside the lower tubular wall 104. Here, the bottom container 120 may be bonded to the housing body 100 in a state where the sealant is applied between the lower surface 102 of the housing body 100 and an upper surface of the flange portion 121 in the bottom container 120. This can increase airtightness of the accommodating space 13 formed in the housing 10. Further, instead of the sealant or in combination with the sealant, an O-ring may be interposed between the lower surface 102 of the housing body 100 and the flange portion 121 of the bottom container 120 to increase the airtightness of the accommodating space 13.

Note that the above aspect regarding the shape of the bottom container 120 is an example, and other shapes may be adopted. Further, the cavity portion formed inside the bottom container 120 communicates with the housing body 100 positioned above, and forms a portion of the accommodating space 13. The bottom container 120 configured as described above can be formed from an appropriate metal member, such as stainless steel or aluminum, having excellent strength and durability, for example. However, a material for forming the bottom container 120 is not particularly limited. Further, the bottom container 120 may have a multilayer structure. For example, in the bottom container 120, an exterior portion facing the outside may be formed from an appropriate metal member, such as stainless steel or aluminum, having excellent strength and durability, and an interior portion facing the accommodating space 13 may be formed from an insulating member such as a synthetic resin. Of course, the entire bottom container 120 may be formed from an insulating member.

As described above, the housing 10 in the embodiment includes the housing body 100, the top holder 110, and the bottom container 120 that are integrally assembled, and the accommodating space 13 extending in the direction from the first end portion 11 to the second end portion 12 is formed inside the housing 10. The accommodating space 13 accommodates the igniter 20, the projectile 40, a cutoff portion 53 in the conductor piece 50, the first coolant material 60, and the second coolant material 70 that are described below in detail.

Igniter

Next, the igniter 20 will be described. The igniter 20 is an electric igniter that includes an ignition portion 21 with an ignition charge, and an igniter body 22 including a pair of conduction pins (not illustrated) connected to the ignition portion 21. The igniter body 22 is surrounded by an insulating resin, for example. Further, tip end sides of the pair of conduction pins in the igniter body 22 are exposed to the outside, and are connected to a power source when the breaker device 1 is used.

The igniter body 22 includes a body portion 221 having a substantially cylindrical shape and accommodated inside the small diameter cylinder portion 112 in the top holder 110, and a connector portion 222 positioned on the body portion 221. The igniter body 22 is fixed to the small diameter cylinder portion 112 by, for example, the body portion 221 being pressed to an inner circumferential surface of the small diameter cylinder portion 112. Further, a constricted portion having an outer circumferential surface recessed as compared with other locations is annularly formed along a circumferential direction of the body portion 221 at an axially intermediate portion of the body portion 221. An O-ring 223 is fitted into this constricted portion. The O-ring 223 is formed from, for example, rubber (silicone rubber, for example) or a synthetic resin, and functions to increase airtightness between the inner circumferential surface in the small diameter cylinder portion 112 and the body portion 221.

The connector portion 222 in the igniter 20 is disposed protruding to the outside through an opening 112A formed at an upper end of the small diameter cylinder portion 112. The connector portion 222 has, for example, a cylindrical tubular shape covering a side of the conduction pin, allowing connection with a connector of a power source.

As illustrated in FIG. 1, the ignition portion 21 of the igniter 20 is disposed facing the accommodating space 13 (more specifically, the cavity portion formed inside the large diameter cylinder portion 113) of the housing 10. The ignition portion 21 is configured as a form accommodating an ignition charge in an igniter cup, for example. For example, the ignition charge is accommodated in the igniter cup in the ignition portion 21 in a state of being in contact with a bridge wire (resistor) suspended coupling the base ends of the pair of conduction pins to each other. As the ignition charge, for example, zirconium—potassium perchlorate (ZPP), zirconium—tungsten— potassium perchlorate (ZWPP), titanium hydride—potassium perchlorate (THPP), lead tricinate, or the like may be adopted.

In actuation of the igniter 20, when an actuating current for igniting the ignition charge is supplied from the power source to the conduction pins, the bridge wire in the ignition portion 21 generates heat, and as a result, the ignition charge in the igniter cup is ignited and burns, generating a combustion gas. Then, the pressure in the igniter cup increases along with the combustion of the ignition charge in the igniter cup of the ignition portion 21, a rupture surface 21A of the igniter cup ruptures, and the combustion gas is discharged from the igniter cup into the accommodating space 13. More specifically, the combustion gas from the igniter cup is discharged into a recess 411 in a piston portion 41 described later of the projectile 40 disposed in the accommodating space 13.

