A nozzle for a breaker, and a breaker having such a nozzle

Description

Technical Field

[0001] The present invention relates to a nozzle for a medium and/or high voltage breaker, the breaker comprising at least two arcing contact members movable in relation to one another to at least one closed position where the arcing contact members are electrically connected to one another, and to at least one open position where the arcing contact members are disconnected from one another and form an electrically insulating gap between them. The nozzle is made partially of an electrically insulating material and is adapted to guide electrically insulating gas to the insulating gap, for preventing arcing between the arcing contact members when separating or connecting them. The nozzle comprises a nozzle portion adapted to be positioned in the region of the electrically insulating gap, and the nozzle comprises a first electrically conductive body which is entirely surrounded by the insulating material of the nozzle and electrically insulated from the arcing contact members. Further, the present invention relates to a breaker for medium and/or high voltage comprising a nozzle of the above-mentioned sort.

Background of the Invention

[0002] Breakers for medium and/or high voltage, e.g. 1 -1000 kV, which may also be called power breakers, circuit breakers, or interrupters, are provided in medium and/or high voltage electric systems to interrupt the electric circuit upon occurrence of specific operational conditions. The basic structure of breakers and their applications are well known to the person skilled in the art, and breakers can for example be installed in switchgears.

[0003] Breakers may comprise a housing which houses the contact members, or electrodes, of the breaker, and the housing may be filled with an electrically insulating gas, e.g. compressed gas. It is previously known to install an electrically insulating nozzle, e.g. formed by a dielectric material, in the gas-filled breaker. The nozzle is movable in relation to at least one contact member and is adapted to be positioned in the region of the electrically insulating gap which is formed between two separated contact members, more precisely the arcing contact members. The nozzle is adapted to guide a flow of electrically insulating gas to the insulating gap for preventing arcing during opening and closing operations. The flow of electrically insulating gas guided to the insulating gap by the nozzle can be said to blow out an arc which is struck between the two arcing contact members. In prior art, various designs of the features of the breaker are suggested in order to improve the performance or the structure of the breaker.

[0004] US 4,420,662 discloses a compressed-gas circuit breaker with two contact members which move in relation to one another, and a nozzle made of a dielectric material and attached to one of the contact members. An annular insert made of a conductive material is provided at the nozzle constriction.

[0005] JP 02-168524 describes a gas circuit breaker having a nozzle in which a shield is embedded, the shield being electrically connected to a movable main contact of the breaker.

[0006] JP 10-199382 describes a puffer-type gas breaker having a shield embedded on the contact side of a nozzle, the shield being electrically connected to a contact of the breaker.

[0007] DE 42 05 501-C1 discloses a high voltage breaker having two arc contacts and two rated current contacts, and a nozzle provided with one metal sleeve. The metal sleeve may be provided on the outside of the nozzle, or may be embedded inside the nozzle.

[0008] US 2009/0261070-A1 describes an insulating nozzle made of two different materials, and both of the materials may be electrically insulating materials.

[0009] GB 712,785 discloses an electric gas-blast circuit breaker which comprises an intermediate cylinder consisting of an insulating material and having a bulbous portion which projects into the space between an inner casing and a nozzle of an outer breaker casing, and one metal insert is provided within the body of the bulbous portion, the insert having the shape of part of a hollow sphere.

[0010] WO 2008/043721-A1 describes an insulating tube provided around the insulating nozzle of an interrupter. A second material may be moulded onto the inside or outside of the insulating tube.

[0011] DE 39 04 147-A1 discloses a metal-encapsulated, gas-blast power circuit breaker. In the region of the switching path, metallic fitting bodies, which at the same time form control rings, are fitted on the circumference of an insulating tube which accommodates the contact tubes of the breaker.

[0012] US 6,462,295-B1 describes a high voltage power breaker having two arc contacts and two rated current contacts, and an insulating nozzle projecting at least partially into the insulating gap between the contacts. The insulating nozzle has an annular filling attached to its outer circumference and made of insulating material having a dielectric constant above three.

