JPH0810575B2 - Circuit breaker - Google Patents

Description

Description: BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a circuit breaker, and in particular, a circuit breaker provided with a contact pressure generating means suitable for obtaining excellent breaking characteristics in which the contact state of contacts is excellent. Regarding

[Background of the Invention]

In miniaturizing the circuit breaker, the electromagnetic repulsion force due to the short-circuit current was used to open the contacts and raise the arc voltage prior to the tripping operation of the mechanism, as described in Japanese Utility Model No. 48-35967. In many cases, a current limiting cutoff method that limits the passing current is adopted. However, when the contact opens due to the electromagnetic repulsion force, the torque in the anti-separation direction by the contact spring for applying the contact pressure increases linearly, whereas the electromagnetic repulsion force is inversely proportional to the square of the separation distance. However, since the repulsion separation speed is limited and a sufficient increase in arc voltage cannot be obtained, the passing current cannot be limited and the breaking performance is insufficient. Also, in order to eliminate the effect of contact wear due to the arc during opening and closing and to stabilize the contact resistance, sliding of the contact (hereinafter referred to as wipe) for the purpose of separating the arc generation point during opening and closing on the contact from the contact point during energization. Is conventionally provided, and the larger the wipe, the larger the distance between the two points, and the more stable the contact resistance. Since the increase of the wiper and the increase of the wiper will impose a large load on the switching mechanism, in the case of a downsized circuit breaker, this wiper cannot be removed greatly,
In some cases, the contact resistance of the contacts became unstable.

The problems in the conventional example will be specifically described below with reference to FIGS. 36 to 39. FIG. 36 is a sectional view of a conventional one-sided repulsion mechanism. Reference numeral 1 denotes a movable contact base having a movable contact at one end, which is opened / closed by an opening / closing mechanism. Reference numeral 4 is a fixed contact base having a fixed contact 3. The movable contact base 1 is engaged with the opening / closing mechanism by the pin 6, and is constantly urged toward the fixed contact base by the spring 5 having a small spring inclination. 7 is a lever lower, 9 is a lever, and one end is pivotally supported below the lever by a pin 8 and the other end is rotatably locked to a locking portion 9a formed on the frame 26. The drive spring 10 is hooked, and the other end is engaged with the handle lever 11. Opening and closing depends on the relationship between the lever lower 7, lever upper 9 and drive spring 10 by operating the handle 12. In this ON state, the angle of the lever 9 is 0
Taking the angle of the counterclockwise direction around the engaging portion 9a as θ and the torque applied to the lever top 9 as T, the torque curve of FIG. 37 is obtained. In the figure, 13 is the torque curve, 14
Indicates anti-torque caused by the spring 5.

In this figure, the wipe amount W is converted and displayed as the rotation angle θ of the lever upper 9. Here, in order to stabilize the contact resistance, W
Torque 13 and anti-torque 14 when wipe is increased by
It becomes impossible to put it in because there is no room. As a measure against this,
It may be possible to secure the link allowance of the mechanism and increase the drive spring force, but the miniaturized circuit breaker had a limit due to the limited space.

Next, assuming that the ON angle of the movable contact stand 1 is 0 and the clockwise angle is θ ', the torque curve of the spring 5 is as shown in FIG. In the past, a spring with a small spring inclination was used to reduce the increase in torque T'with an increase in θ ', but to reduce the spring inclination requires a large spring space, and a small circuit breaker is required. While conflicting with
Even if a spring with a small spring inclination is used, the spring load increases with an increase in θ ′, but the electromagnetic repulsion force decreases, so the contact base speed is greatly improved, that is, the arc voltage rises sharply. There was a limit to the current limiting characteristics.

