[0001] The present invention relates to an improved circuit breaker. More particularly the
present invention relates to an improved low voltage (i.e. for voltage values lower
than 1KV) circuit breaker, which is remotely controlled during the closing operation.
[0002] It is known that low voltage circuit breakers are aimed at interrupting the circulation
of current in a power distribution line, (for example in case of fault). This is achieved
by means of separating, generally using a suitable spring mechanism, two electric
contacts that are serially connected with the power distribution line (opening operation).
After an opening operation of the circuit breaker has been performed, it is necessary
to bring again the circuit breaker to normal functioning conditions and, therefore,
to couple the electric contacts (closing operation) of the circuit breaker, so as
to allow the current to flow. The closing operation is generally performed by means
of a manual closing mechanism. It is known that the manual closing operation can be,
in some cases, quite difficult, particularly when the circuit breaker is placed in
a difficulty accessible position or is placed quite far from the operator. In order
to solve this problem, remotely controlled circuit breakers have been introduced in
the state of the art. Remotely controlled circuit breakers are commonly provided with
a remotely controlled motor arrangement, which allows the operator to perform the
closing operation, without the need of a manual intervention. In fact, a motor arrangement
can be remotely activated, so as to generate a motion, which allows coupling the electric
contacts by means of suitable mechanical arrangements. After the electric contacts
are coupled, the motor arrangement is disengaged from the movable contact and the
circuit breaker continues its normal functioning, till a new opening operation is
performed.
[0003] Known remotely controlled circuit breakers are characterised by some drawbacks.
[0004] In fact, the mentioned remotely controlled motor arrangement generally comprises
a remotely controlled electric motor, whose overall size and occupied volume is often
relevant, due to the presence of the inductive/capacitor circuits and/or windings.
The practice has shown that this fact makes often quite difficult to install a remotely
controlled circuit breaker on a power distribution switchboard (in fact, at least
a so-called four-modules case is generally needed for including a remotely controlled
circuit breaker of the known type). Obviously, this provokes an increase of the installation
costs. Further, the presence of an electric motor makes necessary to provide for complex
mechanical arrangements for transmitting the motion generated by the electric motor
to the movable contact. The presence of complex mechanical arrangements implies obviously
a further increase of the overall size. Moreover, the reliability of the whole remotely
controlled circuit breaker is necessarily decreased, due to a higher probability of
mechanical faults. Further, the complexity of the mechanical arrangements that are
commonly adopted implies necessarily higher production costs.
[0005] The main aim of the present invention is to provide a remotely controlled circuit
breaker, which allows overcoming the drawbacks mentioned above.
[0006] Within this scope, another object of the present invention is to provide a remotely
controlled circuit breaker, which is characterised by remarkably reduced overall size
and volume.
[0007] Another object of the present invention is to provide a remotely controlled circuit
breaker, which allows achieving a strong simplification of the mechanical arrangements
and operating elements that are needed for transmitting the motion of the movable
contact, during the closing operation of the circuit breaker.
[0008] Another object of the present invention is to provide a remotely controlled circuit
breaker, which is characterised by a higher simplicity of installation and higher
reliability levels.
[0009] Not the least object of the present invention is to provide a remotely controlled
circuit breaker, which is easy to fabricate at competitive costs.
[0010] Thus, the present invention provides a remotely controlled circuit breaker, which
comprises at least a fixed contact and a movable contact that is coupled/de-coupled
with the fixed contact, respectively during the closing/opening operation of the remotely
controlled circuit breaker. The remotely controlled circuit breaker, according to
the present invention, further comprises remotely controlled motor means for coupling,
by means of motion transmission means, the movable contact to the fixed contact during
a closing operation of the circuit breaker. The remotely controlled circuit breaker,
according to the present invention, is characterized in that the remotely controlled
motor means comprise at least a remotely controlled piezoelectric motor assembly.
The remotely controlled piezoelectric motor assembly is operatively connected to the
motion transmission means, so as to couple the movable contact to the fixed contact
during a closing operation of the remotely controlled circuit breaker.
