FR2825188A1 - MOLDED BOX CIRCUIT BREAKER - Google Patents

Abstract

In a molded case circuit breaker comprising a current interruption section made up of a combination of an isolated case 6, the contact shoes 7A and 7B of fixed contact on the power supply side and on the load side are contained in the insulated housing 6 and arranged diagonally opposite one another, a shoe 8 of movable contact in rotation forming a bridge, a support 9 of shoe contact, and arc extinguishing devices 10, shoes 7A , 7B of fixed contact consisting of conductors of linear contact shoes to allow the height H of the current interruption section to be reduced, and being arranged vertically parallel and in opposition to each other so that the fixed contact shoes on the side of and the movable contact shoe form a conductive path in the form of a Z, thereby allowing the movable shoe 8 to be driven and opened by electromagnetic force in the event of an overcurrent.

Description

power supply.

  The present invention relates to a molded case circuit breaker, and in particular to the assembled structure of an interrupting section.

  s of current provided with a contact shoe movable in rotation and forming bridging.

  First, the configuration of the molded case circuit breaker is shown diagrammatically in Figure 7. In this figure, the reference numeral 1 designates the case forming the main body of the circuit breaker, the reference numeral 2 is a joystick opening and closing, the numerical reference o 3 is an opening and closing mechanism of the toggle type, the numerical reference 4 designates a device for

  tripping in the event of overcurrent (based on a two-way process

  blade or the like), the reference numeral 5 is a current interruption section containing fixed contact shoes, a movable contact shoe, and s arc extinguishing devices of a main circuit, and which is connected the opening and closing mechanism. The opening and closing operations of a circuit breaker of this kind are well known, and an on / off or on / off operation of the opening and closing lever 2 makes the movable contact shoe of section 5 d 'interruption of current o opens or closes via the mechanism 3 of opening or closing. In addition, if an overcurrent flows and activates the trigger device 4 in the event of an overcurrent while electricity is flowing in the main circuit, the opening or closing mechanism 3 performs a triggering operation. to open the moving contact shoe of section 5 of current interruption, thereby interrupting

  the current flowing in the main circuit.

  Here, the interrupt method used for the current interrupt section 5 includes a single break method and a double break method. An example of a double break process using a movable contact shoe provided with a rotationally movable contact shoe and forming bridging is described in Japanese patent applications N06-028964 and 652777. The configuration of this circuit breaker is shown in FIG. 8. In this figure, the reference numeral 6 designates an isolated box of section 5 of current interruption, the reference numerals 7A and 7B represent fixed contact shoes on the side of the load and on the side of the power supply contained in the insulated housing 6 and arranged in diagonal opposition to each other, the numerical reference 7A is a fixed contact disposed at the tip part of each fixed contact shoe, the reference numeral 8 is a movable contact shoe which forms a bridge between the contacts of the fixed contact shoes 7, reference numeral 9 is a contact shoe support in the form of a rotary drum which holds the shoe 8 of mobile contact, and the reference numeral 10 is s an arc extinguishing device (grid) positioned on each side of the shoe 8 of mobile contact and contained in the cas ^ 'tier 6 isolated. The movable contact shoe 8 is biased and held in position by means of a pressurized spring (tension spring or torsionally wound spring) 11 loosely fitted in a hole 9A for diametric crossing formed in the core. of the contact shoe support 9 and assembled inside the contact shoe support 9. One end of the shoe 7A of fixed contact on the power supply side is taken out of the insulated housing 6 to form a terminal part on the power supply side. A terminal portion of the shoe 7B of fixed contact on the load side is connected to the main circuit conductor of the device 4 for tripping in the event of an overload, represented in FIG. 4, on the side of the upper surface of the housing.

6 isolated.