FIG. 39 is a cross-sectional view of conventional double repulsion. The contact position in this case is the second spring 37 that applies torque to the second contact base 36.
And a first spring 39 which imparts a torque to the first contact base 38. Here, the torque of the second spring 37 is limited by the mechanism portion, and a large torque difference with the first spring 39 cannot be taken. Therefore, for example, the torque may be stopped at the contact position of the alternate long and short dash line, and the contact resistance is unstable. . Also, the spring 39 on the first contact side
However, the torque increases at the time of repulsion, and the blocking performance cannot be improved.

[Object of the Invention]

An object of the present invention is to provide a circuit breaker having stable contact resistance and good breaking characteristics.

[Outline of Invention]

A first contact block having a first contact fixed thereto, a second contact block having a second contact opposite to the first contact fixed thereto, and a trip shaft common to a plurality of poles. A movable frame that pivotally supports the second contact point, an opening / closing mechanism that opens and closes the second contact point through the movable frame, and a contact pressure between the first and second contacts. In a circuit breaker comprising a pressing means for adding, a first pin provided on the movable contact base, a second pin provided on the movable frame, and a pivot shaft attached to a rotary shaft of the movable frame,
A fulcrum portion common to the trip shaft, a first urging portion locked to the first pin, and a second urging portion locked to the second pin.
The pressing means includes a torsion spring having an urging portion, and the pressing means includes the first and second urging portions, and the first and second urging portions are provided in a low torque region within a rotation torque curve of the opening / closing mechanism.
And three stages of the second contact operation, that is, different pressing forces corresponding to the complete opening time, the contact operation start time or the repulsion operation start time, and the contact operation completion time, respectively. It is a circuit breaker.

Example of Invention

An embodiment of the present invention will be described below with reference to FIGS.

FIG. 1 is a sectional view of a circuit breaker according to a first embodiment of the present invention.

The fixed contact 3 that is the first contact is fixed to the fixed contact base 4 that is the first contact base and is disposed near the bottom surface in the case, and is the second contact provided facing the fixed contact 3. A movable contact base 1, which is a second contact base to which a certain movable contact 2 is fixed, is rotatably supported by a movable frame 17. The movable frame 17 has one end fixed to a common trip shaft 19 penetrating between the poles, and the other end rotatably supported by the movable contact base 1 and above the movable contact base 1. A pin 6 is pivotally supported by a pin 6 on the lower lever 7 of the opening / closing mechanism 20 provided. In the present embodiment, the opening / closing mechanism 20 includes a lower lever 7 pivotally supported by the movable frame 17, and one end rotatably supported by the lower lever 7 by a pin 8 and the other end formed on the frame 26. Lever upper 9 rotatably locked to the stop 9a
And a handle lever 11 fitted with a handle 12, and a drive spring 10 stretched between the pin 8 and the handle lever 11.

In this embodiment, the movable contact base 1 is provided with a pin 15 projecting from a side surface substantially intermediate between the movable contact 2 and the pin 6,
An end of a spring 16, which is a pressing means for urging the movable contact point 1 in the counterclockwise direction, is locked at this position. The details of the movable contact stand 1 are shown in FIG. The springs used as the pressing means in the first to fifth embodiments are all torsion springs having two end portions connected to the central portion, like the spring 16 shown in FIG.

The movable contact base 1 having the movable contact 2 at one end is urged counterclockwise by the spring 16 fitted to the pin 6,
Is rotatably supported by the movable frame 17. Spring 16
One end 16a of the pin 15 is an upper surface 15a of the pin 15 engaged with the movable contact base 1.
It is in contact with the part. The other end 16b of the spring 16 is in contact with a convex portion 17b which is a pressing force variation means formed by the punching 17a of the movable frame 17.