Projectile

Next, the projectile 40 will be described. The projectile 40 is formed from an insulating member such as synthetic resin, for example, and includes the piston portion 41 and a rod portion 42 connected to the piston portion 41. The piston portion 41 has a substantially cylindrical shape and has an outer diameter substantially corresponding to an inner diameter of the large diameter cylinder portion 113 in the top holder 110. For example, the diameter of the piston portion 41 may be slightly smaller than the inner diameter of the large diameter cylinder portion 113. The shape of the projectile 40 can be changed as appropriate according to the shape of the housing 1 and the like.

Further, the recess 411 having a cylindrical shape, for example, is formed on an upper surface of the piston portion 41. This recess 411 receives the ignition portion 21. A bottom surface of the recess 411 is formed as a pressure receiving surface 411A that receives energy received from the igniter 20 during actuation of the igniter 20. Further, a constricted portion having an outer circumferential surface recessed as compared with other locations is annularly formed along a circumferential direction of the piston portion 41 at an axially intermediate portion of the piston portion 41. An O-ring 43 is fitted into this constricted portion. The O-ring 43 is formed from, for example, rubber (silicone rubber, for example) or a synthetic resin, and functions to increase airtightness between an inner circumferential surface in the large diameter cylinder portion 113 and the piston portion 41.

The rod portion 42 of the projectile 40 is a rod-shaped member having an outer circumferential surface smaller in diameter than the piston portion 41, for example, and is integrally connected to a lower end side of the piston portion 41. A lower end surface of the rod portion 42 is formed as a cutoff surface 421 for cutting off the cutoff portion 53 from the conductor piece 50 during actuation of the breaker device 1. Note that although the rod portion 42 in the present embodiment has a substantially cylindrical tubular shape, the shape thereof is not particularly limited, and can be changed in accordance with the shape and size of the cutoff portion 53 to be cut off from the conductor piece 50 during actuation of the breaker device 1. The rod portion 42 may have a columnar shape such as a cylinder or a prism, for example. Note that, in an initial position of the projectile 40 illustrated in FIG. 1, a region on a tip end side including the cutoff surface 421 in the rod portion 42 of the projectile 40 is positioned in the cavity portion (forming a portion of the accommodating space 13) of the housing body 100. The diameter of the rod portion 42 is slightly smaller than the inner diameter of an inner circumferential surface of the housing body 100, for example, and the outer circumferential surface of the rod portion 42 is guided along the inner circumferential surface when the projectile 40 is projected.

As described in detail later, the projectile 40 configured as described above is projected from the initial position illustrated in FIG. 1 when the upper surface of the piston portion 41 including the pressure receiving surface 411A receives the energy from the igniter 20 during actuation of the igniter 20, and moves at high speed toward the second end portion 12 side (downward) along the accommodating space 13. Specifically, as illustrated in FIG. 1, the piston portion 41 of the projectile 40 is accommodated inside the large diameter cylinder portion 113 in the top holder 110, and is slidable in the axial direction along an inner wall surface of the large diameter cylinder portion 113. In the present embodiment, the piston portion 41 of the projectile 40 has a substantially cylindrical shape, but the shape thereof is not particularly limited. As the outer shape of the piston portion 41, an appropriate shape and size can be adopted in accordance with the shape and size of the inner wall surface of the large diameter cylinder portion 113.

Conductor Piece

Next, the conductor piece 50 will be described. FIG. 2 is a top view of the conductor piece 50 according to the embodiment. The conductor piece 50 is a metal body having conductivity that constitutes a portion of the components of the breaker device 1 and, when the breaker device 1 is attached to a predetermined electric circuit, forms a portion of the electric circuit, and may be referred to as a bus bar. The conductor piece 50 can be formed from a metal such as copper (Cu), for example. However, the conductor piece 50 may be formed from a metal other than copper, or may be formed from an alloy of copper and another metal. Note that examples of metals other than copper included in the conductor piece 50 include manganese (Mn), nickel (Ni), and platinum (Pt).