[0013] EP 1 544 881-A1 discloses a nozzle for a gas-insulated switching device having a couple of separable arc contacts, and the nozzle has a hollow body comprising an electrically insulating portion and an annular conductive body partially surrounded by the insulating portion.

[0014] EP 1 772 882-A1 describes a gas-insulated breaker having an insulating nozzle. Onto the outer circumference of the nozzle, or in an open groove in the outer circumference of the nozzle, one or more electrically conductive or dielectric field element may be mounted.

[0015] CA 1077100 discloses a disconnect contact assembly for metal-clad switchgear, where nonlinear semiconductor coatings may be provided onto the surface of a tubular insulator which surrounds a conductive stud of the disconnect contact assembly.

The Object of the Invention

[0016] When separating the arcing contact members of a breaker, the arcing contact members are subjected to electric field stress because of the electric field produced in the insulating gap between the arcing contact members upon separation, which may impair the performance of the breaker and may result in wear on the arcing contact members.

[0017] The object of the present invention is to provide an improved breaker for medium and/or high voltage. It is a further object of the present invention to prevent secondary arcing between contact members of a breaker for medium and/or high voltage. It is also an object of the present invention to prevent wear on the arcing contact members of a breaker for medium and/or high voltage.

Summary of the Invention

[0018] The above-mentioned objects of the present invention are attained by providing a nozzle for a medium and/or high voltage (e.g. 1 -1000 kV) breaker as defined in the appended claim 1. The breaker comprises at least two arcing contact members movable in relation to one another to at least one closed position where the arcing contact members are electrically connected to one another, and to at least one open position where the arcing contact members are disconnected from one another and form an electrically insulating gap between them, the nozzle being made partially of an electrically insulating material and being adapted to guide electrically insulating gas to the insulating gap, for preventing arcing between the arcing contact members when separating or connecting them, the nozzle comprises a nozzle portion adapted to be positioned in the region of the electrically insulating gap, and the nozzle comprises a first electrically conductive body which is entirely surrounded by the insulating material of the nozzle and electrically insulated from the arcing contact members, wherein the nozzle comprises at least one second electrically conductive body which is at least partially surrounded by the insulating material of the nozzle and electrically insulated from the arcing contact members, wherein the at least one second electrically conductive body is spaced from the first electrically conductive body by a distance, wherein the conductive bodies are adapted to form a capacitive coupling between them, for electric field control in the insulating gap, and wherein at least one of the conductive bodies is electrically insulated from earth.

[0019] Thus, the nozzle comprises a first part in the form of the insulating material, and a second part in the form of the conductive bodies.

[0020] The conductive bodies are adapted to form a capacitive coupling between them such that efficient electric field control in the insulating gap is provided, e.g. such that an advantageous electric field distribution is formed in the insulating gap.

[0021] By combining the first electrically conductive body, which is entirely surrounded by the insulating nozzle material (i.e. the insulating material of the nozzle), with the at least one second electrically conductive body, which is at least partially surrounded by the insulating nozzle material, the electric field stress is efficiently displaced from the arcing contact members to the nozzle material and to the region between the conductive bodies, which has been shown in tests performed by the inventors of the present invention, whereby field stress on the arcing contact members is reduced. The maximum electric field between the arcing contact members in the insulating gap is efficiently reduced. Because of the reduced electric field stress on the arcing contact members, the risk of secondary arching, also called re-strike, between the arcing contact members is efficiently reduced. By entirely embedding and enclosing one of the electrically conductive bodies, any triple point with regard to this body is excluded, resulting in a reduced electric field level. When an electrically conductive body is not entirely surrounded by the insulating nozzle material but has an exposed surface in contact with the insulating gas, a triple point is formed between the conducting material of the conductive body, the insulating gas and the insulating material of the nozzle, and a triple point results in high electric field. A high electric field increases the risk of secondary arching between the arcing contact members, and increases the risk of electrical breakdown in the insulating nozzle material or in the insulating gas. Further, as a result of the present invention, a breaker which can withstand increased voltage levels is provided.