Next, the operation of this embodiment will be described with reference to FIGS. FIG. 3 is the moment when the opening / closing mechanism 20 operates and the movable contact 2 comes into contact with the fixed contact 3. In this state, one end 16b of the spring abuts on the convex portion 17b of the punched-out 17a of the movable frame 17, and there is a gap with the pin 15 projecting on the movable contact stand 1. The other end of the spring 16. 16a abuts on the pin 15 and applies a counterclockwise biasing force to the movable contact base 1. This ON
The urging force of the spring 16 at the moment is halved because only one end 16a is in contact. In this state, the movable contact 2 starts to wipe, and when the gap between the one end 16b of the spring 16 and the pin 15 becomes zero, the entire urging force of the spring 16 is applied to the movable contact base 1. FIG. 4 shows the final ON state (wiping completed state) after further wiping from this state. In this state, both ends 16a, 16b of the spring 16 are in contact with the pin 15 and apply a biasing force to the movable contact base 1, thereby applying a predetermined contact pressure between the movable contact 2 and the fixed contact 3. In the state shown in FIG. 3, the projecting portion 17b of the embossing 17a of the movable frame 17 and the end 16b of the spring 16 are provided.
There is a gap between them. Although the convex portion 17b is formed by stamping in this embodiment, it may be formed by cutting and raising or the like. FIG. 5 shows the torque curve for the upper lever 9 of the configuration of this embodiment. Reference numeral 13 is a torque curve of the opening / closing mechanism 20, and 18 is an anti-torque curve of this embodiment. In the same figure, the T ₀₃ part is in the state of FIG. 3, the T ₀₂ part is in a state in which both ends 16a, 16b of the spring 16 are in contact with the pin 15 protruding from the movable contact base 1, and T ₀₁ is in FIG. Is ON state, and the graph is discontinuous at T ₀₂ and T _{03 with} an inflection point. Anti-torque curve 18
By making the inclination with an inflection point, the anti-torque can be reduced at a place where the torque of the mechanism portion is small, and a sufficient margin can be secured. Therefore, a large wipe can be taken only between T ₀₃ and T ₀₂ , and the arc point and the contact point are separated from each other, so that the contact resistance is stable.

A second embodiment of the present invention will be described with reference to FIGS.

In this embodiment, an inflection point is provided in the spring inclination when shutting off. FIG. 6 is a cross-sectional view of the repulsion portion of the one-side repulsion mechanism. Reference numeral 22 denotes a movable contact frame pin 6 which is a second contact block having a movable contact 2 at one end, and a movable frame 23 and an opening / closing mechanism section 20.
Is supported by. The spring 25, which is a pressing means, is fitted to the pin 24 pivotally supported by the movable frame 23 below the pin 6,
One end of the spring 25 is in contact with the pin 15 protruding from the movable contact base 22, and the other end is in contact with the movable frame 23. A fixed contact base 21, which is a first contact base having the fixed contact 3 and is arranged opposite to the movable contact base 22, is arranged. The direction of the current is opposite to that of the movable contact base 22 and the fixed contact base 21 as indicated by arrow AA 'in the figure, and when a large current flows during a short circuit, electromagnetic repulsion acts between the contact bases. . When the electromagnetic repulsive force exceeds the torque P ₀ l ₁ given to the movable contact base 22 of the spring 25, the movable contact base
22 starts to rotate clockwise with pin 6 as a fulcrum. The middle of this opening is shown in FIG. In this embodiment, since the rotation fulcrum of the movable contact base 22 and the fulcrum of the spring 25 are different, the contact position between the pin 15 of the movable contact base 22 and the spring 25 changes, and in the state of FIG. The pin 15 abuts on the bent portion 25a which is a pressing force changing means. This position corresponds to the movable contact base 22 of the spring 25.
It becomes the inflection point of the torque given to. FIG. 8 shows a state in which the movable contact base 22 is further rotated and repelled. The contact position between the spring 25 and the pin 15 moves to 25b. The torque applied to the movable contact stand in this state is P ₁ l ₁ . The torque applied by the spring 25 to the movable contact 22 shown in FIGS. 7 to 8 is the bending portion of the spring 25.
Since there is 25a, compared to the case without this part, spring 2
An angle of 5 can be suppressed from increasing by θ ₁ .