In one aspect illustrated in FIG. 2, the conductor piece 50 is formed as an elongated flat plate piece as a whole, and includes a first connecting end portion 51 and a second connecting end portion 52 on both end sides, and the cutoff portion 53 positioned in an intermediate portion therebetween. Connection holes 51A, 52A are provided in the first connecting end portion 51 and the second connecting end portion 52 of the conductor piece 50, respectively. These connection holes 51A, 52A are used to connect with other conductors (lead wires, for example) in the electric circuit. Note that in FIG. 1, the connection holes 51A and 52A in the conductor piece 50 are not illustrated. The cutoff portion 53 of the conductor piece 50 is a portion forcibly and physically cut by the rod portion 42 of the projectile 40 and is cut off from the first connecting end portion 51 and the second connecting end portion 52 when an abnormality such as excessive current occurs in the electric circuit to which the breaker device 1 is applied. Notches (slits) 54 are formed at both ends of the cutoff portion 53 of the conductor piece 50, making it easy to cut and cut off the cutoff portion 53.

Here, various forms of the conductor piece 50 can be adopted, and a shape thereof is not particularly limited. While, in the example illustrated in FIG. 2, surfaces of the first connecting end portion 51, the second connecting end portion 52, and the cutoff portion 53 form the same surface, the form is not limited thereto. For example, the conductor piece 50 may be connected such that the cutoff portion 53 is orthogonal to or inclined relative to the first connecting end portion 51 and the second connecting end portion 52. Further, the planar shape of the cutoff portion 53 of the conductor piece 50 is not particularly limited, either. Of course, the shapes of the first connecting end portion 51 and the second connecting end portion 52 of the conductor piece 50 are not particularly limited, either. Further, the notches 54 in the conductor piece 50 can be omitted as appropriate.

Here, a pair of conductor piece holding holes 105A and 105B are formed in the housing body 100 according to the embodiment. The pair of conductor piece holding holes 105A and 105B extend in a transverse cross-sectional direction orthogonal to the vertical direction (axial direction) of the housing body 100. More specifically, the pair of conductor piece holding holes 105A and 105B extend in a straight line with the cavity portion (accommodating space 13) of the housing body 100 interposed therebetween. The conductor piece 50 configured as described above is held in the housing body 100 in a state of being inserted through the pair of conductor piece holding holes 105A and 105B formed in the housing body 100. In the example illustrated in FIG. 1, the first connecting end portion 51 of the conductor piece 50 is held in a state of being inserted through the conductor piece holding hole 105A, and the second connecting end portion 52 is held in a state of being inserted through the conductor piece holding hole 105B. In this state, the cutoff portion 53 of the conductor piece 50 is positioned in the cavity portion (accommodating space 13) of the housing body 100. As described above, the conductor piece 50 attached to the housing body 100 is held orthogonally to the extending direction (axial direction) of the accommodating space 13 with the cutoff portion 53 crossing the accommodating space 13. Note that reference sign L1 illustrated in FIG. 2 denotes an outer circumferential position of the rod portion 42 positioned above the conductor piece 50 in a state of being attached to the housing body 100 of the breaker device 1. In the present embodiment, the conductor piece 50 is installed with the outer circumferential position L1 of the rod portion 42 substantially overlapping the positions of the notches 54 positioned at both ends of the cutoff portion 53. In the present embodiment, for example, since a transverse cross-sectional area of the accommodating space 13 is larger than a transverse cross-sectional area of the cutoff portion 53, a gap is formed on the side of the cutoff portion 53.

Coolant Material

Next, the first coolant material 60 and the second coolant material 70 disposed in the accommodating space 13 in the housing 10 will be described. Here, as illustrated in FIG. 1, prior to actuation of the breaker device 1 (igniter 20), the cutoff portion 53 of the conductor piece 50 in a state of being held in the pair of conductor piece holding holes 105A and 105B in the housing body 100 is horizontally laid crossing the accommodating space 13 of the housing 10. Hereinafter, within the accommodating space 13 of the housing 10 separated by the cutoff portion 53 of the conductor piece 50, a region (space) in which the projectile 40 is disposed is referred to as a “projectile initial arrangement region R1”, and a region (space) positioned on the opposite side of the projectile 40 is referred to as an “arc-extinguishing region R2”. Note that as described above, since the gap is formed on the side of the cutoff portion 53 disposed crossing the accommodating space 13, the projectile initial arrangement region R1 and the arc-extinguishing region R2 are not completely isolated from each other by the cutoff portion 53, but communicate with each other. Of course, depending on the shape and size of the cutoff portion 53, the projectile initial arrangement region R1 and the arc-extinguishing region R2 may be completely isolated from each other by the cutoff portion 53.