[0022] A dielectric material which is stressed beyond its dielectric strength undergoes an electrical breakdown. This results in the sudden transition of part of the dielectric material from an insulating state to a highly conductive state. This transition is characterized by the formation of an electric spark, and possibly an electric arc channel through the material. If an electrical breakdown occurs within a solid dielectric, e.g. within an insulating nozzle material, physical, chemical and structural changes along the path of the discharge will cause permanent degradation and significant reduction in the dielectric strength of the insulating material.

[0023] The inventors have realized that the problem of electric stress may be easier to handle within the insulating nozzle material than in the insulating gas. By providing the at least two conductive bodies within the insulating nozzle material according to the present invention, the "electric stress problem" is moved into the nozzle material, where the electric stress is efficiently taken care of by the inventive design of the nozzle.

[0024] In prior art, there are critical requirements with regard to the driving system which is adapted to control the relative movement of the arcing contact members, normally by controlling the movement of one of the arcing contact members, whereas the other is stationary, since the separation of the arcing contact members must be fast enough to provide a gap between the arcing contact members which is sufficiently large when the Transient Recovery Voltage, TRV, i.e. the voltage which appears across the circuit terminals due to redistribution of trapped energy between source and load side of the network, to which the breaker is connected, appears across the arcing contact members. If not, the electric field in the insulating gap will be too high, resulting in secondary arcing. By the present invention, the speed requirements with regard to the moving arcing contact members can be reduced and the moving arcing contact members does not need to move as fast as in prior art. As a result, the mechanism of the driving system can be less sophisticated, be more light-weight and less expensive, resulting in a less complicated, more compact and less bulky breaker, which has a reduced weight in relation to prior art breakers.

[0025] By the present invention, and the efficient decrease of the electric field strength in the insulating gap between the two arcing contact members, the breaker can use an insulating gas which has a lower breakdown voltage than SF₆. Sulphur hexafluoride, SF₆, may e.g. be replaced by CO₂, N₂, or even air, which are more environmentally friendly gases in relation to SF₆, and thus, a more environmentally friendly breaker may be provided. By the present invention, and for the reasons mentioned above, an improved nozzle is provided. The improved nozzle provides an improved breaker for medium and/or high voltage, which is subjected to less stress and is more durable.

[0026] The distance between the at least one second electrically conductive body and the first electrically conductive body may be set and optimized based on the design of the arcing contact members, the arcing contact member separation speed, the overall structure of the breaker, the composition of the insulating gas used in the breaker, and the electric field pattern in the region of the insulating gap between the arcing contact members.

[0027] The nozzle may have a tubular shape and may be adapted to be positioned around the insulating gap, the nozzle portion may e.g. be tubular, and the conductive bodies may advantageously be annular, ring-shapes and/or tubular, and adapted to be positioned around the insulating gap.

[0028] According to a further advantageous embodiment of the nozzle according to the present invention, the conductive bodies may be optimized in their shape and spatial location so that the breaker, in order to improve the re-strike performance, experiences the least stress in the arcing gaps when the arcing contact members reach half-way between closed and fully open positions along the travel path.

[0029] According to another advantageous embodiment of the nozzle according to the present invention, the at least one second electrically conductive body is entirely surrounded by the insulating material of the nozzle.

[0030] By this embodiment, any triple point with regard to all the conductive bodies is excluded, and a further electric field strength reduction in the region of the insulating gap is efficiently provided, which has been shown in tests performed by the inventors of the present invention. The above-mentioned positive effects of the present invention are thus further enhanced, and a further improved nozzle and breaker for medium and/or high voltage are provided.

