KR20130047542A - Circuit breaker - Google Patents

Abstract

PURPOSE: A circuit breaker of one-pole two-point breaker is provided to generate the spring source on a direct movable contact point without raising costs or causing breaking errors, and to maintain voltage balance. CONSTITUTION: A circuit breaker is comprised of the followings: a movable contact(9) of a rotary motion type which includes a movable contact point in both ends; a power fixed contact and a load fixed contact in which a fixed contact point which cooperates with the movable contact point of the movable contact is prepared, and generate the electron repulsive power to an opened position of the movable contact by flowing the current to the movable contact point when a short-circuit current is generated; a rotor(13) which transfers the rotatory power to the movable contact; and a contact pressure spring(17) which is fixed to the rotor and adds a contact pressure of the movable contact which pushes down the movable contact point to the fixed contact point in an inserting position of the circuit breaker. The contact pressure spring connects one end of the two coils in a connection unit and comprises an extension spring of a one-set which formed hook on the other end of each spring, respectively. By arranging more than one pair of the connection unit of the one-set extension spring symmetrically to a rotary axis of the movable contact, the hook is directly hung to a rib which is prepared in the rotor. Therefore, the contact pressure is applied, and the movable contact is inserted and fitted to the rotor when the rotor rotates by an opening/closing device unit.

Description

Circuit breaker {CIRCUIT BREAKER}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to circuit breakers such as circuit breakers and earth leakage breakers, and more particularly, to a support structure of a movable contactor.

The circuit breaker has a function of opening / closing an electric path by operating an operation handle provided in the circuit breaker, that is, not only a switch function, but also preventing damage to an electric wire or a load device caused by an overcurrent flow. In order to block the converter to play a big role. The breaking of the converter is defined as, for example, "rated short breaking capacity" in JIS (Japanese Industrial Standard) C8201-2-1. It is well known that each manufacturer is trying to improve product variation so that a circuit breaker having an appropriate value can be selected according to the distance from a transformer or a wire.

By the way, when the interruption occurs, an arc is generated between the movable contact and the fixed contact, so-called pair of contacts, but in order to extinguish the arc quickly, the arc voltage for maintaining the arc itself is increased. Therefore, if two pairs of contact points are provided (for example, one pole two-point interruption), for example, the arc voltage is doubled by that amount, and it goes without saying that it is particularly suitable for high breaking capacity products. . As a specific example of this one-pole two-point interruption, a power supply side having two movable contacts at both ends and having a fixed contact paired with each movable contact with respect to the center of rotation of the movable contactor that rotates, and a load It is known to arrange | position the side fixed contactor in the point symmetry position (for example, refer patent document 1 and 2).

This " point symmetry position ", i.e., always locating the movable contactor in the center is indispensable for realizing 1-pole 2-point interruption. This is because, if the center shift of the movable contact occurs, the balance of the contact pressure on the power supply side and the load side may be broken, which may cause a temperature rise or a failure in breaking. On the other hand, although both patent documents 1 and 2 refer mainly to the electromagnetic repulsive force of a movable contact, for example, in patent document 1, the core rod (reference numeral 39) is notch (reference numeral 40). ), And in Patent Literature 2, the roller (reference numeral 151) moves from the engagement in the holding groove (reference numeral 116) at the time of electromagnetic repulsion to the cam surface (reference numeral 113) at OFF. It is considered that the center shift of the movable contactor does not occur, especially when OFF. As a result, even if the operation handle is shifted to the ON state in this state, the above-mentioned pressure balance collapse is unlikely to occur.

