1. Field of the Invention
The present invention relates to a breaker employing a current-limiting device having PTC (Positive Temperature Coefficient) characteristics, and more particularly to a breaker for limiting and breaking a fault current using successive trips by electrically connecting a current-limiting device having PTC characteristics to a plurality of switches.
2. Description of the Related Art
Breakers are widely used for protecting lines and power equipments installed on the lines against a fault current such as a short circuit current in a power system such as a transmission system and a distribution system.
A conventional breaker includes a switch having a fixed contact point and a movable contact point and serially connected to a line for selective opening and closing, an extinction grid for extinguishing an arc generated in the switch while a fault current of the line is broken, and a movable contact point pivoting means for sensing a fault current and tripping the switch by making an angular motion of the movable contact point.
Seeing the operation of the conventional breaker, the fixed contact point and the movable contact point keep a contacted state between them at an ordinary time by using a certain force applied by the movable contact point pivoting means. However, if a fault current flows along the line, an electron repelling force generated between the fixed contact point and the movable contact point makes the movable contact point be rapidly released from the fixed contact point. Arc is generated between the released fixed and movable contact points, and the generated arc is operated toward the surrounding extinction grid, and then cooled and divided. The arc operated toward the extinction grid results in a voltage drop of the line, which limits a fault current flowing on the line, and the limited fault current is completely broken at an artificial current zero point by means of cooling and division of the arc.
Recently, various attempts have been made for realizing an efficient current-limiting and tripping operation of a breaker by connecting a mechanical switch with a current-limiting device having PTC characteristics that makes abrupt change of resistance according to temperature.
The current-limiting device is heated to increase its temperature abruptly by Joule heat when a fault current flows on a line, and its resistance value is abruptly increased when the temperature exceeds a threshold temperature. Accordingly, the fault current of the line is limited by the current-limiting device, and in this state the switch is mechanically operated to break the line.
If the line is broken, the temperature of the current-limiting device is dropped below the threshold temperature, and accordingly the resistance value of the current-limiting device is restored to its initial value. In addition, if a main cause of the fault current is removed and then the breaker is closed again, a common load current flows on the line.
The following prior art shows a breaker prepared by coupling a current-limiting device with a switch as mentioned above.
First, U.S. Pat. NO. 2,639,357 discloses a technique of realizing a breaker by connecting a current-limiting device and switches in parallel. However, U.S. Pat. No. 2,639,357 has a drawback that a fault current is not suitably switched to the current-limiting device.
U.S. Pat. No. 4,878,038 discloses a technique of realizing a breaker by connecting a current-limiting device with switches in series. However, U.S. Pat. No. 4,878,038 has a problem that the current-limiting device connected with a line in series is continuously heated due to Joule heat at ordinary times, so a power loss is caused even when an ordinary load current flows.
U.S. Pat. No. 5,629,658 proposes a breaker operated using the successive trip mechanism by connecting a current-limiting device with a plurality of switches in parallel and in series in order to solve the problem of U.S. Pat. No. 4,878,038.
Japanese Patent Publication No. H10-326554 proposes a more specific structure of a breaker adopting the successive trip mechanism.
The movable arm 26 is divided into a first movable arm 28 having elasticity and to which the first movable contact point 22 is attached, and a second movable arm 26 to which the second movable contact point 24 is attached. At ordinary times, the first contact points 16 and 22 and the second contact points 18 and 24 are electrically connected with each other, and a resistance between the first contact points 16 and 22 is smaller than a resistance between the second contact points 18 and 24, so most current flows through the first contact points 16 and 22 and the first movable arm 28.
If a fault such as a short circuit occurs in a line to flow a fault current through the line, an electron repelling force acts between the first fixed contact point 16 and the first movable contact point 22 so that the first movable arm 28 moves upward, which makes the first movable contact point 22 be released from the first fixed contact point 16. Accordingly, the fault current flows through the second fixed contact point 18 and the second movable contact point 24, and the fault current is limited by means of the current limiting action of the current-limiting device fixed to the second fixed contact point 24. At the same time, if the opening/closing tool detects the fault current and pivots the entire movable arm 26 upward, the fault current flowing between the second fixed contact point 18 and the second movable contact point 24 is completely broken.
However, the breaker of H10-326554 shows the following problems.