That is, even if the electromagnetic repulsion force during the rotation of the movable contact base is reduced, the torque of the spring 25 does not increase, so the rotational speed of the movable contact base 22 does not decrease.
Therefore, the arc voltage can be rapidly raised, the short-circuit current value can be suppressed small, and the breaking performance is improved.

The torque curve of the above operation is shown in FIG. 9, and the angle θ ′ of the movable contact base 22 in FIG. 6 is θ ′ = 0, and the angle θ ′ is clockwise.
Is taking

In the figure, the section W indicates the wiped state, and the movable contact base 22 rotates in the counterclockwise direction by θw. In addition, in the figure
T ₀₄ shows the torque in the ON state shown in FIG. 6, T ₀₅ shows the repulsion start state shown in FIG. 7, and T ₀₆ shows the torque in the full repulsion state shown in FIG. 8, respectively. That is, there is no increase in torque from T ₀₅ to T ₀₆ . In FIG. 9, T ₀₅ to T ₀₆ are parallel, but the inclination angle of this torque can be easily changed by changing the bending angle of one end of the spring 25. Note that, in FIG. 9, the alternate long and short dash line indicates the torque curve when there is no bent portion. Further, FIG. 10 shows a modified example of this embodiment, in which the movable contact base 22 can be locked in a repulsive state by adding a bent portion 25c to the spring 25.
In addition, the movable contact base 22 in this locked state is set to the normal position (OFF,
To return to the TRI position), you can easily use the tripping action of the mechanism.

A third embodiment of the present invention will be described with reference to FIGS. FIG. 11 is a sectional view of the ON state. The movable contact base 29, which is the contact base of FIG. 2, is pivotally supported by the pin 6 on the movable frame 30 and the opening / closing mechanism 20. The spring 33, which is a pressing unit, is fitted on the pin 31 pivotally supported by the movable frame 30. Spring 33
Has one end abutting against the pin 6 and the other end abutting against the pin 32 pivotally supported by the movable contact base 29, so that the movable contact base 29 always applies a counterclockwise torque. From this state, a short-circuit current flows and the movable contact base 29 rotates, as shown in FIG. Since the position of the pin 6 that serves as the fulcrum of rotation of the movable contact base 29 and the position of the pin 31 that serves as the fulcrum of the spring 33 are different, the contact position of the pin 32 and the spring 33 changes as the movable contact base 29 rotates. Since the bent portion 33a is formed in the spring 33 as a means for varying the pressing force, a torque curve similar to that shown in FIG. 9 can be obtained also in this embodiment.

A fourth embodiment of the present invention will be described with reference to FIGS.

This embodiment is a combination of the first and second embodiments of the present invention.

In this embodiment, as shown in FIG. 13, a movable frame 34 is provided with a convex portion 35 to which a spring 25, which is a pressing means having a bent portion 25a which is a changing means, abuts, and a movable contact, as in the second embodiment. The table 15 has pins 15 protruding from it. This operation is the operation of the first embodiment up to the ON state and has the inflection point T ₀₇ due to the engagement of the spring 25 and the convex portion 35, and the operation is the operation of the second embodiment at the time of repulsion. 15 has an inflection point T ₀₉ by passing through the bent portion 25a. When the angle of the movable contact base 22 in the ON state is θ ′ = 0, the torque applied to the movable contact base of the spring 25 is shown in FIG. 14, and has two inflection points T ₀₇ and T ₀₉ .
At this point a discontinuous torque curve is obtained. Note that T ₀₈ is the torque at θ ′ = 0, and the movable contact base 22 rotates counterclockwise at θw during the wiping shown in the section W.

A fifth embodiment of the present invention will be described with reference to FIGS.

In this embodiment, the present invention is applied to the side of the first contact point base having a structure in which the first contact point base and the second contact point base are rotatably provided, and both are repelled.