  Furthermore, in the illustrated structure, the tip part of each of the fixed shoes 7A and 7B is bent to form a fixed contact 7A so that by using the electromagnetic elastic force exerted between the tip parts of the shoes 7A and 7B fixed contact and the movable contact shoe 8 when an overcurrent such as a short-circuit current flows in the main circuit, the mobile contact shoe 8 is opened substantially instantaneously before the device 4 for triggering in the event of overload (see Figure 7) does not work. In addition, the folded part of each fixed contact shoe has a magnetic yoke 12 to reinforce a magnetic field acting on an arc produced between the contacts of the fixed and mobile contact shoes during the power interruption, thereby increasing the force. of electromagnetic arc towards the devices

arc extinction.

  The power interruption section 5 is as compact as possible in order to facilitate a desirable reduction in the

  o dimension of the molded case circuit breaker.

  However, in the conventional structure of the current interruption section shown in FIG. 8, the tip part of each of the shoes 7A and 7B of fixed contact on the power supply side and on the load side is folded in the form of the letter U in order to produce the electromagnetic elastic force necessary to entrain and open the shoe 8 of movable contact when an overcurrent of the current passes in the circuit. As a result, the height H of the insulated housing 6, which contains the clogs 7A and 7b of fixed contact must be increased, so as to ensure that

  the size of the current interruption section 5 is increased.

  In addition, as shown in FIG. 9, Japanese patent application N 1-166429 describes a molded case circuit breaker in which the fixed contact shoes 7A and 7B, contained in the box Tier6 isolated from the section 5 of current interruption and arranged diagonally opposite to each other, consist of conductors with linear contact shoes, with the contact shoe 8 movable in rotation forming a bridge positioned between the

  fixed contacts 7A disposed at the tips of the fixed contact shoes 7A and 7B.

  According to this assembled structure, the contact shoe conductors of the fixed contact shoes 7A and 7B, contained in the insulated box, are linear, so as to allow the height H of the section 5 of interruption of o current d 'be reduced compared to the configuration of Figure 8. On the other hand, the direction of the current flowing in the shoes 7A and 7B of fixed contact is the same as that of the current flowing in the shoe 8 of movable contact, so that the great electromagnetic elastic force essential to entrain and open the movable contact shoe is not produced between each

  fixed contact shoes 7A and 7B and the movable contact shoe 8.

  An object of the present invention is thus to provide an improved molded case circuit breaker, in which the fixed contact shoes on the load side and on the power supply side are made up of shoe contact conductors. fixed linear contacts, in order to eliminate the need to increase the height of the current interrupting section, and in which the arrangement of the fixed and movable contact shoes is modulated so as to produce the large electromagnetic elastic force o essential for entrain and open the movable contact shoe when a

  overcurrent flows in the circuit.

  To achieve this object, the present invention provides a molded case circuit breaker comprising a current interruption section consisting of an assembly of an insulated case containing arc extinguishing devices, a shoe fixed contact on the power supply side and a fixed contact shoe on the load side contained in the housing and arranged diagonally opposite one another, a movable contact shoe forming a bridge extending between the contacts of the fixed contact shoes, and a rotary contact shoe support which holds and connects the movable contact shoe and a pressure spring to the opening or closing mechanism of the circuit breaker, the movable contact shoe being open by an electromagnetic elastic force exerted when the overcurrent flows, the contact shoe conductors of the fixed contact shoes on the load side and on the power supply side being substantially linear ires and being arranged parallel to each other and opposite one another with the interposition of the movable contact shoe, and the fixed contact shoes on the power supply side and on the load side and the movable contact shoe, which carry stator contacts disposed at tip portions of the conductors of the fixed contact shoes, are assembled o together to form a conductive path in the shape of a Z. According to this configuration, the fixed contact shoes consist of linear contact shoe conductors, thus allowing the height of the current interruption section to be reduced compared to the conventional structure using the fixed U-shaped contact shoes. In addition, while electricity flows through the circuit breaker, the direction of current passing through the fixed contact shoes on the power supply side and the load side, is relatively opposite

  s to that of the current passing through the movable contact shoe in the form of a bridge.