First, during the fault current breaking procedure of the breaker, an arc generated when the first contact points 16 and 22 are released may be operated toward the second fixed contact point 18, and also when the second contact points 18 and 24 are released, a serious arc is generated even between the second fixed contact point 16 and the second movable contact point 24. Arc causes a high temperature capable of melting metal or nonmetal material, so the second fixed contact point 24 composed of a PTC current-limiting device is apt to be melt, damaged or divided due to such an arc.
Second, when the breaker is closed, the second contact points 18 and 24 are firstly closed, and then the first contact points 16 and 22 are closed. Even in this breaker closing procedure, an arc is generated between the second contact points 18 and 24. Thus, the arc generated during the breaker closing procedure is apt to melt, damage or divide the second fixed contact point 24 composed of a PTC current-limiting device.
Third, the second fixed contact point 24 is composed of a PTC current-limiting device that is weaker than general contact point materials, so it is apt to be easily deformed or damaged. In addition, if the contact point itself is composed of a PTC current-limiting device, there is a drawback of shortening an electric life of the breaker as well as a mechanical life.
Fourth, a contact resistance between the first contact points 16 and 22 should be smaller than a contact resistance between the second contact points 18 and 24. However, if a contact resistance between the second contact points 18 and 24 is excessively great in comparison to a contact resistance between the first contact points 16 and 22, a fault current is not adequately switched to the second contact points 18 and 24 though the first contact points 16 and 22 are released before.
The breaker of H10-326554 configures the second fixed contact point 18 with a PTC current-limiting device. However, in this case, though a contact resistance between the second fixed contact point 18 and the second movable contact point 24 is increased to release the first contact points 16 and 22, a fault current may be not adequately switched toward the second contact points 18 and 24.
Fifth, a general contact point material is attached to the fixed arm 20 and the movable arm 26 by means of brazing. However, since the second fixed contact point 18 is composed of a PTC current-limiting device, it is impossible to use brazing for attachment of the contact points.
Sixth, the first movable arm 28 is made of metal with great elasticity. Thus, though the first movable contact point 22 and the first fixed contact point 16 attached to the first movable arm 28 are released due to an electron repelling force when a fault current occurs, the first movable arm 28 may be quickly closed again due to the elasticity of the first movable arm 28, which may resultantly limit the fault current insufficiently.
The present invention is designed to solve the problems of the prior art, and therefore it is an object of the present invention to provide a breaker for providing successive trip mechanism, which is capable of preventing deterioration of a PTC current-limiting device, preventing a previously released switch from being closed again, and easily switching a fault current toward the PTC current-limiting device.
In order to accomplish the above object, the present invention provides a breaker for providing successive trip mechanism based on a PTC current-limiting device, the breaker comprising: a first switch having a first fixed contact point and a first movable contact point; a second switch having a second fixed contact point and a second movable contact point and connected to the first switch in parallel; a PTC current-limiting device connected to the second switch in series and to the first switch in parallel, the PTC current-limiting device allowing a change of current flow direction from the first switch to the second switch when a fault current occurs; a movable arm to which the first and second movable contact points are installed at a predetermined interval therebetween, the movable arm opening/closing the first and second switches by operating the first and second movable contact points; a fixed arm including a first fixed arm conductor for guiding current flow toward the first fixed contact point in a normal load current mode, and a second fixed arm conductor for guiding current flow toward the second fixed contact point via the PTC current-limiting device in a fault current mode; and a successive trip means for elastically biasing the second switch by means of an operation of the movable arm in a closing direction when the first and second switches are closed, the successive trip means successively tripping the first and second switches using a time taken for releasing the elastic bias of the second switch when the movable arm is operated in a tripping direction.
In one aspect of the invention, the first and second fixed contact points are provided on the first and second fixed arm conductors extended to the first and second fixed contact points so that an angle between the first fixed and movable contact points is greater than an angle between the second fixed and movable contact points while the first and second switches are in a tripped state, and wherein the successive trip means includes a geometric structure of the second fixed arm conductor that elastically biases the second switch in proportion to a relative difference of both angles when the first and second switches are closed.
In another aspect of the invention, the first and second fixed contact points are provided on the first and second fixed arm conductors extended to the first and second fixed contact points so that an angle between the first fixed and movable contact points is greater than an angle between the second fixed and movable contact points while the first and second switches are in a tripped state, and wherein the successive trip means is a torsion spring that elastically biases the second switch by elastically rotating a part of the second fixed arm conductor provided with the second fixed contact point on the center of a predetermined rotary axis in proportion to a relative difference of both angles when the first and second switches are closed.