[0031] According to an advantageous embodiment of the nozzle according to the present invention, both the first electrically conductive body and the at least one second electrically conductive body are electrically insulated from earth.

[0032] By having both conductive bodies insulated from the earth/ground, it is easier to manufacture the nozzle, to install the nozzle in the breaker, and to assemble the breaker, since the second conductive body does not have to be electrically connected to earth, e.g. by a wire etc. The nozzle is just put in place inside the breaker. Hereby, a further improved nozzle and breaker for medium and/or high voltage are provided.

[0033] According to a further advantageous embodiment of the nozzle according to the present invention, said nozzle portion comprises at least one of the conductive bodies. According to another advantageous embodiment of the nozzle according to the present invention, said nozzle portion comprises the first electrically conductive body and the at least one second electrically conductive body. The nozzle portion may be tubular and adapted to be positioned around the insulating gap. Advantageously, in the open position, the nozzle portion is adapted to be positioned adjacent to the insulating gap.

[0034] The insulating material of the nozzle can for example be formed by one polymer or a plurality of polymers, e.g. a composite material, and suitable polymers are known to the skilled person.

[0035] According to still another advantageous embodiment of the nozzle according to the present invention, the insulating material of the nozzle comprises a dielectric material. Examples of suitable dielectric materials are well known to the skilled person.

[0036] Each conductive body comprises an outer surface facing the insulating material of the nozzle, and at least one surface portion of the outer surface of at least one of the conductive bodies comprises a nonlinear field grading material, FGM. The at least one surface portion may be formed by a layer of FGM, for example, by covering a portion of the conductive body with a layer of FGM. The FGM layer may have a suitable thickness. Alternatively, the entire outer surface of the conductive body may comprise FGM, and the outer surface may be formed by a layer of FGM.

[0037] By the inventive provision of the field grading material, the inventors of the present invention address the increased risk of an electrical breakdown in the insulating nozzle material because of the increased electric field strength in the insulating nozzle material. The inventors have identified that the electric field strength is highest at the surface of the conductive body. By introducing the nonlinear field grading material according to this embodiment, the electric field at the surface of the conductive body is efficiently distributed, or smoothed out, and the electric field stress on the conductive body surface and on the insulating nozzle material is reduced, and the risk of an electrical breakdown in the insulating nozzle material is efficiently reduced.

[0038] A field grading material is a material adapted to grade or to guide the electric field. Examples of so called field grading material, FGM, which can be used as defined by the advantageous embodiments of the nozzle according to the present invention, are for example mentioned in WO-A1-2008/076058 and EP-A1-1 736 998. However, other suitable FGM may also be used.

[0039] According to an advantageous embodiment of the nozzle according to the present invention, the nonlinear field grading material is a resistive field grading material with a resistivity which is a function of the electric field. Alternatively, a capacitive field grading material with field dependent permittivity may be used.

[0040] By introducing a resistive nonlinear field grading material according to this embodiment, the reduction of the electric field strength at the surface of the conductive body is further improved, the electric field stress on the insulating nozzle material is further reduced, and the risk of an electrical breakdown in the insulating nozzle material is further reduced.

[0041] According to a further advantageous embodiment of the nozzle according to the present invention, the at least one surface portion of at least one of the conductive bodies faces an adjacent other conductive body. The inventors of the present invention have found that the electric field is highest at the surface of the conductive body which faces another conductive body. By this embodiment, the reduction of the electric field strength at the surface of the conductive body is further improved, and the risk of an electrical breakdown in the insulating nozzle material is further reduced.

[0042] According to another advantageous embodiment of the nozzle according to the present invention, the at least one surface portion of at least one of the conductive bodies is located at a shorter distance to an adjacent other conductive body in relation to the remainder portion of the outer surface of the conductive body comprising the at least one surface portion.