  Therefore, if an overcurrent flows through the circuit, a large electromagnetic elastic force, acting as a torque, is produced between the tip portion of the fixed contact shoe on the power supply side and the movable contact shoe and between the tip part o of the fixed contact shoe on the load side and the movable contact shoe. This electromagnetic elastic force can be used as

  drive torque to drive and open the movable contact shoe.

  Furthermore, in accordance with the present invention, to further improve the opening operation of the movable contact shoe and the interrupting efficiency, the following specific strategies can be implemented with the above configuration as a basis: (1 ) a magnetic yoke is arranged in an area around the tip portion of each of the fixed contact shoes on the power supply side and on the load side, thereby strengthening the magnetic field acting on the contact shoe mobile to increase the electromagnetic elastic force. In this case, a magnetic field acting on an arc produced between the contacts of the fixed and movable contact shoes during the current interruption is reinforced to increase the driving force of the electromagnetic arc, thereby directing the arc towards the devices

corresponding arc extinction.

  (2) The tip portion of each of the fixed contact shoes on the power supply side and the load side is tilted away from the movable contact shoe, so that an electromagnetic elastic force produced between the tip part and the movable contact shoe acts effectively as the drive torque required to rotate the movable contact shoe

  relative to its center of rotation.

  (3) The tip portion of each of the fixed contact shoes on the power supply side and the load side is set to be thinner than that of the conductor, which is behind its tip portion, thus concentrating the current and strengthening the magnetic field produced in a peripheral zone of the tip part in order to increase the electromagnetic elastic force acting on the movable contact shoe. In this case, the conductor portion of the contact shoe, which is wider than the tip portion, absorbs and radiates heat produced in the contact portion as a result of the power interruption to prevent the temperature of the fixed contact shoe terminal part located at its rear end to rise

  and to be greater than an admissible value.

  (4) A magnetic protective element is arranged in the area opposite the tip portion of each of the fixed contact shoes on the power supply side and on the load side, located opposite the other. fixed contact shoe with interposition of the mobile contact shoe. This configuration prevents the formation, in the path of rotation of the movable contact shoe, of a magnetic field acting in a direction in which the

  o movable contact shoe is prevented from being opened.

  (5) Each of the fixed contact shoes on the load side and the power supply side has a slit-shaped vacuum formed along a longitudinal direction of its contact shoe conductor and in one of its zones located opposite the tip part of the other fixed contact shoe, the slot dividing the conductive path into two lateral parts. Thus, the magnetic field produced in the peripheral region of each conductor is dispersed to suppress the electromagnetic elastic force acting in the direction in which the movable contact shoe is prevented from being

open as in (4) above.

  (6) A hot gas discharge port is open in each of the end surfaces on the power supply side and the load side of the section insulated housing.

7 2825188

  interruption of current so as to extend perpendicularly towards the conductor of the contact shoe and away from the contact shoe conductor of the corresponding fixed contact shoe out of the insulated housing. Consequently, hot gas produced in the insulated casing of the current interrupting section by the arc produced when a large current is interrupted is prevented from blowing directly against the conductor of each shoe. fixed contact which was removed by pulling it from the insulated box and from the periphery of the conductor,

  which results in a spark between pole.

  o (7) The terminal part of the fixed contact shoe placed along the bottom surface of the insulated housing is curved in the shape of the letter U and is pulled out from an end surface of the isolated bo ^ 'tier. Thus, the magnetic field produced in a peripheral zone of the terminal part as a result of the current which passes through the contact shoe conductor is prevented from hindering the extension of an arc produced between the fixed and mobile contacts during the interruption. of current, so

  guarantee superior interrupt performance.

  An embodiment of the present invention is described below with reference to the examples shown in Figures 1 to 6. In Figure o of each example, the same components as those of Figures 8 and 9 are

  designated by the same reference numbers and their description is omitted.