The arc-extinguishing region R2 of the accommodating space 13 is a region (space) for receiving the cutoff portion 53 cut off by the rod portion 42 of the projectile 40 projected during actuation of the breaker device 1 (igniter 20). In this arc-extinguishing region R2, the first coolant material 60 as an arc-extinguishing material is disposed. Furthermore, in the present embodiment, the second coolant material 70 as an arc-extinguishing material is disposed in the projectile initial arrangement region R1. More specifically, the second coolant material 70 is disposed between the projectile 40 and the cutoff portion 53 in the accommodating space 13 prior to actuation of the breaker device 1 (igniter 20). The first coolant material 60 and the second coolant material 70 are coolant materials for removing thermal energy of the arc generated and the cutoff portion 53 when the projectile 40 cuts off the cutoff portion 53 of the conductor piece 50, and cooling the arc and the cutoff portion 53, thereby suppressing arc generation during cutting off of a current or thereby extinguishing (eliminating) the generated arc.

The arc-extinguishing region R2 of the breaker device 1 has significance as a space for receiving the cutoff portion 53 cut off from the first connecting end portion 51 and the second connecting end portion 52 of the conductor piece 50 by the projectile 40 and, at the same time, as a space for effectively extinguishing the arc generated when the projectile 40 cuts off the cutoff portion 53. Then, in order to effectively extinguish the arc generated when the cutoff portion 53 is cut off from the conductor piece 50, the first coolant material 60 is disposed as an arc-extinguishing material in the arc-extinguishing region R2.

As one aspect of the embodiment, the first coolant material 60 and the second coolant material 70 are solid. As one aspect of the embodiment, the first coolant material 60 and the second coolant material 70 are formed from a shape retaining body. The shape retaining body herein is, for example, a material that can keep a constant shape when no external force is applied and can hold the integrity (does not come apart), even if deformation can occur, when an external force is applied. For example, examples of the shape retaining body include a fibrous body formed into a desired shape. In the present embodiment, the first coolant material 60 and the second coolant material 70 are formed from a metal fiber that is a shape retaining body. Here, examples of the metal fiber forming the first coolant material 60 and the second coolant material 70 include an aspect in which at least any one of steel wool or copper wool is included. However, the above aspects in the first coolant material 60 and the second coolant material 70 are examples, and the first coolant material 60 and the second coolant material 70 are not limited to the above aspects.

The first coolant material 60 is formed into a substantially disk shape, for example, and is disposed at a bottom portion of the bottom container 120. The second coolant material 70 is formed into a substantially disk shape having a diameter corresponding to the rod portion 42 of the projectile 40, for example, and has a diameter substantially equal to the outer diameter of the rod portion 42. As described above, the outer circumferential position L1 of the rod portion 42 substantially coincides with the positions of the notches 54 positioned at both ends of the cutoff portion 53. Therefore, the outer circumferential position of the second coolant material 70 also coincides with the positions of the notches 54 provided at both ends of the cutoff portion 53 (that is, an expected cutoff position of the cutoff portion 53).

Operation

Next, operation content when the breaker device 1 is actuated to interrupt the electric circuit will be described. As described above, FIG. 1 illustrates a state of the breaker device 1 prior to actuation (hereinafter also referred to as the “pre-actuation initial state”). In this pre-actuation initial state, in the projectile 40 in the breaker device 1, the piston portion 41 is positioned on the first end portion 11 side (upper end side) in the accommodating space 13, and the cutoff surface 421 formed at the lower end of the rod portion 42 is set at an initial position positioned on the upper surface of the second coolant material 70 placed on the cutoff portion 53 in the conductor piece 50. That is, in the pre-actuation initial state, the projectile 40 is set in a state where the second coolant material 70 is sandwiched between the rod portion 42 and the cutoff portion 53.

