[0001] The present invention relates to an electric circuit breaker with a housing comprising
a pair of fixed contact members or contact rails and a movable contact member with
a first and a second, substantially parallel contact surface, said movable contact
member being displaceable for establishing a connection between the two fixed contact
members and with spring means for pressing the movable contact member against the
fixed contact members in a closed position and where the movable contact member is
attached to a slider movable on a guide track provided for this purpose and aligned
with the spring means, said slider pressing the movable contact member into the open
position when subjected to a pressure-transferring mechanism activated by the control
handle of the circuit breaker and where the contact surfaces and the displacement
direction of the guide track of the slider form an angle different from 90°.
[0002] Keeping contacts clean is a constant problem in connection with the making and breaking
of electric pathways. Several different types of self-cleaning contacts are known,
where movable or fixed contacts wipe each other clean by means of one or other form
of rolling or displacement (e.g. EP application 0 105 817). Furthermore, the German
Offenlegungsschrift nr. 2 817 815 describes a circuit breaker, where the contact
surfaces and the displacement direction of a rod form an angle of only approx. 10-15°.
The cleaning effect is not satisfactory with circuit breakers of the above type, especially
with high currents, exceeding e.g. approx. 10 A.
[0003] According to the present invention a circuit breaker is proposed, which is characterised
by the movable contact member comprising a first and a second midpart between, said
first and second contact surfaces said first midpart being substantially perpendicular
to the displacement direction of the slider and said second midpart being substantially
parallel to the displacement direction of the slider.
[0004] Thus it is achieved that the movement of the movable contact member from the open
to the closed position consists of two movements: First, the movable contact member
is pressed by a spring in the displacement direction of the slider, said spring or
springs being arranged perpendicular to the contact member, until the movable contact
surfaces touch the fixed contact surfaces. Then the reaction forces of the fixed
contact members oppose part of the spring pressure, resulting in a displacement force
parallel to the contact surfaces. The resulting displacement force is proportional
to the cosine of the angle between the contact surfaces and the direction of the spring
forces and causes a displacement of the movable contact member parallel to the fixed
contact surfaces, such that possible dirt is wiped off. Thus a self-cleaning effect
is achieved.
[0005] In a preferred embodiment the guide track in the housing is arranged in such a way
that the angle between the track and the bottom of the normally horizontally installed
housing is approx. 10°, and such that the end of the slider actuating the movable
contact member is closer to the bottom of the housing than the slider end subjected
to the pressure-transferring mechanism, and the fixed and the movable contact surfaces
form an angle of approx. 60° with said bottom. This is proposed with regard to the
fact that the corresponding known circuit breaker without self-cleaning contacts comprises
a guide track, which is usually horizontal in the installation position, while contact
surfaces and rails are normally vertical to this position. By turning the guide track
as well as the contact surfaces against each other so that the angle between them
is approx. 50°, the compact form of the circuit breaker is retained. The new circuit
breaker with self-cleaning contacts does thus not need more space than the common
circuit breaker without self-cleaning contacts.
[0006] Preferably the circuit breaker housing furthermore comprises a retainer surface
arranged such that a bend connecting the first and the second planar midparts of the
contact member abuts the retainer surface in the closed position of the circuit breaker
and when the breaker is opened, the bend or "knee" is guided back to its start position
by the retainer surface. Thus the retainer surface has two effects: First, the retainer
surface stops the displacement of the movable contact member during the closing operation
and thus defines its final position, second, the retainer surface is a guide surface
for the movable contact member, when the latter is returned to its open position.
[0007] Besides the main advantage of the circuit breaker, i.e. its self-cleaning, a reduced
contact bounce time is achieved, probably due to damping caused by the special form
of the movable contact member with its three curves and especially because of the
position of the bend against the retainer surface. By choosing a suitable angle between
the first and the second midpart of the contact member the bounce time can be considerably
reduced. The exact angle depends, however, on the materials used as well as their
dimensions and has to be experimentally determined in each individual case. An angle
of approx. 80° is found to be especially advantageous with contact members made of
brass.