[0011] Further characteristics and advantages of the remotely controlled circuit breaker,
according to the present invention, will be better described hereinafter, with particular
reference to the enclosed figures, in which:
figure 1 schematically illustrates a block diagram representing schematically the
basic structure of the remotely controlled circuit breaker, according to the present
invention;
figure 2 schematically illustrates a preferred embodiment of a portion of the remotely
controlled circuit breaker, according to the present invention;
figure 3 schematically illustrates a block diagram representing schematically a preferred
embodiment of another portion of the remotely controlled circuit breaker, according
to the present invention;
figure 4 schematically illustrates a preferred embodiment of another portion of the
remotely controlled circuit breaker, according to the present invention;
figure 5 schematically illustrates a preferred embodiment of another portion of the
remotely controlled circuit breaker, according to the present invention;
figure 6 schematically illustrates another preferred embodiment of another portion
of the remotely controlled circuit breaker, according to the present invention.
[0012] Referring to figure 1, a block diagram illustrating the basic structure of the remotely
controlled circuit breaker (reference 1), according to the present invention, is represented.
[0013] The remotely controlled circuit breaker 1 comprises at least a fixed contact 3 and
a movable contact 2. The movable contact 2 is coupled/uncoupled with the fixed contact
3 respectively during the closing/opening operation of the remotely controlled circuit
breaker 1.
[0014] The remotely controlled circuit breaker 1 comprises further remotely controlled motor
means 4, for coupling, by means of motion transmission means 5, the movable contact
2 to the fixed contact 3, during a closing operation of the remotely controlled circuit
breaker 1. The remotely controlled motor means 4 comprise at least a remotely controlled
piezoelectric motor assembly 6, operatively connected to the motion transmission means
5, so as to couple the movable contact 2 with the fixed contact 3, during a closing
operation of the remotely controlled circuit breaker 1.
[0015] The remotely controlled piezoelectric motor assembly 6, comprises, advantageously,
a stator arrangement 7, which includes at least a piezoelectric assembly 8, operatively
connected to a stator frame 9. The remotely controlled piezoelectric motor assembly
6 comprises further a rotor arrangement 10, operatively connected the stator frame
9.
[0016] Referring now to figure 2, according to a preferred embodiment of the remotely controlled
circuit breaker 1, the stator frame 9 comprises preferably a flange element 11. The
flange element 11 is advantageously provided with a base wall 13 and a projecting
wall 12, which protrudes from the base wall 13 in a substantially vertical manner.
As illustrated in figure 2 (where only a portion of the flange element 11 is shown),
the piezoelectric assembly 8 comprises preferably one or more piezoelectric elements
15 that are mechanically coupled to the base wall 13. The piezoelectric elements 15
are advantageously excited by predefined excitation signals 16 (see also figure 1),
so as to determine an elliptical motion 17 of the projecting wall 12.
[0017] In fact, advantageously, two different portions (not shown) of the piezoelectric
elements 15 may be fed with excitation signals 16 that comprise two different ultrasonic
signals that are shifted of 90°. Therefore, the piezoelectric elements 15 of each
portion are forced to vibrate with a 90° phase-shift. The vibration is transmitted
to the projecting wall 12 and two 90°-shifted "travelling waves" (not shown) on the
projecting wall 12 are generated. In this manner, each point of the projecting wall
12 is subjected to an elliptical motion 17.
[0018] The excitation signals 16 (see figure 1) may be advantageously generated by a suitable
electronic circuit 160, placed closed to the remotely controlled motor assembly 6.
[0019] Remote control means 18, preferably placed in a position that can be easily accessed
by the operator, generate activation signals 180 and transmit them to the electronic
circuit 160. The transmission of the activation signals 180 may be performed according
to the techniques that are known to those skilled in the art. Particularly, the transmission
might be performed according to arrangements either of the traditional (electrical
connection) kind or the wireless kind. Alternatively, the electronic circuit 160 may
be integrated with the remote control means 18.
[0020] According to this embodiment of the present invention, the rotor arrangement 10 comprises
a rotor disc 19 (not shown in figure 2 but illustrated in figures 3 and 4). The rotor
disc 19 is mechanically coupled to the projecting wall 12, so as to be subjected to
a motion of the rotational kind.