Furthermore, the breaker device 1 according to the embodiment further includes an abnormality detection sensor (not illustrated) configured to detect an abnormal current of the electric circuit, and a control unit (not illustrated) configured to control the actuation of the igniter 20. In addition to the current flowing through the conductor piece 50, the abnormality detection sensor may be capable of detecting a voltage and a temperature of the conductor piece 50. Further, the control unit of the breaker device 1 is a computer capable of performing a predetermined function by executing a predetermined control program, for example. The predetermined function of the control unit may be realized by corresponding hardware. Then, when excessive current flows through the conductor piece 50 forming a portion of the electric circuit to which the breaker device 1 is applied, the abnormal current is detected by the abnormality detection sensor. Abnormality information regarding the detected abnormal current is passed from the abnormality detection sensor to the control unit. For example, the control unit is energized from an external power source (not illustrated) connected to the conduction pin of the igniter 20 and actuates the igniter based on the current value detected by the abnormality detection sensor. Here, the abnormal current may be a current value that exceeds a predetermined threshold value set for protection of a predetermined electric circuit. Note that the abnormality detection sensor and the control unit described above need not be included in the components of the breaker device 1, and may be included in a device separate from the breaker device 1, for example. Further, the abnormality detection sensor and the control unit are not essential components of the breaker device 1.

For example, when an abnormal current of the electric circuit is detected by an abnormality detection sensor that detects an abnormal current of the electric circuit, the control unit of the breaker device 1 actuates the igniter 20. That is, an actuating current is supplied from the external power source (not illustrated) to the conduction pin of the igniter 20, and as a result, the ignition charge in the ignition portion 21 is ignited and burns, generating a combustion gas. Then, the rupture surface 21A ruptures due to rise in pressure in the ignition portion 21, and the combustion gas of the ignition charge is discharged from the inside of the ignition portion 21 into the accommodating space 13.

Here, the ignition portion 21 of the igniter 20 is received in the recess 411 of the piston portion 41, and the rupture surface 21A of the ignition portion 21 is disposed facing the pressure receiving surface 411A of the recess 411 in the projectile 40. Therefore, the combustion gas from the ignition portion 21 is discharged to the recess 411, and the pressure (combustion energy) of the combustion gas is transmitted to the upper surface of the piston portion 41 including the pressure receiving surface 411A. As a result, the projectile 40 moves downward in the accommodating space 13 in the extending direction (axial direction) of the accommodating space 13.

FIG. 3 is a view illustrating actuation situations of the breaker device 1 according to the embodiment. The upper half of FIG. 3 illustrates a situation in the middle of actuation of the breaker device 1, and the lower half of FIG. 3 illustrates a situation in which the actuation of the breaker device 1 is completed. As described above, upon actuation of the igniter 20, the projectile 40 having received the pressure (combustion energy) of the combustion gas of the ignition charge is vigorously pushed downward. As a result, the cutoff surface 421 formed on the lower end side of the rod portion 42 pressingly cuts, by shearing, the boundary portions between the first connecting end portion 51 and the cutoff portion 53 and between the second connecting end portion 52 and the cutoff portion 53 in the conductor piece 50. As a result, the cutoff portion 53 is cut off from the conductor piece 50. Note that as long as the projectile 40 can be moved smoothly in the extending direction (axial direction) of the accommodating space 13 when the igniter 20 is actuated, the shape and the dimensions of the projectile 40 can be freely determined, and the outer diameter of the piston portion 41 of the projectile 40 may be set to a dimension equal to the inner diameter of the large diameter cylinder portion 113 in the top holder 110, for example. Then, as illustrated in the lower half of FIG. 3, the projectile 40 moves downward in the extending direction (axial direction) of the accommodating space 13 by a predetermined stroke until the lower end surface of the piston portion 41 abuts (collides with) the upper surface 101 of the housing body 100. Then, in this state, the cutoff portion 53, which has been cut off from the conductor piece 50 by the rod portion 42 of the projectile 40, is received in the arc-extinguishing region R2 where the first coolant material 60 is disposed. As a result, the first connecting end portion 51 and the second connecting end portion 52 positioned on both ends of the conductor piece 50 are electrically disconnected, and the predetermined electric circuit to which the breaker device 1 is applied is forcibly interrupted.

In the breaker device 1 of the embodiment, the first coolant material 60 is disposed in the arc-extinguishing region R2. Therefore, the cutoff portion 53 after being cut off that has been received in the arc-extinguishing region R2 can be rapidly cooled by the first coolant material 60. Thus, when the cutoff portion 53 is cut off from the conductor piece 50 constituting a portion of the predetermined electric circuit by the projectile 40, even in a case where an arc is generated at the cut surface of the cutoff portion 53 of the conductor piece 50, the generated arc can be quickly and effectively extinguished.