In still another aspect of the invention, the first and second fixed contact points are provided on the first and second fixed arm conductors extended to the first and second fixed contact points so that an angle between the first fixed and movable contact points is greater than an angle between the second fixed and movable contact points while the first and second switches are in a tripped state, wherein the movable arm is provided with a guide housing including a compression spring mounted therein, wherein the second movable contact point is received in the guide housing so that one side thereof faces the compression spring and the other side is exposed outward to face the second fixed contact point, and wherein the successive trip means is the compression spring that elastically biases the second switch by means of a back movement of the second movable contact point in proportion to a relative difference of both angles when the first and second switches are closed.
In further another aspect of the invention, the movable arm has a bent that is elastically deformable, wherein the first and second fixed contact points are provided on the first and second fixed arm conductors extended to the first and second fixed contact points, wherein the second movable contact point is provided to the bent, wherein an angle between the first fixed and movable contact points is greater than an angle between the second fixed and movable contact points when the first and second switches are in a tripped state, and wherein the successive trip means is the bent that elastically biases the second switch by being elastically deformed in proportion to a relative difference of both angles when the first and second switches are closed.
Preferably, the breaker of the present invention further includes a movable arm pivoting means for detecting a fault current over a predetermined level when a fault current occurs, and providing the movable arm with a rotating force for tripping the second switch within a predetermined time, wherein the first switch is operated in a tripping direction by means of an electron repelling force generated between the first fixed contact point and the first movable contact point, and the second switch is operated in a tripping direction by means of an electron repelling force generated between the second fixed contact point and the second movable contact point and the rotating force provided by the movable arm pivoting means. In addition, the second switch is positioned outer than the first switch on the basis of a rotary axis of the movable arm.
Preferably, the first fixed arm conductor provides an electric conduction path so that currents around both first fixed and movable contact points of the first switch flow in opposite directions. In addition, the second fixed arm conductor preferably provides an electric conduction path so that currents around both second fixed and movable contact points of the second switch flow in opposite directions.
In order to accomplish the above object, there is also provided a breaker for providing successive trip mechanism based on a PTC current-limiting device, the breaker comprising: a first switch having a first fixed contact point and a first movable contact point; a second switch having a second fixed contact point and a second movable contact point and connected to the first switch in parallel; a movable arm to which the first and second movable contact points are installed oppositely on the center of a rotary axis at a predetermined interval therebetween, the movable arm opening/closing the first and second switches by angularly moving the first and second movable contact points in opposite directions by means of a rotating mechanism; first and second fixed arms to which the first and second fixed contact points are installed respectively; a PTC current-limiting device connected to the first switch in parallel and to the second switch in series, the PTC current-limiting device allowing a change of current flow direction from the first switch to the second switch when a fault current occurs; and a successive trip means for elastically biasing the second switch by means of an operation of the movable arm in an closing direction when the first and second switches are closed, the successive trip means successively tripping the first and second switches using a time taken for releasing the elastic bias of the second switch when the movable arm is pivoted in a tripping direction.
Preferably, an angle between the first fixed and movable contact points is greater than an angle between the second fixed and movable contact points when the first and second switches are in a tripped state.
Preferably, the successive trip means is a geometric structure of the second fixed arm conductor that is elastically deformed to elastically bias the second switch in proportion to a relative difference of both angles when the first and second switches are closed.
As an alternative, the successive trip means is a torsion spring that elastically biases the second switch by elastically rotating a part of the second fixed arm provided with the second fixed contact point on the center of a predetermined rotary axis in proportion to a relative difference of both angles when the first and second switches are closed.
As another alternative, a guide housing including a compression spring is provided at a position of the movable arm provided with the second movable contact point, the second movable contact point is received in the guide housing so that one side thereof faces the compression spring and the other side is exposed outward to face the second fixed contact point, and the successive trip means is the compression spring that elastically biases the second switch by means of a back movement of the second movable contact point in proportion to a relative difference of both angles when the first and second switches are closed.