That is, in this embodiment, as shown in FIGS. 15 to 18, a first contact base 41 having a first contact 40 at one end is pivotally supported by a pin 44 on a support frame 45. The second spring 42, which is a pressing means, is fitted to the pin 43 pivotally supported by the support frame 45. One end 42a of the second spring 42 abuts on a pin 46 projecting from the first contact base 41, and the other end 42b abuts on a projection 45a portion which is a changing means formed on the support frame 45. Second spring 4
The other end 42b of 2 is provided so as to have a slight gap with the pin 46 in the OFF state, and the second contact side from this state
The ON operation is performed, the first contact side wipes, the state shown in FIG. 16 is passed, and the state is changed to the complete ON state shown in FIG. Figure 16 shows the first
The contact base 41 is rotated and the pin 46 is in contact with both ends 42a and 42b of the spring 42. At this point, the protrusion 45a of the support frame 45
And there is no gap at the spring end 42b. Before this state, the torque applied to the first contact block is only one end 42a of the spring 42, and the torque is halved. Wiping further and in Fig. 17, the spring
A gap is created between one end 42b of 42 and the protrusion 45a of the support frame 45, and the total torque of the spring 42 acts on the first contact point base 41. 17th
In the state shown in the figure, short-circuit current flows, electromagnetic repulsion works, and spring 42
Becomes larger than the torque applied to the first contact point base 41, the first contact point base 41 rotates counterclockwise and is formed at the end of the first contact point base 41 opposite to the first contact point 40. Stopper 41a
Comes into contact with the pin 43 and the state shown in FIG. 18 is established. Springs 42a, 42b
The contact position between the pin 46 and the pin 46 moves because the position of the pin 44, which is the fulcrum of rotation of the first contact base 41, and the position of the pin 43, which is the fulcrum of the spring 42, are different. Further, since the spring 42 has the bent portion 42c which is a changing means, when the pin 46 moves from this position to the end, the torque applied by the spring 42 to the first contact point base 41 does not increase and becomes substantially constant. The above operation is performed by the first contact block 41 of FIG.
The angle θ'and the torque T are represented as shown in Fig. 19 with the angle θ'of Fig. 19 being θ '= 0, and T ₁₀ is shown in Fig. 15 and T ₁₁ is shown in Fig. 16.
FIG. 17, T ₁₂ shows the state of FIG. 17, and T ₁₃ shows the state of FIG.
Also in this embodiment, the same effect as the case where it is provided on the second contact side is obtained.

In all of the above-mentioned embodiments, a torsion spring is used as the pressing means, but an embodiment using another spring will be described below.

A sixth embodiment of the present invention will be described with reference to FIGS.

FIG. 20 shows the state at the start of the wipe of this embodiment. 51
Is a movable contact base which is a second contact base having the second contact 2 at one end, and is pivotally supported by the pin 53 on the movable frame 54 and the lever lower 7. The spring 56 and the spring 57, which apply the contact pressure to the second contact point 51, are supported at one end by spring receiving portions 54a formed on the movable frame 54, and the spring 56 abuts on the movable contact point 51 and serves as a pressing means. But give
The spring 57 is provided as a changing means, and the spring length is set so as to have the movable contact base 51 and the gap G ₁ . In this state, the end 51b of the movable contact base 51 opposite to the movable contact 2
Is brought into contact with and locked by the locking portion 54b of the movable frame 54. When you start wiping from this state, the gap G ₁ becomes smaller,
On the contrary, the cap G ₂ is generated at the engaging portion 54b. When the wipe is further performed, the gap G ₁ becomes 0, and both springs 56 and 57 act on the movable contact base 51. Figure 21 shows the complete ON state after the wipe is completed. In this state, a gap G ₂ exists between the end portion 51b of the movable contact base 51 and the locking portion 54b of the movable frame 54, and the springs 56 and 57 apply contact pressure to the movable contact base 51. According to this embodiment, in addition to the spring that is the pressing means during the wipe, another spring is made to act, so that the torque characteristic during the wipe can have an inflection point.

A seventh embodiment of the present invention will be described with reference to FIGS.