[Patent Document 1] Japanese Unexamined Patent Publication No. 6-52777 (Right column 14 to row 34 on the right side of page 4) [Patent Document 2] Japanese Patent Application Laid-Open No. 2005-310780 (Page 8, Lines 16 to 29)

On the other hand, in Patent Literature 1, since the movable contactor (contact bridge: reference numeral 13) interferes with the rod (reference numeral 42) provided in the rotation driving rod (reference numeral 20) in the opening direction at the time of electromagnetic repulsion, There was a difficulty in increasing the amount of openings, i.e., the arc voltage. This point is improved in Patent Literature 2, but at the time of ON, since the load of the spring (reference numeral 141) is applied to the movable contact point through the roller, the spring force is not effectively used, and the force is small. There was a challenge. In addition, since the cam surface is in contact with the cam surface, when the accuracy of the cam surface is deteriorated, there is also a problem that the force generated in the movable contactor and the amount of OT (over travel) are easily changed. In addition, in both documents, an increase in cost associated with the addition of parts such as a mandrel, a rod, a slide pin (reference numeral 131), and a roller is unavoidable.

SUMMARY OF THE INVENTION The present invention has been made in order to solve the above problems, and it is possible to obtain a circuit breaker of a 1-pole 2-point breaker that maintains the pressure balance while generating a spring force directly at a movable contact without causing an increase in cost or a breakdown failure. It is for the purpose.

The circuit breaker according to the present invention is provided with a rotatable movable contactor having movable contacts at both ends, and a fixed contact which cooperates with the movable contact of the movable contactor. A power supply side fixed contactor and a load side fixed contactor for generating an electromagnetic repulsion force in the contactor to the contactor; a rotor for transmitting rotational force to the movable contactor; and fixed to the rotor, and the movable contact at the closing position of the circuit breaker. A contact spring for imparting a contact pressure of the movable contact pushed to the fixed contact, the contact spring connecting one end portion of two coils constituting the spring at a connection portion, It consists of a set of tension springs each having hooks at the ends, and the contact pressure of the movable contact is this one set of phosphorus The connecting portion of the spring is brought into contact with a surface on the side opposite to the movable contact side of the movable contact, and the respective coil portions of the tension spring are disposed on the axial sides of the rotation shaft of the movable contact over the opposite side. In addition, the hook is directly applied to the rib provided in the rotor, and the pair of tension springs are arranged at least one pair symmetrically with respect to the pivot axis of the movable contact. When the rotor is rotated by the bent portion, the movable contactor is fitted to the rotor.

As described above, the present invention can provide a circuit breaker having a high breaking capacity by a single pole two-point breaking having excellent cost performance and high reliability.

1 is an external perspective view of the cover of the one-pole two-point breaker circuit breaker according to the first embodiment of the present invention.
FIG. 2 is a side sectional view of the ON state in FIG. 1. FIG.
3 is a side cross-sectional view of the OFF state in FIG.
4 is a side view illustrating the opening and closing mechanism part and the two-point blocking unit case in FIG. 2.
5 is a side view illustrating the opening and closing mechanism part and the two-point blocking unit case in FIG. 3.
Fig. 6 is an enlarged view of the portion A in Figs. 2 and 3, wherein (a) is ON and (b) is OFF.
7 is a view showing a rotational trajectory of the rotor when there is no fitting between the movable contactor and the rotor as a comparative example.
Fig. 8 is a diagram showing the force of the tension spring in the ON state, where (a) is fitted (invention) and (b) is not fitted (comparative example).
FIG. 9 is a diagram corresponding to FIG. 6 showing Embodiment 2 of the present invention. FIG.
FIG. 10 is a diagram corresponding to FIG. 6 showing Embodiment 3 of the present invention. FIG.
FIG. 11 is a top view of FIG. 10 (b).

Embodiment 1

1 to 6 show a one-pole two-point breaker circuit breaker according to the first embodiment of the present invention. In detail, FIG. 1 is an external perspective view with the cover removed, FIG. 2 is ON, and FIG. 3 is OFF. Each is a side cross-sectional view of the state. 4 and 5 are side views showing the two-point blocking unit case of the opening and closing mechanism and the central pole in FIG. 1, and similarly to FIGS. 2 and 3, FIG. 4 is in an ON state and FIG. 5 is in an OFF state. 6 is an enlarged view of the portion A in FIGS. 2 and 3, and similarly to FIGS. 2 and 3, (a) is in an ON state and (b) is in an OFF state.