Furthermore, in the breaker device 1, the second coolant material 70 as an arc-extinguishing material is disposed in the projectile initial arrangement region R1. Thus, the cutoff portion 53 can be cut off from the conductor piece 50 in a state where the second coolant material 70 is sandwiched between the cutoff surface 421 in the rod portion 42 and the cutoff portion 53. Furthermore, with the state in which the second coolant material 70 is in contact with the cutoff portion 53 maintained even thereafter, the cutoff portion 53 can be received in the arc-extinguishing region R2 where the first coolant material 60 is disposed as illustrated in the lower half of FIG. 3. Accordingly, as illustrated in the upper half of FIG. 3, the cutoff portion 53 can be continuously cooled by the second coolant material 70 even at the moment when the cutoff portion 53 is cut off from the conductor piece 50 by the cutoff surface 421 of the rod portion 42 and immediately thereafter, that is, in a transient state from the moment when the cutoff portion 53 is cut off from the conductor piece 50 to when the cutoff portion 53 comes into contact with the first coolant material 60 disposed in the arc-extinguishing region R2. This makes it possible to suitably suppress the generation of an arc at the cut surface of the cutoff portion 53 in the transient state at the moment when the cutoff portion 53 is cut off from the conductor piece 50 and immediately thereafter.

As described above, according to the breaker device 1 of the present embodiment, the cutoff portion 53 is cooled in two stages by the first coolant material 60 and the second coolant material 70, and arc generation can be effectively suppressed. As a result, it is possible to quickly interrupt the electric circuit to which the breaker device 1 is applied in a case where an abnormality is detected in the electric circuit, or the like. That is, by effectively suppressing delay in extinguishing of the arc generated when the electric circuit is interrupted, it is possible to suppress delay in interruption of the electric circuit. Further, according to the breaker device 1, it is possible to suitably suppress the generation of a large spark or flame or the generation of a loud impact sound when the electric circuit is interrupted. Further, damage to the housing 10 and the like of the breaker device 1 caused by these can also be suppressed.

Further, according to the breaker device 1 of the present embodiment, since the first coolant material 60 and the second coolant material 70 are formed from a solid arc-extinguishing material, it is easy to form the first coolant material 60 and the second coolant material 70 into a desired shape as compared with a case where, for example, a liquid or gel arc-extinguishing material is adopted. In particular, the second coolant material 70 is disposed between the rod portion 42 of the projectile 40 and the cutoff portion 53 prior to actuation of the breaker device 1 (igniter 20). In particular, the second coolant material 70 being a solid arc-extinguishing material has an advantage in that it is easy to dispose the second coolant material 70 in a state of being sandwiched between the rod portion 42 and the cutoff portion 53. Therefore, for example, even in an environment where a gap is formed on the side of the cutoff portion 53 in the accommodating space 13 and the projectile initial arrangement region R1 and the arc-extinguishing region R2 communicate with each other through the gap, the second coolant material 70 can be suppressed from falling off or spilling into the arc-extinguishing region R2 through the gap prior to actuation of the breaker device 1 (igniter 20).

Furthermore, forming the second coolant material 70 from a shape retaining body obtained by forming a metal fiber has the following further advantages. That is, prior to actuation of the breaker device 1, it is easy to maintain the second coolant material 70 in a constant shape in a state of being sandwiched between the rod portion 42 and the cutoff portion 53. Furthermore, even when the second coolant material 70 is vigorously pressed against the cutoff portion 53 by the rod portion 42 during actuation of the breaker device 1, the second coolant material 70 is less likely to come apart. Accordingly, it is easy to maintain the second coolant material 70 in a state of being in contact with the cutoff portion 53 from when the cutting off of the cutoff portion 53 by the rod portion 42 is started during actuation of the breaker device 1 to when the cutoff portion 53 after being cut off comes into contact with the first coolant material 60 disposed in the arc-extinguishing region R2. Therefore, it is possible to more suitably suppress the generation of an arc during actuation of the breaker device 1. However, as long as the second coolant material 70 can be disposed between the projectile 40 and the cutoff portion 53 in the accommodating space 13 prior to actuation of the breaker device 1 (igniter 20), the second coolant material 70 need not necessarily be formed from a shape retaining body, and need not be a solid arc-extinguishing material. For example, the second coolant material 70 may be formed by compression-forming a powdered or granular material, or the second coolant material 70 may be formed from a liquid or gel arc-extinguishing material.