Other objects and aspects of the present invention will become apparent from the following description of embodiments with reference to the accompanying drawing in which:
a to 3c are side views respectively showing a breaker-closed state, a first switch tripped state, and a first/second switch tripped state according to a first embodiment of the present invention;
a to 4c are side views respectively showing a breaker-closed state, a first switch tripped state, and a first/second switch tripped state according to a second embodiment of the present invention;
a to 5c are side views respectively showing a breaker-closed state, a first switch tripped state, and a first/second switch tripped state according to a third embodiment of the present invention;
a to 6c are side views respectively showing a breaker-closed state, a first switch tripped state, and a first/second switch tripped state according to a fourth embodiment of the present invention;
a to 7c are side views respectively showing a breaker-closed state, a first switch tripped state, and a first/second switch tripped state according to a fifth embodiment of the present invention;
Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the accompanying drawings. Prior to the description, it should be understood that the terms used in the specification and appended claims should not be construed as limited to general and dictionary meanings, but interpreted based on the meanings and concepts corresponding to technical aspects of the present invention on the basis of the principle that the inventor is allowed to define terms appropriately for the best explanation. Therefore, the description proposed herein is just a preferable example for the purpose of illustrations only, not intended to limit the scope of the invention, so it should be understood that other equivalents and modifications could be made thereto without departing from the spirit and scope of the invention.
a to 3c respectively show a breaker-closed state, a first switch tripped state, and a first/second switch tripped state of a breaker according to a first embodiment of the present invention.
The breaker according to the first embodiment of the present invention includes a fixed arm 40 and a movable arm 50 in brief as shown in
The second fixed arm conductor 54 has a geometric structure capable of giving an elastic bias by means of elastic deformation. As shown in
The movable arm 50 includes a movable arm member 56 having one end electrically connected to a load of the line, and first and second movable contact point 58 and 60 attached to the movable arm member 56 at a predetermined interval between them. Here, the first fixed contact point 46 and the first movable contact point 58 configure a first switch, while the second fixed contact point 52 and the second movable contact point 60 configure a second switch. Preferably, the movable arm member 56 is configured with a metal plate made of copper, brass or the like. In addition, the first and second fixed contact points 46 and 52 and the first and second movable contact points 58 and 60 are made of a metal piece of a plate shape with excellent arc-resistant characteristics such as AgCdO, AgC and AgWC.
The movable arm 50 operates the first and second movable contact points 58 and 60 in a tripping direction A (see
The movable arm pivoting means may employ a movable arm pivoting means used in MCCB (Molded Case Circuit Breaker) well known in the art, as it is. The movable arm pivoting means applies a contact pressure to the first and second switches when the breaker is in a closed state, and also applies a rotating force to the movable arm 50 within a predetermined time to break a fault current when a fault current over a predetermined level is detected.
One end of the PTC current-limiting device 44 is connected to the fixed arm member 42, and the other end is electrically connected to the second fixed arm conductor 54 and the second fixed contact point 52. Thus, the PTC current-limiting device 44 may ensure a significant distance from the first and second switches. Accordingly, when the breaker breaks a fault current or the breaker is closed again, an influence affected on the PTC current-limiting device 44 by an arc generated from the first and second switches may be minimized.
The PTC current-limiting device 44 is configured so that upper and lower electrodes 44b and 44c face each other with a PTC material layer 44a having a plate shape being interposed between them as well known in the art. Preferably, the PTC material layer 44a includes crystalline polymer resin and conductive material particles, and also has a nonlinear resistance characteristic that a specific resistance at 25° C. is 1 Ωcm or below, and the specific resistance is increased to 10 Ωcm or above when a fault current occurs. However, the present invention is not limited thereto. The upper and lower electrodes 44b and 44c are configured with a metal plate made of aluminum, silver, copper or the like.
As shown in
Meanwhile, the second fixed and movable contact points 52 and 60 are pressed to contact with each other due to the following reasons. As shown in
If the second switch is elastically biased as mentioned above, points of tripping times of the first and second switches when a fault current occurs are changed, and as a result the first and second switches are successively tripped. It will be explained in more detail later. Hereinafter, a component that causes successive trips of the first and second switches by elastically biasing the second switch as mentioned above will be named ‘a successive trip means’. In the first embodiment, the successive trip means is the geometric structure of the second fixed arm conductor 54 that is elastically deformable.
If the breaker is in a closed state as shown in
The breaker of the present invention has a current limiting function. This current limiting function needs an assumption of faster release of contact points. That is to say, if a fault current occurs on the line, the breaker should rapidly detect the occurrence of the fault current, and then automatically conduct a contact point releasing operation. For this purpose, the breaker uses an electron repelling force generated between the contact points. The electron repelling force is generated in two kinds of patterns.