[0043] The inventors of the present invention have found that the electric field is highest at the surface of the conductive body where the distance to another conductive body is the shortest. By this embodiment, the reduction of the electric field strength at the surface of the conductive body is still further improved, and the risk of an electrical breakdown in the insulating nozzle material is still further reduced.

[0044] According to yet another advantageous embodiment of the nozzle according to the present invention, at least one of the conductive bodies has a terminal portion facing an adjacent other conductive body, and the terminal portion is convex towards the adjacent other conductive body. By giving the conductive body a smoothly curved surface towards an adjacent other conductive body, the inventors of the present invention have found, i.e. via tests performed by them, that the electric field at the surface of the conductive body is efficiently distributed, or smoothed out, and the electric field strength at the conductive body surface is further reduced, and a further reduced risk of an electrical breakdown in the insulating nozzle material is attained.

[0045] According to another advantageous embodiment of the nozzle according to the present invention, the conductive body, which has the convex terminal portion, has a longitudinal extension toward an adjacent other conductive body and defines a longitudinal axis, and the convex terminal portion has a radial extension which exceeds the radial extension of the remainder portion of the conductive body having the convex terminal portion. This embodiment further improves the distribution of the electric field at the surface of the conductive body, which has been shown in tests performed by the inventors of the present invention, and a still further reduced risk of an electrical breakdown in the insulating nozzle material is attained.

[0046] The above-mentioned reduced risk of an electrical breakdown in the insulating nozzle material, as a result of the inventive and efficient electric field control, provides an efficiently improved nozzle, which in turn provides an efficiently improved breaker for medium and/or high voltage.

[0047] The material of the conductive bodies may for example comprise graphite, carbon black, metal oxides, mercury etc. However, other materials for the conductive bodies are possible.

[0048] According to still another advantageous embodiment of the nozzle according to the present invention, at least one conductive body comprises an electrically conductive liquid material filled into a compartment formed by the insulating material of the nozzle.

[0049] It may be complicated to add and embed a second material into the nozzle material, e.g. when the insulating material of the nozzle is formed by polytetrafluoroethylene, PTFE, which has weak adhesion properties, and because the different materials may have different thermal expansion and contraction properties. By using a liquid material for the conductive bodies, e.g. an electrically conducting gel or oil, the problems of the difference in thermal expansion and contraction properties are overcome. The manufacturing of the nozzle is also facilitated, which provides for a less expensive nozzle, and a consequently a less expensive breaker. Suitable electrically conducting liquids, such as gels or oils, are known to the person skilled in the art. According to an advantageous embodiment of the nozzle according to the present invention, the insulating nozzle material is formed by fluorinated ethylene propylene, FEP. FEP may be easier to process in relation to PTFE. According to another advantageous embodiment of the nozzle according to the present invention, an adhesive, for example an epoxy adhesive, can be provided between the conductive body and the insulating nozzle material, in order to facilitate the provision of the conductive body inside the insulating nozzle material.

[0050] According to an advantageous embodiment of the nozzle according to the present invention, the nozzle comprises at least one compartment formed by the insulating material of the nozzle, the compartment having a wall surface, at least one conductive body comprises at least one electrically conductive layer, and the wall surface comprises the at least one electrically conductive layer. By this embodiment, hollow conductive bodies are provided, which also reduces the problems of the difference in thermal expansion and contraction properties. Further, the hollow conductive bodies add little weight to the nozzle, whereby a light-weight nozzle, and consequently a light-weight breaker, may be provided. The light-weight nozzle requires a less sophisticated driving mechanism for controlling the arcing contact member to which the nozzle may be physically connected. An improved nozzle and breaker are thus provided.

[0051] According to a further advantageous embodiment of the nozzle according to the present invention, the nozzle comprises at least two second electrically conductive bodies. By this embodiment, the nozzle is provided with at least three embedded conductive bodies. By providing more than two conductive bodies, there are more distances between conductive bodies which may be adjusted and optimized for a particular breaker design, and the re-strike prevention and breakdown prevention can be tailored and adapted in a more sophisticated way for a particular breaker design, whereby a further improved breaker can be provided.