Note that for the breaker device 1 according to the embodiment, various modifications can be adopted. For example, the shape, position, range, and the like of the first coolant material 60 disposed in the arc-extinguishing region R2 of the accommodating space 13 can be changed as appropriate. For example, the first coolant material 60 made of a metal fiber may be disposed over the entire region formed inside the bottom container 120 or the entire arc-extinguishing region R2. Then, during actuation of the breaker device 1, the cutoff portion 53 cut off from the conductor piece 50 by the projectile 40 may be quenched by being buried in the first coolant material 60.

Further, the mode of installation of the second coolant material 70 disposed in the projectile initial arrangement region R1 of the accommodating space 13 is not limited to the above aspects. For example, in the example illustrated in FIG. 1, the second coolant material 70 is disposed in a state of abutting the cutoff surface 421 of the rod portion 42 in the projectile 40 prior to actuation of the breaker device 1, but the second coolant material 70 is not limited thereto. For example, the second coolant material 70 may be disposed on the cutoff portion 53 with a gap formed between the cutoff surface 421 of the rod portion 42 and the second coolant material 70. Further, prior to actuation of the breaker device 1, for example, the second coolant material 70 may be disposed with a gap formed between the second coolant material 70 and the cutoff portion 53 by fixing the second coolant material 70 to the cutoff surface 421 of the rod portion 42 or the like. Further, in the example illustrated in the lower half of FIG. 3, after actuation of the breaker device 1, the cutoff surface 421 of the rod portion 42 in the projectile 40 and the second coolant material 70 are in a state of being away from each other, but the cutoff surface 421 of the rod portion 42 and the second coolant material 70 may be in a state of being in contact with each other. In this case, the second coolant material 70 and the cutoff portion 53 may be pressed to the bottom portion side of the arc-extinguishing region R2 while the second coolant material 70 is maintained in a state of being in contact with the cutoff surface 421 of the rod portion 42 of the projectile 40 projected during actuation of the breaker device 1, for example.

Electric Circuit Interruption Test

Next, an electric circuit interruption test performed on the breaker device 1 will be described. FIG. 4 is a view schematically illustrating a testing device used in the electric circuit interruption test. Reference sign 1000 denotes a power source, reference sign 2000 denotes an insulation resistance meter, and reference sign 3000 denotes an actuation power source. Further, reference sign 4000 denotes wiring for forming an electric circuit EC in cooperation with the conductor piece 50 of the breaker device 1. Further, reference sign 5000 denotes wiring for causing an actuation current supplied from the actuation power source 3000 to flow to the conduction pin of the igniter 20 of the breaker device 1.

TABLE 1
Sample information	Insulation resistance
Presence or absence of	Test sample	value/MΩ
second coolant material	No.		Average
Absent	1	1.7	3.7
Absent	2	0.8
Absent	3	4.7
Absent	4	5.5
Absent	5	8.3
Absent	6	1.2
Present	7	9.0	14.7
Present	8	5.5
Present	9	15.1
Present	10	31.0
Present	11	11.8
Present	12	15.7

Table 1 shows a list of conditions and results of the electric circuit interruption test. The test sample Nos. 1 to 6 in the table were tested without the second coolant material 70 disposed between the rod portion 42 of the projectile 40 and the cutoff portion 53 of the conductor piece 50 in the accommodating space 13 of the breaker device 1. On the other hand, the test sample Nos. 7 to 12 were tested with the second coolant material 70 disposed between the rod portion 42 of the projectile 40 and the cutoff portion 53 of the conductor piece 50 in the accommodating space 13 of the breaker device 1. Note that in this test, to verify the influence of the difference in the presence or absence of the second coolant material 70 on the arc-extinguishing performance, the test was conducted without the first coolant material 60 being disposed in the arc-extinguishing region R2 in all the tests.

Next, the steps of the electric circuit interruption test will be described.