  FIG. 1 is a diagram showing the configuration of a current interruption section corresponding to example 1 of the present invention; Figure 1 (a) is a side view illustrating the configuration of the internal mechanism of the power interruption section, Figure 1 (b) is a plan view of the fixed contact shoes of Figure 1 (a) , and Figure 1 (c)

  is a sectional view along line X-X of Figure 1 (a).

  FIG. 2 is a diagram representing the configuration of the current interruption section corresponding to example 2 of the present invention; FIG. 2 (a) is a side view illustrating the configuration of the internal mechanisms of the current interruption section, FIG. 2 (b) is a plan view of the fixed contact shoes of FIG. 2 (a), and figure 2 (c)

  is a sectional view along line X-X of Figure 2 (a).

8 2825188

  Figure 3 is a diagram showing the configuration corresponding to Example 3 of the present invention; Figure 3 (a) is a plan view of the fixed contact shoes and Figure 3 (b) is a diagram

  representing the magnetic field distribution.

  Figure 4 is a sectional view showing the configuration of a current interruption section corresponding to Example 4 of the

present invention.

  Figure 5 is a sectional view showing the configuration of a current interruption section corresponding to Example 4 of the

  o present invention, but which differs from that shown in FIG. 4.

  Figure 6 is a sectional view showing the configuration of a current interruption section corresponding to Example 5 of the

present invention.

  Figure 7 is a diagram showing the configuration of a

molded case circuit breaker.

  Figure 8 is a sectional view showing the configuration

  of an example of a conventional current interruption section in FIG. 7.

  Fig. 9 is a sectional view showing the configuration of an example of a conventional power interruption section, which differs from

  o that shown in Figure 8.

Example 1

  Figures 1 (a) to 1 (c) show an example of a method of renlisation of the invention. In this example, the contact shoes 7A and 7B fixed on the power supply side and on the load side, which are contained in the housing 6 isolated from the current interruption section, consist of substantially linear contact shoe conductors and are arranged in parallel and in opposition to each other with interposition of the contact shoe 8 movable in rotation. That is to say that the contact shoe 7A fixed o on the power supply side, which was removed by pulling it from the side of the bottom surface of the box 7 isolated from its left , has a tip part 7c provided with the fixed contact 7a and extending beyond a center O of rotation of the movable contact shoe 8, held in the shoe support 9

9 2825188

  contact in the form of a rotating drum, in the vicinity of the arc extinguishing device 10, position born to the left of the insulated housing 6. On the other hand, the load side shoe 7B of the load side, which has been pulled into the upper surface side of the housing 7 isolated from its right, has a tip portion 7c extending beyond the center O of rotation of the movable contact shoe 8 towards the vicinity of the arc extinguishing device 10 positioned to the right of the insulated housing 6. A Z-shaped conductive path is formed by the fixed contact shoes 7A and 7B and the movable contact shoe 8, arranged diagonally so as to bridge the fixed contacts 7a of the shoes 7A and 7B of

o fixed contacts.

  Here, the tip part 7c of each of the fixed contact shoes 7A and 7B, provided with the fixed contact 7a, is tilted away from the movable contact shoe 8 (tilting angle 0), and the conductor in the part 7c tip has a width d less than the width D of the conductor in the area of the fixed contact shoe which is behind the tip part 7c. In this regard, the reference numeral 7d designates an arc duct (arc horn) further extending from the position of the fixed contact 7a towards the corresponding arc extinguishing device 10. Figure 1 (b) is a plan view of the fixed contact shoe 7A on the power supply side, but similar arrangements are made for the fixed contact shoe 7B

load side.

  In addition, a U-shaped magnetic yoke 12 is assembled on the insulated housing 6 so as to surround the rear, the right and the left of the tip part 7a of each of the contact shoes 7A and 7B s fixed, thus reinforcing the magnetic field acting on an arc produced between the contacts of the fixed and movable contact shoes during the current interruption, in order to increase the arc drive force necessary to extend the arc towards the corresponding arc extinguishing device 10. The magnetic yoke 12 consists of a stack of thin steel plates

  so in order to reduce the eddy current losses.