In the first pattern, the electron repelling force is generated between the first fixed contact point 46 and the first movable contact point 58 and between the second fixed contact point 52 and the second movable contact point 60. While the breaker is in a closed state, each contact point 46, 52, 58 or 60 is electrically connected due to a suitable contact pressure. Of course, since the second fixed arm conductor 54 is elastically biased, the contact pressure between the second fixed and movable contact points 52 and 60 is greater than the contact pressure between the first fixed and movable contact points 46 and 58.
Seeing each contact point 46, 52, 58 or 60 with the eyes of a human, the contact points are looked to perfectly come in contact with each other as if the contact portion is electrically well connected. However, in fact, both contact points are partially electrically connected as shown in
In the second pattern, the electron repelling force is related to a direction of the magnetic field formed around the first and second switches. That is to say, if directions of the currents around the first fixed contact point 46 and the first movable contact point 58 and around the second fixed contact point 52 and the second movable contact point 60 become relatively opposite, an electron repelling force is generated in each interface between contact points according to the Fleming's left-hand rule. For this purpose, the present invention arranges an electric conduction path so that a direction from bents L of the first and second fixed arm conductors 48 and 54 toward the first and second fixed contact points 46 and 52 is opposite to a direction from the first and second movable contact points 58 and 60 toward the rotary axis of the movable arm 50, as shown in
Now, the successive trip operation of the breaker according to the first embodiment of the present invention is described in detail. First, while the breaker is closed as shown in
However, if a fault occurs in the line in which the breaker is installed and thus a fault current starts flowing therein, a magnitude of the electron repelling force is increased in proportion to square of current. And then, at the instant that the electron repelling force overcomes the force of the wipe spring of the movable arm pivoting means, the movable arm 50 is lifted up. Accordingly, as shown in
At the instant that the first switch is tripped, most of the fault current having flowed along the first path I is directed to the second path II and flows to the PTC current-limiting device 44. Then, the PTC current-limiting device 44 starts being heated to increase its temperature rapidly. If the temperature of the PTC current-limiting device 44 keeps increasing and exceeds a threshold temperature, a resistance value of the PTC current-limiting device 44 is abruptly increased to limit the fault current.
In parallel to the fault current limiting operation of the PTC current-limiting device 44, the movable arm pivoting means detects a fault current flowing in the second path II. After that, if it is determined that the detected current level is over a predetermined fault current level, the movable arm pivoting means rotates the movable arm 50 in a tripping direction A as shown in
Meanwhile, an arc is generated while the first fixed contact point 46 and the first movable contact point 58 are released, but an arc energy is not great since most of the fault current is directed to the second path II, and also the generated arc is cooled and divided due to an extinction grid, not shown. In addition, an arc is also generated while the second fixed contact point 52 and the second movable contact point 60 are released, but the arc generated during the releasing procedure of the second switch does not have a great energy since most of the fault current energy is exhausted due to the heating of the PTC current-limiting device 44, and also the generated arc is cooled and divided by the extinction grid. In addition, the PTC current-limiting device 44 is arranged at a position spaced apart from the first and second switches. Thus, it can be effectively prevented that the PTC current-limiting device 44 sensitive to arc is damaged while the breaker is operating.
a to 4c respectively show a breaker-closed state, a first switch tripped state, and a first/second switch tripped state of a breaker according to a second embodiment of the present invention.
According to the second embodiment of the present invention, as shown in
Like the first embodiment, an angle θ1 between the first fixed and movable contact points 46 and 58 is relatively greater than an angle θ2 between the second fixed and movable contact point 52 and 60 in the breaker of the second embodiment, as shown in
In the breaker of the second embodiment, the first and second switches are successively tripped as follows. If a fault current occurs in a line, an electron repelling force greater than a contact pressure applied by the movable arm 50 in the interface between contact points of the first switch is generated so that the movable arm 50 is lifted up as shown in
a to 5c respectively show a breaker-closed state, a first switch tripped state, and a first/second switch tripped state of a breaker according to a third embodiment of the present invention.