Fig. 7 is a view illustrating the rotational trajectory of the rotor in the absence of the “fitting contactor and rotor fitting” which is the main part of the present invention as a comparative example, and Fig. 8 shows the force of the tension spring with or without the “fitting”. The figure also demonstrated as a comparative example shown.

In Fig. 1, the insulating case of the 1-pole 2-point breaker circuit breaker 101 for the 3-pole is composed of a cover 1 (see Fig. 2) and a base 2, of which the operation handle 3 is attached to the base 2; The opening / closing mechanism part 51 provided with this, the two-point breaking unit case 52 and the overcurrent tripping apparatus 53 of the number of poles (in this case, three) are arrange | positioned. Moreover, since the operation handle 3 protrudes from the handle window hole 1a (refer FIG. 2) of the cover 1, the point which can be operated in an ON or OFF direction, and the two-point interruption unit case 52 and an overcurrent From the positional relationship of the tripping device 53, the points which are a tetravalent power supply side terminal and a 5-valent load side terminal are each as noted.

As shown in Fig. 2, the two-point breaking unit case 52 extends from the power supply side terminal 4, has a power supply side fixed contactor 6 having a fixed contact 7 at one end, and an overcurrent tripping device ( A movable contact which is connected to the load-side terminal 5 via 53) and which contacts the load-side fixed contactor 12 having a fixed contact 11 at one end and the fixed contacts 7 and 11 at both ends. (8, 10), for example, a movable contact 9 held by the rotor 13, which is a resin molded article, a fixed contact 7, a movable contact 8, and a movable contact 10 and a fixed contact. It is comprised by the extinguishing apparatus 14 and 15 which cut out the arc which arises by opening in (11). In addition, the rotor 13 which rotates inside the two-point blocking unit case 52 by the rotation shaft 13a has a fixed contact 7 and a movable contact 8, and a movable contact 10 and a fixed contact 11. In order that the contact springs 16 and 17 which generate | occur | produce the contact pressure between them are arrange | positioned, respectively, and the movable contactor 9 of each pole is rotated according to the operation | movement of the opening / closing mechanism part 51, the connection shaft 18 It is connected by. That is, the side sectional drawing by FIG. 2 has shown the center pole which showed engagement with the opening-closing mechanism part 51. As shown in FIG.

Next, the structure of the opening / closing mechanism part 51 is demonstrated. As shown in FIG. 1, the opening / closing mechanism part 51 is a substantially U-shaped handle arm pivotally rotatably supported by the frame 19 formed by the pair of frame boards 19A and 19B which oppose each other. (20), so-called unitized by the operation handle (3) fixed to the handle arm (20), the inside thereof returns to Figure 2 again, the latch (21) of the overcurrent tripping device (53) ), A lever 22 axially supported on the frame 19 by the pivot shaft 22a, an upper link 23 axially supported by the lever 22, the upper link 23 and a spring pin ( The main spring 26 with the lower link 24, the driven side 26a, which is coupled through the 25, and the driven side 26a mounted on the spring pin 25, and the driving side 26b mounted on the handle arm 20, respectively. )

Hereinafter, the coupling | bonding and operation | movement of the switching | closing mechanism part 51 and the two-point blocking unit case 52 in the circuit breaker 101 are demonstrated based on FIGS. The three two-point blocking unit cases 52 are connected by two pin shafts 27 and fixed to a predetermined position of the base 2 (see FIG. 1). In this connection, the frame plate 19A is used. Between the two-point blocking unit case 52 of this right pole (on the front side of Fig. 1) and the two-point blocking unit case 52 of the central pole, the frame plate 19B is placed on the left pole (on the ground of Fig. 1, By interposing the pin shaft 27 horizontally between the two-point blocking unit case 52 of the inner side and the two-point blocking unit case 52 of the central pole, the opening / closing mechanism part 51 is also fixed at the same time. . In this connection, the connecting shaft 18 provided extending from the rotor 13 of the two-point blocking unit case 52 of the central pole is fitted into the rotor 13 of the left pole and the right pole.