  According to this configuration, the contact shoe conductors of each of the shoes 7A and 7B and of fixed contact, placed inside the insulated housing 6, are linear, thus allowing the height H of section 5 current interruption to be decreased compared to the conventional configuration of Figure 8 in which the tip portion of each of the fixed contact shoes 7A and 7B is bent in the form of the letter U. In addition, a current of main circuit which passes in section 5 of interruption of current passes in the conductive path in the form of Z. made up of shoes 7A and 7B of fixed contact and shoe 8 of movable contact, as represented by arrow i in the figure . On this conductive path, the direction of the current i passing through this part is reversed between the tip part 7c of each of the fixed contact shoes 7A and 7B and each end o of the movable contact shoe 8, so that the current causes the electromagnetic elastic force F is produced between each of the fixed contact shoes 7A and 7B and the movable contact shoe 8 on the basis of a similar principle

  to that of the U-shaped fixed contact shoes 8 shown in FIG. 8.

  In this regard, the movable contact shoe 8 is biased and closed by a pressurized spring assembled on the contact shoe support 9 as in the case of the structure of FIGS. 8 and 9. Consequently, a large electromagnetic elastic force n is not produced with a nominal current and a minor overload current, thus preventing the movable contact shoe 8 from being opened. On the contrary, if an excessive current such as a short-circuit current (which is 10 to 20 times greater than the nominal current) passes, the electromagnetic elastic force F overcomes the elastic force of the pressure spring, thereby causing the movable contact shoe 8 anticlockwise with respect to the center O of rotation to open it. In addition, the magnetic field produced in the area around the movable contact shoe 8 which results from the current passing through the fixed and movable contact shoes is reinforced to increase the driving force of the electromagnetic arc, thereby extending and entraining an arc of the interrupted current, produced between the fixed and movable contact shoes as a result of the opening of the movable contact shoe 8, towards the extinguishing devices 10

  o corresponding arc, o it is extinguished.

  In this case, provided that the tip part 7c of each of the fixed contact shoes 7A and 7B is tilted away from the movable contact shoe 8 as described above, the electromagnetic elastic force can also be effectively exerted on the movable contact shoe 8 as opening drive torque. In addition, the conductor in the tip part 7c of each of the fixed contact shoes 7A and 7B has the small width d and a concentrated current passes through the tip part s, so that the magnetic field produced in the area around the tip part and acting on the movable contact shoe 8 is reinforced, so as to allow a large electromagnetic elastic force to act

on the movable contact shoe 8.

o Example 2

  Figures 2 (a) to 2 (c) show the configuration of a

  applied example of another embodiment of the present invention.

  According to this example, in addition to the configuration described in FIG. 1, a magnetic shielding element 13 is also installed inside each of the fixed contact shoes 7A and 7B on the side of the power supply and on the side of the load, so that the area between the magnetic shielding element 13 and the movable contact shoe 8 is magnetically shielded. Here, the magnetic shielding element 13 for the shoe 7A of fixed contact on the side of the power supply is placed in a zone o situated opposite the tip part 7c of the shoe 7B of fixed contact on the side of the load. , located opposite the shoe 7A of fixed contact on the power supply side with interposition of shoe 8 of movable contact. The element 13 of magnetic shielding for the shoe 7B of fixed contact on the side of the load is put in a zone located in front of the part 7c of point of the shoe 7A of fixed contact on the side of the power supply, located in face of fixed contact shoe 7B on the load side. Figure 2 (b) is a plan view of the fixed contact shoe 7A on the power supply side, but similar arrangements are made for the fixed contact shoe 7B on the side

of the load.

  o With the configuration described above, in the position o the movable contact shoe 8 is open as shown in FIG. 2 (a), even when the contact parts of the movable contact shoe 8, which are located at ends opposite, are closed towards an intermediate part of the conductor of each of the fixed contact shoes 7A and 7B, the shoe 8 of

  mobile contact does not undergo a magnetic effect such that it prevents it from opening.