According to the third embodiment of the present invention, a guide housing 70 having a compression spring 66 mounted therein and an opening 68 formed at its lower end is provided below the movable arm 50 as shown in
Like the first embodiment, an angle θ1 between the first fixed and movable contact points 46 and 58 is relatively greater than an angle 02 between the second fixed and movable contact point 52 and 60 in the breaker of the third embodiment, as shown in
In the breaker of the third embodiment, the first and second switches are successively tripped as follows. If a fault current occurs in a line, an electron repelling force greater than a contact pressure applied by the movable arm 50 in the interface between contact points of the first switch is generated so that the movable arm 50 is lifted up as shown in
Meanwhile, though not shown in the figures, it is also possible that the second fixed contact point 52 is received in a guide housing (not shown) attached to the second fixed arm conductor 54 together with a compression spring, and the second movable contact point 60 that is made to have a shape corresponding to an opening so as to be inserted into the opening provided in the lower portion of the guide housing is attached to a lower side of the movable arm 50, as a modification of the third embodiment. In this case, in the breaker closing procedure, the second movable contact point 60 presses the second fixed contact point 52 oppositely to the third embodiment so that the compression spring in the guide housing retreats toward the second fixed arm conductor 54. Of course, the successive trip mechanism of the first and second switches are substantially identical to that of the third embodiment.
a to 6c respectively show a breaker-closed state, a first switch tripped state, and a first/second switch tripped state of a breaker according to a fourth embodiment of the present invention.
According to the fourth embodiment of the present invention, a ⊂-shaped bent 57 having a geometric structure capable of allowing elastic deformation is prepared to one side of the movable arm member 56 as shown in
Like the first embodiment, an angle θ1 between the first fixed and movable contact points 46 and 58 is relatively greater than an angle 02 between the second fixed and movable contact point 52 and 60 even in the breaker of the fourth embodiment, as shown in
In the breaker of the fourth embodiment, the first and second switches are successively tripped as follows. If a fault current occurs in a line, an electron repelling force greater than a contact pressure applied by the movable arm 50 in the interface between contact points of the first switch is generated so that the movable arm 50 is lifted up as shown in
Meanwhile, in the third and fourth embodiments as mentioned above, it should be understood that the second fixed arm conductor 54 may also be deformed to some extent depending on the procedure that the second switch comes to an elastically biased state.
a to 7c respectively show a breaker-closed state, a first switch tripped state, and a first/second switch tripped state of a breaker according to a fifth embodiment of the present invention.
According to the fifth embodiment of the present invention, a first fixed arm 72 and a second fixed arm 74 are arranged oppositely on the basis of a movable arm 76, as shown in
The movable arm 76 is rotated in an closing direction A or in a tripping direction B on the center of a rotary axis 78 by means of a movable arm pivoting means, not shown. The movable arm pivoting means applies a contact pressure by a wipe spring to the first and second switches when the breaker is in a closed state. The first movable contact point 58 and the second movable contact point 52 are opposite on the basis of the rotary axis 78 of the movable arm 76 and are attached to positions facing the first fixed contact point 46 and the second fixed contact point 60 respectively. The PTC current-limiting device 44 is connected to the first switch composed of the first fixed contact point 46 and the first movable contact point 58 in parallel and also connected to the second switch composed of the second fixed contact point 52 and the second movable contact point 60 in series.
In case of the breaker of the fifth embodiment, as shown in
In the breaker of the fifth embodiment, the first and second switches are successively tripped as follows. If a fault current occurs in a line, an electron repelling force greater than a contact pressure applied by the movable arm 76 in the interface between contact points of the first switch is generated so that the movable arm 76 is lifted up as shown in
Meanwhile, though not shown in the figures, the second fixed arm 74 may have a structure that may be elastically deformed by a torsion spring as shown in
The present invention has been described in detail based on the limited embodiments and drawings. However, it should be understood that the detailed description and specific examples, while indicating preferred embodiments of the invention, are given by way of illustration only, since various changes and modifications within the spirit and scope of the invention will become apparent to those skilled in the art from this detailed description.
According to the present invention, since the PTC current-limiting device is arranged to be spaced apart from contact points where arc is generated and also most of arc energy is consumed by means of heating of the PTC current-limiting device, it is possible to prevent the PTC current-limiting device from being deteriorated by arc while the breaker is closed or makes a successive trip operation.
In another aspect of the present invention, the second fixed contact point and the second movable contact point do not have a high contact resistance since the contact points are not composed using a PTC current-limiting device. Thus, when a fault current is broken, the fault current is easily turned toward the second switch.
In still another aspect of the present invention, if the first switch is released, an elastically biased state of the second switch caused by the successive trip means is released and at the same time a predetermined gap is generated between the first fixed contact point and the second movable contact point. Thus, the present invention may maximize reliability of the breaker since there is no possibility that the first switch is closed again, differently from the prior art in which the first switch is easily closed again after being released.
Number | Date | Country | Kind |
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KR102005014290 | Feb 2005 | KR | national |