[0021] According to a preferred embodiment of the present invention, which is schematically
illustrated in the block diagram of figure 3, the motion transmission means 5 preferably
comprise a shaft element 20 mechanically connected to the rotor disc 19. The shaft
element 20 might be mechanically coupled to the rotor disc 19 or, alternatively, be
integrated with structure of the rotor disc 19. Preferably, the motion transmission
means 5 may also comprise a toggle element 21, which is operatively connected to the
shaft element 20. In practice, the mechanical co-operation of the toggle element 21
with the shaft element 20, as it will be illustrated better in the following, may
be achieved by means of a gear assembly 22. Further, the motion transmission means
5 comprise preferably a kinematic chain 23, which operatively connects the toggle
element 21 with the movable contact 2, at least during the closing operation of remotely
controlled circuit breaker.
[0022] Referring now to figure 4, two different views of a preferred embodiment of the gear
assembly 22 are illustrated. The gear assembly 22 comprises preferably a pinion element
24, which is mechanically connected to the shaft element 20, and a rotating rack element
25, which is mechanically connected to the toggle element 21. The rotating rack element
25 mechanically cooperates with the pinion element 24, so as to transmit a motion
to the toggle element 21. In fact, if the rotor disc 19 rotates, for example in direction
of the arrow 26, the rotating rack element 25 moves in direction of the arrow 27 and,
consequently, the toggle element 21 is subjected to a motion according to the direction
indicated by the arrow 28. Particularly, as it can be noticed in figure 4, the rotational
motion of the rotor disc 19 is advantageously transformed in a motion 28 of the toggle
element 21.
[0023] As mentioned above, the toggle element 21 is operatively connected with the movable
contact 2, during a closing operation, by means of a kinematic chain 23. With reference
of the figure 5, the kinematic chain 23 chain comprises preferably a bar mechanism
30, which includes one or more bar elements 31 mechanically connected between the
movable contact 2 and the toggle element 21, so as to transmit a motion to the movable
contact 2 during a closing operation. As illustrated in figure 5, the bar mechanism
30 may comprise four bar elements 31. This is particularly advantageous in case the
remotely controlled circuit breaker is of the magneto-thermal kind. However, according
to the needs, the bar mechanism might comprise a different number of bar elements
31. For example, in case a remotely controlled residual current circuit breaker, five
bar elements may be advantageously used. As mentioned above, the kinematic chain 23
allows transmitting a motion to the movable contact 2, during a closing operation
of the remote controlled circuit breaker, according to the present invention. Particularly,
the bar mechanism 31 can be arranged, for example establishing suitable rotational
pivots, so as to transmit the motion of the toggle element 21 to the movable contact
2. With reference to the preferred embodiment illustrated in figure 5, a motion of
the toggle element 21 in direction of the arrow 28, provokes the translation of the
rotational pivot 35 may in direction of the arrow 32. This implies a decrease of the
angle 34 between elements 31
a and 31
b of the bar mechanism 30. In this manner, the movable contact is necessarily moved
in direction of the arrow 33 and, therefore, coupled with the fixed contact 3.
[0024] As soon as the movable contact 2 is coupled with the fixed contact 3, the toggle
element 21 is mechanically disengaged from the kinematic chain 23. This can be obtained
by means of trip mechanisms (not shown), whose arrangement is well known to those
skilled in the art. The same trip mechanism is able to engage the kinematic chain
23 with the spring mechanism, which is generally used for performing the separation
on the movable contact 2 from the fixed contact 3 (opening operation), when this is
required. In this manner, the remote controlled piezoelectric motor assembly 6 cannot
have any influence on the opening operation of the remotely controlled circuit breaker,
which is essentially determined by the mentioned spring mechanism, according to the
common market requirements and/or standards.
[0025] When an opening operation has been performed and, therefore, it is necessary to re-close
the electric contacts 2 and 3, the remotely controlled piezoelectric motor assembly
is brought to its initial position. This can be obtained by means of simply inverting
the phase delay of the predefined excitation signals. During this motion, by means
of the mentioned trip mechanism, the toggle element 21 is again mechanically engaged
with the kinematic chain 23. In this manner, the piezoelectric motor assembly 6 can
drive the closing operation of the remotely controlled circuit breaker.