  That is to say, without the magnetic shielding elements 13, the conductive current causes the electromagnetic elastic force f to occur between the end of the right side of the movable contact shoe 8 and the contact shoe conductor. of the fixed contact shoe 7B on the load side, which is located above the mobile contact shoe 8 and opposite the mobile contact shoe 8, and between the end on the left side of the mobile contact shoe 8 and the contact shoe conductor of the fixed contact shoe 7A on the power supply side, located below and opposite the movable contact shoe 8. Consequently, the movable contact shoe 8 is prevented from opening. In addition, under the magnetic effect, an arc produced between the fixed and movable contact shoes is also prevented from being entrained towards the

arc extinguishing device 10.

  By putting the magnetic shielding elements 13 as in the example illustrated, the magnetic shielding effect reduces the production of the electromagnetic elastic force f, which prevents the movable contact shoe 8 from opening, as well as the electromagnetic force, that prevents

  the extension and drive of a current arc produced between the contacts.

  This prevents the opening speed of the movable contact shoe 8 from being reduced during an opening operation. Consequently, the movable contact shoe 8 is subjected to an electromagnetic elastic force resulting from the overcurrent of the current described in FIG. 1, and opens without stopping, in

  improving circuit breaker interrupt performance.

Example 3

  Figures 3 (a) and 3 (b) show an applied example corresponding to another embodiment of the present invention. In this example, each of the fixed contact shoes 7A and 7B has a gap o 7b in the form of a slit formed along its longitudinal direction and in an intermediate part (the same zone in which the magnetic shielding element 13 is placed in the example of FIG. 2) of the contact shoe conductor, the vacuum dividing the conductive path into two lateral parts. Thus, as shown in FIG. 3 (b), the current i conductor is used to laterally disperse a magnetic field produced in an area around the conductor, thereby reducing the electromagnetic elastic force which acts in the direction in which the shoe 8 of moving contact is prevented from opening. This produces effects similar to those of the realization mode of

  realization 2 to guarantee a very good interrupt performance.

Example 4

  Figures 4 and 5 show an example corresponding to o another embodiment of the present invention. In this example, a hot gas discharge orifice 6a (an opening through which a hot gas produced in the insulating casing due to an arc during the interruption of current is emitted to the outside) opening into each of the surfaces of the load side and of the power supply side (right and left end surfaces in the figure) of the insulated housing 6 is specified as follows: the hot gas discharge port 6a is defined inside a vertical gas deflection wall 6b formed along the corresponding end surface of the box 6 isolated 6 so as to extend perpendicularly in the direction of the contact shoe conductor and in moving away from it and from the fixed contact shoes 7A and 7B on the load side and on the corresponding power supply side which are placed on the upper and bottom surfaces respectively of the insulated housing 6 and who came out of them the corresponding end surface of the housing. The reference numeral 7e designates the terminal part of each of the fixed contact shoes 7A and 7b, and the terminal part 7e of the fixed contact shoe 7A on the power supply side is folded in the form of the letter L and is removed by pulling it from the terminal part of the main circuit breaker box 1, shown in FIG. 7. On the contrary, the terminal part 7 of the shoe of fixed contact shoe 7B on the load side is removed pulling it out linearly and is connected to device 4 of

  tripping in the event of an overcurrent in Figure 7.

  In addition, in the example in FIG. 4, the orifice 6a for discharging hot gas opens onto the open side of the shoe 8 for movable contact, while the example in FIG. 5, the orifice 6a for discharging hot gas on the power supply side opens onto the closed side of the movable contact shoe 8 so as to be at a distance from the shoe terminal part 7e

7A fixed contact.