FIG. 22 shows the ON state of this embodiment. 61 is a movable contact block which is a second contact block having a second contact 62 at one end, and is a pin.
The movable frame 65 and the lower lever 7 are pivotally supported by 63.
67 is a movable plate that is rotatably supported by a movable frame 65 by a pin 66 and is given a rotational force in the counterclockwise direction by a spring 69 that is a pressing means. The movable plate 67 abuts on a pin 68 projecting from the other end of the movable contact base 61 to apply a contact pressure to the movable contact base 61. When the electromagnetic repulsion force generated when a large current such as a short-circuit current flows in this state increases due to the contact pressure, the movable contact base 61 starts rotating clockwise. Here, the pin 63 which is the fulcrum of the second contact block 61
And the position of the pin 66, which is a fulcrum of the movable plate 67, are different from each other, so that the contact surfaces of the movable plate 67 and the pin 68 move. When this abutting position crosses over the bent portion 67a which is the changing means,
The load applied to the movable contact base 61 by the spring 69 is substantially constant.
FIG. 23 shows a state where the movable contact base 61 is completely repelled.

Also in this embodiment, by providing the spring fulcrum at a position different from the fulcrum of rotation of the contact base, it is possible to suppress an increase in spring load and provide an inflection point in the torque characteristic during repulsion.

An eighth embodiment of the present invention will be described with reference to FIGS. 24 to 26.

In this embodiment, the movable plate of the seventh embodiment is a movable plate 70 having a plurality of bent portions. FIG. 24 shows the wiping state of the movable contact when it is turned on in this embodiment. In this state, the pin 68 projecting from the movable contact base 71 is the first plate of the movable plate 70.
It comes into contact with the bent portion 70a. FIG. 25 is a complete ON state diagram. In this state, since the movable contact base 71 and the movable plate 70 have different fulcrums, the contact position between the movable plate 70 and the pin 68 is the second position.
It moves to the first straight line portion 70c over the bent portion 70b. Therefore, the contact pressure at the moment of turning on can be reduced by the amount of the step moving from 70a to 70c. When a short circuit current flows in the ON state shown in Fig. 25, when the electromagnetic repulsion force generated between the contact bases becomes larger than the contact pressure by the contact springs 69, the movable contact base 71 begins to repel and open, and the pin 68 moves to the first position. The second straight line portion 70e is abutted beyond the third bent portion 70d, and the state of complete repulsion is shown in FIG.

By providing the movable plate 70 with a plurality of bending portions as in the present embodiment, it is possible to provide an inflection point for the characteristics during wiping and repulsion.

The ninth embodiment of the present invention will be described with reference to FIGS.

In this embodiment, one end of the spring 76, which is a pressing means, is connected to the other spring 77.
An example in the case of being supported by FIG. 27 is a side view at the moment when it is turned on. The movable contact base 72, which is the second contact base, is pivotally supported on the movable frame 74 by pins 75. One end 76a of the contact spring 76 abuts on a pin 73 protruding from the movable contact base 72, and the other end 76b abuts on a convex portion 74a formed on the movable frame 74 as a changing means. The connected one end 76c of the spring 76 is
It is supported by another spring 77. FIG. 28 shows a state in which it is completely turned on in this state. Contact spring 76 76a,
The action of the portion 76b on the movable contact base 72 is the same as that of the first embodiment, but since the other end connected is supported by the spring 77, the contact due to the load is equal to the increase in the deflection angle of the spring 76, Displace the spring 77 downwards so that the end 76 of the contact spring 76
Try to keep the angle between a, 76b and 76c constant. From FIG. 28, FIG. 29 shows a state where the movable contact base 72 is completely opened by the electromagnetic repulsive force. Contact spring 76 in full rebound
The deflection angle (load applied to the contact base) increases, but the spring 77 is displaced further downward,
This increase is suppressed. FIG. 28 is a diagram in which the angle θ ′ of the movable contact base 72 is θ ′ = 0 and θ ′ is taken in the clockwise direction, and the torque characteristic is written in FIG. T ₁₄ is Fig. 27, T ₁₅ is Fig. 28
The figure and T ₁₆ show the states of FIG. 29, respectively. By supporting one end of the spring by another spring as described above,
A flat torque characteristic can be obtained, and an inflection point can be obtained during wiping of the movable contact base 72. The movable contact base 72 rotates in the counterclockwise direction by θw during the wiping shown in the section W in FIG.