[0008] The invention will be described in greater details below with reference to the accompanying
drawings, in which
Figure 1 shows a preferred embodiment of a main circuit breaker according to the present
invention in closed position,
Figure 2 shows the same in open position,
Figure 3 a vector diagram,
Figure 4 an embodiment of a contact member, and
Figure 5 an enlarged section of the circuit breaker.
[0009] The circuit breaker is shown in its preferred embodiment and comprises a housing
10, wherein a pair of fixed contacts 21 and 23 is mounted, which can be connected
by a movable contact member 25. The movable contact member 25 is fastened between
a strong spring 19, in the following referred to as toggle spring, and a somewhat
weaker spring 31 inside a slider 27 sliding along a track 29 supported by guide points
and guide grooves in the housing. Figure 1 shows furthermore that the toggle spring
19 is aligned with a track 29 and is at its base end guided and supported by a retainer
wall 20.
[0010] The circuit breaker is in Figure 1 shown in its closed position. When the current
is to be cut off, a lever arm turning around a pivot 13 is actuated. The lever arm
11 is part of a partially circular holder 12 with a toggle arm 15, which can turn
around the pivot 13 together with the lever arm 11. The toggle arm 15 is by means
of a rotating joint 16 attached to one end of another arm 17, which is tapered being
flat but rounded at the other end and is referred to in the following as toggle member
17. The toggle arm 15, the pivot 16 and the toggle member 17 constitute the pressure-transferring
mechanism referred to in the introduction. These are well-known means and can be
realized in several ways. The toggle member 17 protrudes into a V-shaped recess at
one end of the slider 27, which moves in the track 29. The other end of the slider
is provided with a track or groove, receiving the movable contact member 25. When
the lever arm 11 is turned to the open position shown in Figure 2, the toggle arm
15 is also turned and at a certain moment during this turning the toggle arm 15 and
the toggle member 17 are aligned with each other. At this moment the toggle spring
19 is maximally compressed. The presence of the toggle spring ensures in a manner
known per se that the last part of the movement is executed in such a way that the
circuit breaker is either completely closed or completely open. In the open position
shown in Figure 2 the spring is slightly compressed and the contact member 25 lies
in its groove at the end of the slider fastened between the two springs 19 and 31
and at some distance to the two fixed contact rails 21 and 23.
[0011] When the lever arm is moved from the open to the closed position shown in Figure
1, the toggle spring 19 is compressed slightly more and the movable contact member
is pressed further away from the contacts. During the last part of the movement the
toggle spring 19 tries to straighten itself and thus the movable contact member is
pressed against the fixed contacts 21 and 23, while the slider 27 is pressed back.
At the same time the toggle member 17 is moved back during the rotation of the lever
arm. The comparatively weak spring 31 ensures that the slider is pressed back (i.e.
to the right in Figure 1) in such a way that its V-shaped bottom follows the toggle
member 17. Since the angle between the spring force of the toggle spring 19 and the
reaction forces from the fixed contacts is approx. 130°, as shown in the vector diagram
in Figure 3, the resulting force presses the contact member upwards and sidewards
along the contact surfaces. Thus a cleaning of the contact surfaces is achieved by
the sliding movement of the movable contact member along the contact surfaces, and
possible dirt is wiped off.
[0012] Preferably the movable contact member 25 is bent as shown in Figure 4 so that the
contact member has two contact surfaces 25
a and 25
e at each end and a first planar midpart 25
b, approx. perpendicular to the other midpart 25
d with the two midparts meeting at the bend 25
c. The angle between the contact surface 25
a and the first midpart 25
b is between 130° and 150°, preferably 140°.
[0013] The first midpart 25
b is, when mounted in the circuit breaker, approx. perpendicular to the slider and
is guided in a track at the end surface of the slider. The movable contact member
can be displaced in this track during the last part of the closing engagement, when
the self-cleaning takes place. The first midpart 25
b is provided with a cam 38, which supports the adjacent end of the spring 19 so that
the spring and the contact member 25 slip simultaneously, cleaning the contact surfaces.