[0052] The above-mentioned objects of the present invention are also attained by providing a breaker for medium and/or high voltage, e.g. 1-1000 kV, comprising at least two arcing contact members movable in relation to one another to at least one closed position where the arcing contact members are electrically connected to one another, and to at least one open position where the arcing contact members are disconnected from one another and form an electrically insulating gap between them, and a nozzle adapted to guide electrically insulating gas to the insulating gap, for preventing arcing between the arcing contact members when separating or connecting them, wherein the nozzle comprises the features mentioned in any of the appended claims 1 to 9, or the features of any of the above-mentioned embodiments of the nozzle. Hereby, an improved breaker is provided for reasons stated above in connection with the disclosure of the nozzle according to the present invention.

[0053] According to an advantageous embodiment of the breaker according to the present invention, the nozzle is physically connected to a movable first arcing contact member of the arcing contact members, and the nozzle is adapted to move together with the first arcing contact member in relation to the other arcing contact member. This is an efficient way to mount the nozzle and control the movement of the nozzle inside the breaker.

[0054] According to a further advantageous embodiment of the breaker according to the present invention, the breaker comprises at least two rated current contact members movable in relation to one another to at least one closed position where the rated current contact members are electrically connected to one another, and to at least one open position where the rated current contact members are separated from each other, and the electrically conductive bodies are insulated from the at least two rated current contact members. By the nozzle according to the present invention, an efficient breaker, having at least two rated current contact members and at least two arcing contact members, is provided.

[0055] According to another advantageous embodiment of the breaker according to the present invention, the breaker comprises a housing which houses the contact members and the nozzle, the housing separates the insulating gap from an atmosphere outside the housing, and the housing is filled with the insulating gas. By the nozzle according to the present invention, an efficient insulating gas-filled breaker is provided.

[0056] According to yet another advantageous embodiment of the breaker according to the present invention, the insulating gas comprises CO₂. By the present invention, and the efficient decrease of the electric field strength in the insulating gap between the two arcing contact members, one can use CO₂ instead of the insulating gas SF₆. SF₆ has a higher dielelectric strength and a higher breakdown voltage than CO₂. CO₂ is more environmentally friendly than SF₆, and by this embodiment a more environmentally friendly breaker is provided. However, the insulating gas of the breaker may also comprise other insulating gases, e.g. N₂, air, and even SF₆.

[0057] According to an advantageous embodiment of the breaker according to the present invention, the dielectric strength of the insulating nozzle material is higher than the dielectric strength of the insulating gas contained in the housing of the breaker. Tests performed by the inventors have shown that this is an advantageous relationship, which provides an efficient control of the electric field, and provides an improved breaker. However, other relationships between the dielectric strength of the insulating nozzle material and the insulating gas, respectively, are also possible.

[0058] The above-mentioned embodiments and features of the nozzle and breaker, respectively, may be combined in various possible ways providing further advantageous embodiments.

[0059] Further advantageous embodiments of the nozzle and the breaker according to the present invention and further advantages with the present invention emerge from the detailed description of embodiments.

Brief Description of the Drawings

[0060] The present invention will now be described, for exemplary purposes, in more detail by way of embodiments and with reference to the enclosed drawings, in which:

Fig. 1

is a schematic side view showing a longitudinal section of a part of an embodiment of the breaker according to the present invention, to the left of the axis of symmetry z-z the breaker being shown in a closed position, and to the right of the axis z-z the breaker being shown in an open position;

Fig. 2

is a schematic side view showing a longitudinal section of a first embodiment of the nozzle according to the present invention, when the breaker is in an open position;

Fig. 3

is a schematic side view showing a longitudinal section of a second embodiment of the nozzle according to the present invention; and

Fig. 4

is a schematic side view showing a longitudinal section of a third embodiment of the nozzle according to the present invention.