Next, a tenth embodiment of the present invention will be described with reference to FIGS.

In this embodiment, the movable contact point 81, which is the second contact point, has one fulcrum and uses two springs. FIG. 31 is a side view at the moment when it is turned on. The movable contact base 81 is pivotally supported by a movable frame 84 by a pin 82, and a contact spring 83, which is a pressing means fitted to the pin 82, has one end on the movable frame 84 and the other end on a convex portion 85 of the movable frame 84. They are in contact with each other. In this state, the pin that is the changing means engaged with the movable contact base 81
There is a gap between 86 and one end 83a of the contact spring 83. A spring 88 is stretched between the pin 86 and the pin 87 pivotally supported by the movable frame 84, and in this state, a force is applied to rotate the movable contact base 81 in the contact direction. FIG. 32 shows a state in which it is completely turned on from this state. From this Figure 31
One end 83a of the contact spring 83 comes into contact with the pin 86 during the wiping in FIG. 32, and a force for rotating the second contact base 81 in the contact direction acts. A gap exists between the convex portion 85 and the one end 83a. In FIG. 32, the contact pressure of the movable contact base 81 is the contact spring.
Given by both 83 and 88. In this ON state, a large current flows and the current repulsive force works, and the state in which the repulsive opening is complete
Figure 33. In the force direction of each spring acting on the movable contact base 81 in this state, the spring 83 always exerts a force in the contact direction, while the banana 88 has a line of action of the spring 88 beyond a fulcrum 82 which is a torque point. As a result, the force acts to keep the movable contact base 81 in the direction opposite to the contact direction. When the angle θ ′ of the movable contact base 81 in FIG. 32 is θ ′ = 0 and θ ′ is taken in the clockwise direction, the torque curve is as shown in FIGS. 34 and 35. In FIG. 34, 89 is the torque characteristic of the spring 88, and 90 is the torque characteristic of the spring 83.

That is, the torque to the movable contact base 81 is
The resultant force is 83,88, resulting in the characteristics shown in FIG. T ₁₇ is first
Fig. 31, T _{18 When} the end 83a of the spring 83 and the pin 86 come into contact with each other, T
₁₉ shows the state of FIG. 32 and T ₂₀ shows the state of FIG. 33. By changing the load of the two springs, the inclination of the torque characteristic of FIG. 35 can be freely changed.

〔The invention's effect〕

According to the present invention, it is possible to obtain a circuit breaker having stable contact resistance and good breaking characteristics.

[Brief description of drawings]