[0026] Alternatively, in a preferred embodiment of the remotely controlled circuit breaker,
according to the present invention, the toggle element 21 can be connected with the
kinematic chain 23, in correspondence of the pivot point 35, which is, therefore,
subjected to a motion 28, directly impressed by the toggle element 21. In this case,
the kinematic chain 23 comprises a bar mechanism 30, which includes, in practice,
only two bar elements (31
a, 31
b), for transmitting a motion to the movable contact 2, during a closing operation
of the remotely controlled circuit breaker, according to the present invention. In
fact, in this case, the bar elements 31
c and 31
d are used only for the opening operation, once the toggle element 21 is disengaged
from the kinematic chain 23. Accordingly, the toggle element 21 might be connected
to the kinematic chain 23, in correspondence of other pivot points, such as for example
the pivot point 36. In this case, the kinematic chain 23 comprises a bar mechanism
30, which includes only the bar element 31
a. It should be noticed that, in this case, it would be quite easier to control, by
means of the piezoelectric motor assembly, also the opening operations of the remote
controlled circuit breaker 1.
[0027] The remotely controlled circuit breaker, according to the present invention, allows
achieving the intended aims and objects.
[0028] In fact, the adoption of the remotely controlled piezoelectric motor assembly 6 for
moving the movable contact 2 allows avoiding the use of electromagnetic arrangements.
In fact, the generation of motion by the remotely controlled piezoelectric motor assembly
is mainly, as shown in the illustrated preferred embodiments, of the "mechanical"
kind. This property allows achieving considerable advantages such as a remarkable
reduction of the number of operating elements and, therefore, a remarkably reduction
of the overall size and the volume occupied by the remotely controlled circuit breaker,
according to the present invention. In fact, the practice has shown that the remotely
controlled circuit breaker, according to the present invention, can be easily placed
in a so-called "two modules" case.
[0029] Moreover, due the absence of electromagnetic arrangements, which require the adoption
of huge winding structures, the remotely controlled circuit breaker, according to
the present invention, has proven also to be characterised by remarkably lower weight.
These facts, allows obtaining relatively lower fabrication and installation costs.
[0030] Further, the remarkable reduction of operating elements has proven to increase the
operation reliability and high torque levels at low speed and relatively reduced response
times can be easily achieved. This implies a remarkable increase of the operation
performance.
[0031] The remotely controlled circuit breaker, according to the present invention, is particularly
suitable for the use in low voltage applications, therefore for voltage values lower
than 1 KV.
[0032] Due to the fact that the use of the piezoelectric motor assembly 6 influences substantially
only the closing operations, the remotely controlled circuit breaker may be of different
types, according to the different modes that can be chosen for determining the opening
operations. Thus, the remotely controlled circuit breaker, according to the present
invention, can be used as a remotely controlled magneto-thermal circuit breaker or
as a remotely controlled residual current circuit breaker. As mentioned above, in
this case, a different using mode is determined, according to the needs, by means
of choosing a different opening mechanism.
[0033] The remotely controlled circuit breaker, according to the present invention, can
comprise one or more electric poles, each one comprising at least a movable contact
2 and a fixed contact 3. Particularly, the remotely controlled circuit breaker, according
to the present invention, can be of the three-pole kind or of the four-pole kind.
[0034] The remotely controlled circuit breaker, according to the present invention, thus
conceived is susceptible of numerous modifications and variations, all of which are
within the scope of the inventive concept. All the details may also be replaced with
other technically equivalent elements. In practice, the materials employed, so long
as they are compatible with the specific use, as well as the dimensions, may be any
according to the requirements and to the state of the art.