  With this configuration, hot gas (containing conductive components such as vapors or metal ions from the contact elements which are produced by an arc) produced inside the cas ^ 'tier6 insulated by an arc during the interruption of current is blown from the arc extinguishing device 10 and then changes its direction

  towards a perpendicular direction as represented by the arrow in the figure.

  The gas is then emitted away from the fixed contact shoes 7A and 7B, passing through the orifices 6a for discharging hot gas. This prevents the hot gas from blowing directly against the contact shoe conductors of the fixed contact shoes 7A and 7B which have been pulled out of the insulated housing 6, thereby rendering the terminal portions 7e and their periphery very well isolated

  electrically without being affected by hot gas.

  On the contrary, in the conventional structure in which the orifice for discharging hot gas is simply opening into each end surface of the insulated casing, the hot gas can blow against the terminal parts of the fixed contact shoes and their periphery to cause a spark between the poles

Example 5

  FIG. 6 represents an example corresponding to an embodiment of the present invention. In this example, for one of the fixed contact shoes 7A and 7B, contained in the insulated box 6 of the current interruption section 5, that is to say the contact shoe 7A on the fixed side. of the power supply, placed on one side of the bottom surface of the insulated box 6, the contact shoe conductor pulled out of the insulated box 6 is bent in the form of the letter U to form the 7th terminal part as shown in the figure, so that the 7th-1 part folded into a U-shape of the

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  perpendicularly rising contact shoe conductor extends to

  outside the 7th terminal part.

  On the contrary, in the conventional circuit breaker represented in FIG. 8 or in Example 4, described above (see FIGS. 4 and 5), the terminal 7e of the shoe 7A of fixed contact which has been pulled out of each end surface of the bo ^ 'tier 6 isolated is folded in the form of the letter L so as to extend the

  along the end surface of the housing.

  Here, we consider the electromagnetic force which acts between a magnetic field produced in the area around the shoe contact conductor of the contact shoe 7A of fixed contact by a current passing through the contact shoe conductor and an arc produced between the contact shoes fixed and mobile contact during power interruption. In the conventional structure, the arc which is extended towards the arc extinguishing device 10 is close to the contact shoe conductor, which extends along the end surface of the insulated housing 6 s , and thus the arc is significantly affected by the magnetic field. In this case, the direction of the current passing through the rising part (perpendicular part) of the contact shoe conductor is opposite to that of the arc current, so that due to the Fleming rule with the left hand , the magnetic field prevents the arc from expanding and the

o pushes back towards contact.

  On the contrary, in the structure in which the contact shoe conductor of the fixed contact shoe 7A which has been pulled out of the insulated housing 6 is bent in the form of the letter U to form the terminal part 7e as shown in FIG. 6, the distance B between the perpendicular part of the conductor s of the part 7e-1 bent in a U shape. through which current flows in the direction opposite to that of the arc current, and the arc which is extended between the contacts is larger than in the case of the conventional structure. This reduces the effect on the arc of a magnetic field produced around the contact shoe conductor of part 7e-1 bent into a U shape by the current so which passes through it (the intensity of the magnetic field acting on the arc is inversely proportional to the distance D to the contact shoe driver). Therefore, the electromagnetic force preventing the arc from expanding is decreased to ensure interrupt performance

very good.

  The structures of Examples 1 to 5, described above, are effective on an individual basis, but the performance of the molded case circuit breaker can further be further improved by using these structures together. The improvement which results from the electromagnetic elastic force and the arc driving force of the movable contact shoe has also been sufficiently appreciated and confirmed by analyzes.

  and magnetic field experiments carried out by the inventors.