Detailed Description of Preferred Embodiments

[0061] Fig. 1 schematically shows a longitudinal section of a part of an embodiment of the breaker for medium and/or high voltage, e.g. 1-1000 kV, such as 12, 24 or 36 kV, according to the present invention, in a closed position (a conducting or connected state), and also in an open position (a non-conducting or disconnected state). To the left of the axis of symmetry z-z the breaker is shown in the closed position, and to the right of the axis z-z the breaker is shown in the open position. The breaker is substantially rotation symmetric around the axis z-z, and thus, the entire structure of the breaker in the open position is obtained by rotating the section to the right of the axis z-z 360 degrees about the axis z-z, and the entire structure of the breaker in the closed position is obtained by rotating the section to the left of the axis z-z 360 degrees about the axis z-z.

[0062] The breaker comprises a first and a second arcing contact member 102, 104 movable in relation to one another to at least one closed position (shown to the left of the axis z-z) where the arcing contact members 102, 104 are electrically connected to one another, and to at least one open position (shown to the right of the axis z-z) where the arcing contact members 102, 104 are disconnected from one another and form an electrically insulating gap 106 between them. The first arcing contact members 102 is tubular and the second arcing contact members 104 has the shape of a cylindrical rod. Further, the breaker comprises a first and a second rated current contact member 108, 110 movable in relation to one another to at least one closed position (shown to the right of the axis z-z) where the rated current contact members 108, 110 are electrically connected to one another, and to at least one open position (shown to the left of the axis z-z) where the rated current contact members 108, 110 are separated from each other, and form a second insulating gap 112 between them. The first and second rated current contact members 108, 110 are both tubular. However, the contact members 102, 104, 108, 110 may have other shapes and designs.

[0063] In this embodiment, the first arcing contact member 102 and the first rated current contact member 108 are adapted to be connected to the load (ground) side of an electric system to which the breaker is connected, and the other two contact members 104, 110 are adapted to be connected to the high voltage (source) side of the electric system. However, it could also be vice versa.

[0064] The breaker includes a tubular housing 114 which is made of an insulating material and defines a longitudinal axis z-z. The exterior of the housing 114 is in a conventional way provided with wing-shaped sheds 116 made of a polymer material, e.g. silicone. The housing 114 houses the contact members 102, 104, 108, 110 and separates the insulating gaps 106, 112 from an atmosphere outside the housing 114, and the housing 114 is filled with an electrically insulating gas, e.g. comprising CO₂, N₂, air, or SF₆, e.g. compressed insulating gas. The housing 114 also defines a space between its inner periphery and the contact members 102, 104, 108, 110.

[0065] In this embodiment, the first arcing contact member 102 and the first rated current contact member 108 are movable in relation to the housing 114, whereas the second arcing contact member 104 and the second rated current contact member 110 are stationary in relation to the housing 114.

[0066] When the breaker is in the closed (connected) position, the main current path is provided via the first and second rated current contact members 108, 110. To interrupt the current path of the breaker and to bring the breaker to the open position, firstly, the rated current contact members 108, 110 are disconnected from one another by axially moving the rated current contact member 108 and the first arcing contact member 102 downward in Fig. 1, while the arcing contact members 102, 104 maintain their connection to one another. Subsequently, by further axial movement of the rated current contact member 108 and the first arcing contact member 102 in a downward direction, the arcing contact members 102, 104 are disconnected from one another. By this disconnecting procedure, any arching between the rated current contact members 108, 110 are prevented, and any arc is struck between the arcing contact members 102, 104. Consequently, the stress on the rated current contact members 108, 110 is reduced.

[0067] The breaker includes a tubular shaped nozzle 202, 302, 402 which is adapted to be positioned around the insulating gap 106, and the nozzle 202 is adapted to guide electrically insulating gas to the insulating gap 106, for preventing arcing between the arcing contact members 102, 104 when separating them. The nozzle 202 is adapted to guide the insulating gas via at least one channel 118.