1. A remotely controlled circuit breaker comprising:
- at least a fixed contact and a movable contact, said movable contact being coupled/uncoupled
with said fixed contact, respectively during the closing/opening operation of said
remotely controlled circuit breaker; and
- remotely controlled motor means for coupling, by means of motion transmission means,
said movable contact to said fixed contact during a closing operation of said remotely
controlled circuit breaker;
characterized in that said remotely controlled motor means comprise at least a remotely controlled piezoelectric
motor assembly, said remotely controlled piezoelectric motor being operatively connected
to said motion transmission means, so as to couple said movable contact to said fixed
contact during a closing operation of said remotely controlled circuit breaker.
2. A remotely controlled circuit breaker, according to claim 1,
characterized in that said remotely controlled piezoelectric motor assembly, comprises:
- a stator arrangement comprising at least a piezoelectric assembly operatively connected
to a stator frame; and
- a rotor arrangement, operatively connected said stator frame.
3. A remotely controlled circuit breaker, according to claim 2, characterized in that said stator frame comprises a flange element provided with a base wall and a projecting
wall, said projecting wall protruding in a substantially vertical manner from said
base wall.
4. A remotely controlled circuit breaker, according to one or more of claims from 2 to
3, characterized in that said piezoelectric assembly comprises one or more piezoelectric elements mechanically
coupled to said base wall, said piezoelectric elements being excited by predefined
excitation signals, so as to determine an elliptical motion of said projecting wall.
5. A remotely controlled circuit breaker, according to one or more of claims from 2 to
4, characterized in that said rotor arrangement comprises a rotor disc, said rotor disc being mechanically
coupled said projecting wall, so as to be subjected to a motion of the rotational
kind.
6. A remotely controlled circuit breaker, according to one or more of claims from 2 to
5, characterized in that said remotely controlled piezoelectric motor assembly is connected to an electronic
circuit, said electronic circuit generating said predefined excitation signals and/or
transmitting said predefined excitation signals to said plurality of piezoelectric
elements.
7. A remotely controlled circuit breaker, according to one or more of claims from 2 to
6, characterized in that said electronic circuit is connected to remote control means, said remote control
means generating predefined activation signals and/or transmitting said predefined
activation signals to said electronic circuit.
8. A remotely controlled circuit breaker, according to one or more of the previous claims,
characterized in that said motion transmission means comprises at least:
- a shaft element mechanically connected to said rotor disc; and
- a toggle element operatively connected to said shaft element; and
- a kinematic chain for operatively connecting said toggle element with said movable
contact, at least during a closing operation of said remotely controlled circuit breaker.
9. A remotely controlled circuit breaker, according to claim 8, characterized in that said motion transmission means comprise a gear assembly for operatively connecting
said toggle element with said shaft element.
10. A remotely controlled circuit breaker, according to claim 9,
characterized in that said gear assembly comprises at least:
- a pinion element mechanically connected to said shaft element; and
- a rotating rack element mechanically connected to said toggle element, said rotating
rack element mechanically cooperating with said pinion element, so as to transmit
a motion to said toggle element.
11. A remotely controlled circuit breaker, according to one or more claims from 8 to 10,
characterized in that said kinematic chain comprises a bar mechanism comprising one or more bar elements,
mechanically connected between said movable contact and said toggle element, so as
to transmit a motion to said movable contact, at least during a closing operation
of said of said remotely controlled circuit breaker.
12. A remotely controlled circuit breaker, according to claim 11, characterized in that said bar mechanism comprises a single bar element.
13. A remotely controlled circuit breaker, according to claim 11, characterized in that said bar mechanism comprises two bar elements.
14. A remotely controlled circuit breaker, according to claim 11, characterized in that said bar mechanism comprises four bar elements.
15. A remotely controlled circuit breaker, according to claim 11, characterized in that said bar mechanism comprises five bar elements.
16. A remotely controlled circuit breaker, according to one or more of claims from 8 to
15, characterized in that said toggle element is mechanically disengaged from said kinematic chain when said
movable contact is coupled with said fixed contact.
17. A remotely controlled circuit breaker, according to one or more of the previous claims,
characterized in that it is a remotely controlled magneto-thermal circuit breaker.
18. A remotely controlled circuit breaker, according to one or more of claims from 1 to
16, characterized in that it is a remotely controlled residual current circuit breaker.