  As described above, in accordance with the configuration of the present invention, in a current interruption section of a molded case circuit breaker made up of a combination of fixed contact shoes on the supply side in power and on the load side and in a movable contact shoe forming a bridge, the contact shoe conductors of the fixed contact shoes on the power supply side and on the load side are substantially linear and are arranged parallel and opposite one another with the interposition of the movable contact shoe, and the fixed contact shoes on the power supply side and on the load side and the mobile contact shoe, which bridge stator contacts positioned at o tip parts of the conductors of the fixed contact shoes, are constructed to form a Z-shaped conductive path. Therefore, the current interruption section is smaller q that of the structure

  classic in which U-shaped fixed contact shoes are used.

  Furthermore, in a conductive state, the direction of the current passing through the fixed contact shoes on the power supply side and on the load side is relatively opposite to that of the current passing through the movable contact shoe forming a bridge. Therefore, if an overcurrent flows through the circuit, a large electromagnetic elastic force acting as a torque is produced between the tip part of the fixed contact shoe on the power supply side and the shoe contact block and between the fixed contact shoe on the load side and the mobile contact shoe. This electromagnetic elastic force can be used as a drive torque for another by opening the sabo1 of conga mobile a mass large comma in the case of the sours assume udUsan1 of contact shoes fine in Irma of U. In outs, using the stratum mentlonnde above trying as a base and using the congol1ions described in the enemies of the psente invention, a performance dlnterrupton pout Ate even more smash.

Claims (8)

  1. Molded case circuit breaker comprising a current interruption section consisting of an assembly of an insulated case containing arc extinguishing devices, of a fixed contact shoe on the side of the power supply and a fixed contact shoe on the load side contained in the housing and arranged diagonally opposite one another, a movable contact shoe forming a bridge extending between the contacts fixed contact shoes, and a rotary contact shoe support which o maintains and connects the mobile contact shoe and a pressurized spring to a circuit breaker opening or closing mechanism, the mobile contact shoe being opened by a electromagnetic elastic force exerted when an overcurrent flows, the circuit breaker being characterized in that contact shoe conductors of fixed contact shoes on the power supply side and on the load side are substantially li and are arranged parallel to each other and opposite one another with the interposition of the movable contact shoe, and the fixed contact shoes on the power supply side and on the load side and the movable contact shoe, which bridge stator contacts disposed at tip portions of the conductors of the fixed contact shoes, are assembled together to form a Z-shaped conductive path. 2. Circuit breaker according to claim 1, characterized in that a magnetic yoke is arranged in an area around the tip part of each of the fixed contact shoes on the supply side.   s power and load side.   3. Circuit breaker according to claim 1 or 2, characterized in that the tip part of each of the fixed contact shoes on the power supply side and on the load side is tilted in   moving away from the moving contact shoe.   s 4. Circuit breaker according to any one of claims 1 to   3, characterized in that the tip part of each of the fixed contact shoes on the power supply side and on the load side is adjusted to be narrower than that of the conductor, which is behind its part peak.   o 5. Circuit breaker according to any one of claims 1 to   4, characterized in that a magnetic shielding element is arranged in a zone located opposite the tip portion of each of the fixed contact shoes on the power supply side and on the load side, located opposite on the other fixed contact shoe with interposition of the contact shoe s mobile contact.   6. Circuit breaker according to any one of claims 1 to   , characterized in that each of the fixed contact shoes on the power supply side and on the load side has a slot-shaped vacuum formed along its longitudinal direction of its contact shoe conductor and in a of its zones located opposite the tip part of the other fixed contact shoe, the slot dividing the conductive path in two side parts.   7. Circuit breaker according to claim 1, characterized in that a hot gas discharge orifice opens into each of the end surfaces on the side of the power supply and on the load side of the boltier isolated from the interrupting section current so as to extend perpendicularly towards the contact shoe conductor of the corresponding fixed contact shoe and away from it, the contact shoe   fixed fixture being removed from the insulated housing.   o 8. Circuit breaker according to claim 1, characterized in that the terminal part of the fixed contact shoe placed along the bottom surface of the insulated housing is curved in the shape of the letter U and is taken out of a