Here, a roller 28 is provided on the outer periphery of the connecting shaft 18 extending from the two-point blocking unit case 52 of the central pole so as to be rotatable. 30) is provided in the two-point blocking unit case 52 of the central pole. The link rotor 30 is provided with a long hole 30a, and the roller 28 is engaged with the inner wall of this long hole 30a, and the roller 28 is extended in the longitudinal direction of the long hole 30a along this inner wall. ) Becomes movable. The link rotor 30 is rotatably coupled to the lower link 24 by a pin 31. Therefore, the movement of the lower link 24 is transmitted to the rotor 13 of each pole through the link rotor 30, the roller 28, and the connecting shaft 18, thereby, as described above, the opening and closing mechanism 51 According to the operation, the movable contact 9 of each pole is rotated. In addition, although the lower link 24 of the front, the link rotor 30, etc. are shown in FIG. 4, it is similarly provided also in the inside, ie, between the two-point blocking unit case 52 of the left pole, Therefore, In the present invention, the upper link 23 has a substantially 'U' shape having a connecting portion 23a.

In the OFF state, when the operation handle 3 is rotated clockwise on the ground, the drive side 26b moves about the rotation shaft 20a (see FIG. 1) of the handle arm 20. By this movement, the load direction of the main spring 26 changes, and the lower link 24 moves by also moving the spring pin 25, and the link rotor 30 is pushed down. By this pressing down, the roller 28 rolls and moves in the long hole 30a, and the rotor 13 is rotated clockwise by the connecting shaft 18 in the roller 28, and the fixed contact 7 and The movable contact 8, the movable contact 10, and the fixed contact 11 come into contact with each other, and the state changes to the so-called ON state.

In the ON state, when the operation handle 3 is rotated in the counterclockwise direction on the ground, the lower link 24 is moved by moving the spring pin 25 to the left side as opposed to the above, and the link rotor ( 30) is pulled upwards. By this pulling up, the roller 28 similarly rolls and moves in the long hole 30a, and the rotor 13 rotates counterclockwise by the connecting shaft 18 in the roller 28, and the fixed contact ( 7) between the movable contact 8, the movable contact 10, and the fixed contact 11 opens, and transfers to what is called OFF state.

In the ON state, when the overcurrent tripping device 53 is operated by detecting an overcurrent or the like, the latch 21 rotates due to the rotation of the trip bar 32 (see FIG. 1). Engagement of the 21 with the lever 22 is released. Here, as is well known, since the lever 22 is always pressed on the ground and clockwise by the main spring 26, the lever 22 starts to rotate clockwise around the rotation shaft 22a. By this rotation, the drive side 26b moves relative to the spring pin 25, and finally an upward force acts on the spring pin 25 and the lower link 24 moves. The movement of the lower link 24 is the same as the above transition from ON to OFF, which is a trip state not shown.

Next, the fitting of the movable contactor 9 and the rotor 13 in these ON states and OFF states, which are main parts of the present invention, will be described with reference to FIG. 6. First, in the ON state of (a), a gap B is generated between the movable contactor 9 and the rotor 13, but this is caused by the contact springs 16, 17 causing the movable contactor 9 to be grounded. This is because further rotation in the clockwise direction is prevented by the fixed contacts 7 and 11 while being pressed clockwise. Therefore, this is the generation of the contact pressure by the contact springs 16 and 17 described above. In addition, the contact spring 16 is connected to one end portions of two coils 16a and 16b (see FIG. 11) forming a spring by a 'U'-shaped connecting portion 16c, and a hook ( 16d and 16e consist of a set of tension springs provided on the outer side of the coils 16a and 16b, respectively, and the arrangement is such that the coils 16a and 16b are on both sides of the axial direction of the rotational shaft of the movable contactor 9, This is done by engaging the connecting portion 16c with the surface 9a on the side opposite to the movable contact 8 of the movable contactor 9 and engaging the hooks 16d and 16e directly with the rib 13b provided in the rotor 13. All. Moreover, since the contact spring 17 is also the same, it consists of a set of contact springs 16 and 17, respectively.