(Step 1) As illustrated in FIG. 4, the first connecting end portion 51 and the second connecting end portion 52 of the conductor piece 50 of the breaker device 1 are respectively connected to the power source 1000 by the wiring 4000, and the igniter 20 of the breaker device 1 is connected to the actuation power source 3000 by the wiring 5000.

(Step 2) The current from the power source 1000 is caused to flow to the electric circuit EC.

(Step 3) The actuation power source 3000 is turned on and the actuation current is applied to the igniter 20 of the breaker device 1, thereby actuating the igniter 20.

(Step 4) The power source 1000 and the actuation power source 3000 are turned off.

In the present interruption test, each test sample was tested according to the above steps, and an insulation resistance value between the first connecting end portion 51 and the second connecting end portion 52 when the cutoff portion 53 was cut off from the conductor piece 50 by the projectile 40 was measured by a commercially available insulation resistance meter 2000 (MY40 manufactured by Yokogawa Electric Corporation). Note that as conditions common to all the tests, the value of the current flowing through the electric circuit EC by the power source 1000 was set to 8 [kA], and a potential difference generated between the first connecting end portion 51 and the second connecting end portion 52 of the conductor piece 50 after the cutoff portion 53 was cut off in each interruption test was set to 450 [V]. For the test sample Nos. 7 to 12, a standard type of steel wool available from Nippon Steel Wool Co., Ltd. (trade name: Bonstar; standard wire diameter: y0.035 mm) was used as the second coolant material 70 after being pressed to a thickness of about 3 mm to have a weight of about 2.5 g.

FIG. 5 shows graphs of results of the electric circuit interruption test. The left side shows the test results for the test sample Nos. 1 to 6 (without the second coolant material), and the right side shows the test results for the test sample Nos. 7 to 12 (with the second coolant material).

As is clear from FIG. 5, the test sample Nos. 7 to 12, with the second coolant material 70 being disposed, had a higher insulation resistance value between the first connecting end portion 51 and the cutoff portion 53 than the test sample Nos. 1 to 6, for which the test was conducted without the second coolant material 70 being disposed between the rod portion 42 of the projectile 40 and the cutoff portion 53 in the accommodating space 13 of the breaker device 1. Here, the average value of the insulation resistance values of the test sample Nos. 1 to 6 was 3.7 [Me]. On the other hand, the average value of the insulation resistance values of the test sample Nos. 7 to 12 was 14.7 [Me]. As described above, it has been confirmed that disposing the second coolant material 70 between the rod portion 42 of the projectile 40 and the cutoff portion 53 in the accommodating space 13 of the breaker device 1 increases the insulation resistance when the cutoff portion 53 is cut off from the conductor piece 50, and improves the arc-extinguishing performance.

While the embodiment of the electric circuit breaker device according to the present disclosure has been described above, each of the aspects disclosed in the present specification can be combined with any other feature disclosed in the present specification.

REFERENCE SIGNS LIST

• • 1 Breaker device
  • 10 Housing
  • 13 Accommodating space
  • 20 Igniter
  • 40 Projectile
  • 50 Conductor piece
  • 53 Cutoff portion
  • 60 First coolant material
  • 70 Second coolant material

Claims

1. An electric circuit breaker device comprising: an igniter provided to a housing;a projectile disposed in an accommodating space, the accommodating space being formed in the housing and extending in one direction, the projectile being to be projected along the accommodating space by energy received from the igniter;a conductor piece that is provided to the housing, forms a portion of an electric circuit, includes in a portion thereof a cutoff portion to be cut off by the projectile that moves by the energy received from the igniter, and is disposed with the cutoff portion crossing the accommodating space;an arc-extinguishing region positioned within the accommodating space, on a side opposite to the projectile prior to actuation of the igniter with the cutoff portion interposed between the arc-extinguishing region and the projectile, and configured to receive the cutoff portion cut off by the projectile;a first coolant material disposed in the arc-extinguishing region; anda second coolant material disposed between the projectile and the cutoff portion in the accommodating space prior to actuation of the igniter.

2. The electric circuit breaker device according to claim 1, wherein the second coolant material is solid.

3. The electric circuit breaker device according to claim 2, wherein the second coolant material is formed from a shape retaining body.

4. The electric circuit breaker device according to claim 2, wherein the second coolant material is formed from a metal fiber.

5. The electric circuit breaker device according to claim 4, wherein the metal fiber forming the second coolant material includes at least any one of steel wool or copper wool.