FIG. 1 is a side sectional view showing the structure of a circuit breaker according to a first embodiment of the present invention, and FIG. 2 is a perspective view showing a movable contact base and a movable frame according to the first embodiment, FIGS. Is a side view of the main part showing the moment when the movable contact contacts the fixed contact and the final ON state in the first embodiment, and FIG. 5 is a torque characteristic diagram relating to the lever top 9 of the first embodiment,
FIGS. 6, 7, and 8 are side views showing the ON state, the repulsion start state due to overcurrent, and the total repulsion state due to overcurrent, respectively, of the main part of the circuit breaker according to the second embodiment of the present invention, FIG. 9 is a torque characteristic diagram of the movable contact base in the second embodiment, FIG. 10 is a side view showing a main part of a modified example of the second embodiment, and FIGS. 11 and 12 are third embodiments of the present invention. FIG. 13 is a side view of the main part of the circuit breaker in the ON state and the repulsive state, FIG. 13 is a side view of the main part of the circuit breaker in the ON state of the fourth embodiment of the present invention, and FIG. FIG. 15, FIG. 16, FIG. 16, which are torque characteristic diagrams of the movable contact base in the embodiment.
FIG. 17 and FIG. 18 respectively show an OFF state of the main part of the circuit breaker in the fifth embodiment of the present invention, a state of being wiped after shifting from OFF to ON, a complete ON state, and a repulsion state due to overcurrent. FIG. 19 is a side view, FIG. 19 is a torque characteristic diagram of the first contact block in the fifth embodiment, and FIGS. 20 and 21 are the main parts of the circuit breaker in the sixth embodiment of the present invention at the start of wiping. Side view showing the state of the and full ON state, Fig. 22, Fig. 23
The figure is a side view showing the ON state and the repulsion state due to overcurrent of the main part of the circuit breaker in the seventh embodiment of the present invention, and FIGS. 24, 25, and 26 are the eighth embodiments of the present invention. FIG. 27 is a side view showing the ON state and the repulsive state of each of the main parts of the circuit breaker in FIG. 27, FIG. 27, FIG. 28, and FIG. 29 showing the main parts of the circuit breaker in the ninth embodiment of the present invention. FIG. 30 is a torque characteristic diagram of the movable contact base in the ninth embodiment, FIG. 31, FIG. 32, and FIG. 33 are views of the present invention. Each of the main parts of the circuit breaker in the tenth embodiment is in a wiped state, an ON state, a side view showing a repulsive state, FIG. 34 is a torque characteristic diagram of a spring 83 and a spring 88 in the tenth embodiment, and FIG. Is a torque characteristic diagram of the movable contact base in the 10th embodiment,
Fig. 37 is a side sectional view showing the structure of a conventional circuit breaker equipped with a one-sided repulsion mechanism. Fig. 37 is a torque characteristic diagram of the lever 9 on the lever of the conventional circuit breaker. Fig. 38 is a conventional circuit breaker. FIG. 39 is a side view showing a main part of a conventional circuit breaker having a double repulsion mechanism, which is a torque characteristic diagram of the movable contact base. 1,22,29,71,72,81: Second contact block, 2: Second contact, 3,40:
1st contact point, 4,21,41: 1st contact point stand, 16,25,33,42,56,6
9,76,83: Pressing means, 17,23,30,34,54,74,84: Movable frame, 17b, 25a, 33a, 35,42c, 45a, 57,67a, 70a, 70b, 70d, 74a,
86: moving means, 17b, 35, 74a: convex portion, 20: opening / closing mechanism, 25a, 33
a, 42c, 67a, 70a, 70b, 70d: bent part.

 ─────────────────────────────────────────────────── ─── Continuation of the front page (56) References JP-A-58-164126 (JP, A) Actual development 59-150146 (JP, U) Actual public 59-4535 (JP, Y2)

Claims (1)

[Claims] 1. A first contact base to which a first contact is fixed,
A second contact block having a second contact fixed to the first contact block and a movable member fixed to a trip shaft common to a plurality of poles so as to pivotally support the second contact block. A circuit breaker comprising a frame, an opening / closing mechanism for opening and closing the second contact block via the movable frame, and a pressing means for applying contact pressure between the first and second contacts. A first pin provided on the movable contact base, a second pin provided on the movable frame, a fulcrum portion pivotally attached to a rotating shaft of the movable frame and common to the trip shaft, and the first pin First locked on
The pressing means is composed of a torsion spring having a biasing portion and a second biasing portion that is locked to the second pin, and the pressing means includes a first biasing portion and a second biasing portion for opening and closing the opening / closing mechanism. In the region within the turning torque curve, the three stages of the first and second contact operations, that is, the point of complete opening,
The circuit breaker is configured to apply different pressing forces corresponding to a contact operation start time, a repulsion operation start time, and a contact operation completion time, respectively.