In this invention, the recessed part 9c was provided in the convex part 13c on the rotor 13 side, and the movable contact 9 side in the site | part of this gap B which arises, respectively. As a result, in the OFF state of (b), the convex portion 13c and the concave portion 9c are fitted so that the movable contactor 9 does not generate left and right shifts in the rotor 13. The position can be made regular. As a result, as shown in (a), it turns to the balanced state of right and left, and it goes without saying that temperature rise by contact pressure stabilization can be suppressed, and also the interruption | blocking performance is stabilized.

This can understand the effect more compared with FIG. 7 without fitting. Originally, since the movable contactor 9 is floating support, the left and right balance is shifted as shown in (4) in consideration of component error, mounting accuracy, and the like (in this example, on the ground, on the right side, namely, If it is easily shifted to the power supply side, and shifts to the ON state as it is, as shown in (1), the movable contactor 9 is also located in the state shifted to the power supply side. For this reason, the contact spring 16 causes the state which slightly extended with respect to the contact spring 17, ie, the gap B does not correspond, and the contact difference of a power supply side and a load side generate | occur | produces, and the contact resistance increases. It could not be said that it does not cause an increase in temperature.

In the process of OFF operation, as shown in (2), since the gap B mentioned above does not match, the load side contacts first, and then, as shown in (3), the power supply side contacts. By this time, the movable contact 10 and the fixed contact 11 open first, and eventually the left and right balance shifts to (4) without improving, and after that, (3) → (2) → (1) and (1) → (2) → (3) → (4) are repeated.

The mechanism by which this phenomenon occurs is described in more detail in FIG. In Fig. 8 (Fig. 8 corresponds to (2) in Fig. 7) in which the OFF operation starts, that is, the rotor 13 starts to rotate in the counterclockwise direction in accordance with the operation of the opening and closing mechanism 51, (a) and (b) In all the fitting parts, the slide direction component Fs resulting from the shape of this unevenness | corrugation generate | occur | produces in (a) which provided unevenness | corrugation with the force F 'according to the distance from the spring force F by the contact springs 16 and 17. . By this occurrence, as described above, the unevenness is surely fitted, and constantly the center position of the movable contact 9 in the rotor 13 is corrected, so that the left and right balance is achieved. On the other hand, in (b) without irregularities, since this Fs only occurs little by little in the direction substantially perpendicular to F ', correction as in (a) cannot be expected. For this reason, as mentioned above, the opening-and-closing operation cannot be repeated, without the improvement of the left-right balance shift | offset | difference.

Further, even in the rotation of only the movable contactor 9 by the electromagnetic repulsive force shown in Patent Literature 1 or 2, in the present invention, only the rotor 13, the concave portion 9c and the convex portion 13c rotated later are fitted. Therefore, in the opening and closing durability, there is a low possibility that the contact pressure balance is broken due to wear, for example. Further, as is clear from the description above, the spring force of the contact springs 16, 17 is effectively utilized as the contact pressure, and the hook portions 16d, 16e, 17d, 17e are directly connected to the ribs 13b. In view of the increase in the opening distance at the time of electromagnetic repulsion of the movable contactor 9 (not shown) by hanging on, it is possible to increase the reliability while suppressing the cost of the circuit breaker having a high breaking capacity. It becomes possible.

Embodiment 2 Fig.

FIG. 9 is a diagram corresponding to FIG. 6 in Embodiment 2 of the present invention. FIG. In Embodiment 1, although the recessed part 9c was provided in the movable contactor 9, and the convex part 13c was provided in the rotor 13, on the contrary, namely, as shown in this FIG. 9, the movable contactor 9 side was provided. It goes without saying that the same effect can be obtained even when the convex portion 9d and the rotor 13 side are the concave portion 13d.