The bend 25
c abuts a retainer surface 33, which, as shown in the drawing, can be a continuation
of the retainer wall 20. During the closing operation the retainer surface 33 stops
the movable contact member and thus limits the travel
x. The retainer surface 33 is preferably situated so that the angle between the retainer
surface and the displacement direction of the slider defined by the track 29 is approx.
20°.
[0014] During the opening operation the retainer surface 33 acts as a guiding surface for
the bend 25
c when the movable contact member is pressed back into its start position.
[0015] The movement of the movable contact member is thus triangular, as shown in Figure
5, where the first part of the closing operation is shown by the rectilinear movement
34 and the last part of the closing operation, i.e. the self-cleaning, is shown by
the vector 35 with the length
x. During the opening operation the movement follows the vector 36 defined by the retainer
surface 33.
[0016] The described embodiment of the circuit breaker possesses the additional advantage
of a surprisingly short bounce time, which is presumably due to the sliding engagement
combined with a dampening effect in the retainer wall and the contact member.
[0017] An angle of approx. 80° between the first and the second midparts 25
b and 25
d of the contact member is found to be especially advantageous for achieving a short
bounce time.
[0018] The proposed new circuit breaker thus enables a controlled, well-defined travel exactly
as long as is necessary for achieving a suitable cleaning of the contacts.
1. Electric circuit breaker with a housing comprising a pair of fixed contact members
or contact rails (21, 23) and a movable contact member (25) with a first and a second,
substantially parallel contact surface (25a, 25e), said movable contact member being displaceable for establishing a connection between
the two fixed contact members (21, 23) and with spring means (19) for pressing the
movable contact member (25) against the fixed contact members (21, 23) in a closed
position and where the movable contact member is attached to a slider (27), movable
on a guide track (29) provided for this purpose and aligned with the spring means
(19), said slider pressing the movable contact member into the open position when
subjected to a pressure-transferring mechanism (15, 16, 17) activated by the control
handle of the circuit breaker (11), and where the contact surfaces (25a, 25e) and the displacement direction of the guide track (29) of the slider form an angle
different from 90. characterised in that the angle is approx. 30°-60°, preferably approx. 50°, and that the movable
contact member further comprises a first and a second midpart (25b, 25d) between said first and second contact surfaces (25a, 25e), said first midpart (25b) being substantially perpendicular to the displacement direction of the slider (27),
and said second midpart (25d) being substantially parallel to the displacement direction of the slider (27).
2. Electric circuit breaker according to claim 1, characterised in that the guide track (29) in the housing is arranged in such a way that the angle
between the track (29) and the bottom of the normally horizontally installed housing
is approx. 10°, and such that the end of the slider (27) actuating the movable contact
member is closer to the bottom of the housing than the slider end subjected to the
pressure-transferring mechanism (15, 16, 17), and that the fixed and the movable contact
surfaces form an angle of approx. 60° with said bottom.
3. Electric circuit breaker according to claim 1 or 2, characterised in that the circuit breaker housing comprises a retainer surface (33) arranged such
that a bend (25c) connecting the first (25b) and the second planar midpart (25d) of the movable contact member abuts the retainer surface (33) in the closed position
of the circuit breaker and when the breaker is opened the bend (25c) is guided back to its start position by the retainer surface.
4. Electric circuit breaker according to claim 3, characterised in that the angle between the retainer surface (33) and the displacement direction
of the slider in the guide track (29) is approx. 20°, the top of the angle substantially
coinciding with the basis of the spring (19).
5. Electric circuit breaker according to claim 1, 2, 3 or 4, characterised in that the angle between the first contact surface (25a) and the first midpart (25b) is between 130. and 150°, preferably 140°.
6. Electric circuit breaker according to claim 1, 2, 3, 4 or 5, characterised in that the angle between the first midpart (25b) and the second midpart (25d) is between 75° and 90°, preferably 80°.