Embodiment 3:

10 is a view corresponding to FIG. 6 in Embodiment 3 of the present invention, and FIG. 11 is a top view of FIG. 10B. Although not described in the first embodiment, as shown in FIG. 6, in the vicinity of the movable contacts 8 and 10 of the movable contact 9, arc scattering to the rotor 13 side at the time of overcurrent interruption is prevented or the arc is prevented. In particular, the arc insulation member 33 is fixed, which discharges the gas leading to the power supply side. In the circuit breaker, on the other hand, AF (Ampere Frame) is used as an expression representing the outline, and the most rated current is added to this AF, and a plurality of rated current products are generally provided in the AF (example For example, for 250AF, 125A, 150A, 175A, 200A, 225A, 250A are provided). At this time, it is assumed that the plate thickness of the movable contactor 9 also varies in order to obtain heat generation control or current-limiting effect according to this rated current.

Therefore, in the third embodiment, as shown in FIG. 10 or 11 in accordance with the change in the plate thickness of the movable contact 9, the rotor 13 is placed on the half movable contact side of the arc insulation member 34. It was extended so that it could enter into the inside. Therefore, the width dimension obtained by adding the arc insulation member 34 and the movable contactor 9 is made to be slightly narrower than the dimension of the groove 13e of the rotor 13 in each rated current, so that the components of the rotor 13 In addition to the standardization, it is possible to suppress the deviation in the vertical direction on the page of Fig. 11, and to prevent the scattering of the arc in the rotor 13, so that the breaking performance can be further stabilized. The material of the arc insulation member 33 (34) is, for example, polyethylene terephthalate, nylon 66, nylon, as shown in Patent No. 3359422 as the material of the extinguishing insulating material composition and the extruding insulating material molded body. 46 is suitable.

6 fixed contacts on power side, 7 fixed contacts,
8 movable contacts, 9 movable contacts,
9a face, 9c recess,
9d convex, 10 movable contacts,
11 fixed contacts, 12 load-side fixed contacts,
13 rotors, 13b ribs,
13c convex, 13d concave,
13e groove, 16 contact springs,
16a, 16b coil, 16c connection,
16d / 16e hooks, 17 contact springs,
17a, 17b coil, 17c connection,
17d and 17e hooks, 33 arc insulation members,
34 arc insulation member, 51 switchgear mechanism,
101 Circuit Breakers.

Claims (3)

A rotatable movable contactor having movable contacts at both ends and a fixed contact cooperating with the movable contact of the movable contactor are provided, and when a short-circuit current occurs, a current flows through the movable contact to provide an electromagnetic repulsion force to the movable contactor in an open position. A power supply side fixed contactor and a load side fixed contactor for generating a power source, a rotor for transmitting rotational force to the movable contactor, and a movable contactor fixed to the rotor and pushing the movable contact to the fixed contact point at the closing position of the circuit breaker. It is provided with a contact spring to give a contact pressure of
The contact springs are configured as one set of tension springs in which one end of two coils constituting the spring is connected to each other at a connecting portion and a hook is formed at the other end of each coil. The connecting portion of the tension spring is brought into contact with a surface on the side opposite to the movable contact side of the movable contact, and the respective coil portions of the tension spring are disposed on both sides of the rotational axis of the movable contact on the opposite side. In addition, in the circuit breaker configured to apply the contact pressure by hooking the hook directly to the rib provided in the rotor,
At least one pair of the tension springs is arranged symmetrically with respect to the pivot axis of the movable contactor,
And the movable contactor is fitted to the rotor when the rotor is rotated by the opening and closing mechanism portion of the circuit breaker. The method according to claim 1,
The fitting is performed by the convex portion provided in the rotor and the concave portion provided in the movable contactor. The method according to claim 2,
The movable contactor is provided with an arc insulation member, and the width in the axial direction of the rotating shaft of the movable contactor including the arc insulation member is slightly narrower than the width of the portion to which the movable contactor of the rotor fits. Circuit breaker.

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