[0068] In a conventional way known to the person skilled in the art, the breaker is provided with a mechanism and a control system to control the breaker and the movement of the movable contact members, and the breaker is provided with conventional equipment to provide the nozzle with a flow of insulating gas in order to guide insulating gas to the insulating gap.

[0069] In Figs. 2-4, embodiments of the nozzle 202, 302, 402 according to the present invention are shown in more detail. Each nozzle is adapted to be installed in a breaker for medium and/or high voltage, e.g. 1-1000 kV, such as the breaker shown in Fig. 1.

[0070] Each nozzle 202, 302, 402 is made partially, and to the major part, of a solid electrically insulating material 204, 304, 404, e.g. a dielectric material, e.g. PTFE, but other insulating materials, e.g. composite materials, may also be used. Herein, the nozzle 202 is physically connected to the first arcing contact member 102 and to the first rated current contact member 108, and the nozzle 202 is adapted to move together with the first arcing contact member 102 and the first rated current contact member 108 in relation to the housing 114 and in relation to the stationary second arcing contact member 104 and the stationary second rated current contact member 110. The nozzle comprises a nozzle portion 206, 306, 406 adapted to be positioned in the region of the insulating gap 106 between the arcing contact members 102, 104. In this embodiment, the nozzle 202 is adapted to project, at least partially in the open position, between the first arcing contact member 102 and the first rated current contact member 108, and between the second arcing contact member 104 and the second rated current contact member 110. In the open position, when the arcing contact members 102, 104 are disconnected, the nozzle portion 206, 306, 406 is adjacent to the insulating gap, and the nozzle 202 separates the insulating gap 106 from the second insulating gap 112 between the rated current contact members 108, 110.

[0071] With reference to Fig. 2, a first embodiment of the nozzle 202 according to the present invention is schematically shown. The nozzle 202 includes a first electrically conductive body 208 and a second electrically conductive body 210 both being entirely surrounded by the insulating material 204 of the nozzle 202 and electrically insulated from the contact members 102, 104, 108, 110 and from earth/ground. The electrically conductive bodies 208, 210 are annular, ring-shaped, or tubular shaped, and adapted to be positioned around the insulating gap 106, and are spaced apart by a distance, the distance being filled with the insulating material 204. Alternatively, the electrically conductive body 208 on the load (ground) side could be electrically connected to earth, by suitable means. Alternatively, one of the electrically conductive bodies 208 could be partially surrounded by the insulating nozzle material 204 instead of entirely surrounded. The conductive bodies 208, 210 are adapted to form a capacitive coupling between them, and there is a capacitance between the conductive bodies 208, 210. In the first embodiment, the conductive bodies 208, 210 are formed by a solid conducting material. Each conductive body 208, 210 comprises an outer surface 212, 214 facing the insulating nozzle material 204, and a surface portion 216, 218 of the outer surface 212, 214 of the conductive bodies 208, 210 comprises a nonlinear field grading material, FGM, e.g. a resistive field grading material with a field dependent electrical resistivity, e.g. SiC or ZnO fillers in a suitable polymer base. The surface portion 216, 218 is advantageously formed by a layer of FGM, which e.g. is applied to the conductive body, e.g. by covering. The FGM layer has a suitable thickness. Reference is made to WO-A1-2008/076058 and EP-A1-1 736 998 for examples of FGM which may used. However, other suitable FGM may also be used. The surface portion 216, 218 of each conductive body 208, 210 has a suitable thickness and faces the adjacent other conductive body 208, 210, and is located at a shorter distance to the adjacent other conductive body 208, 210 in relation to the remainder portion of the outer surface 212, 214 of the conductive body 208, 210. Each conductive body 208, 210 also has a terminal portion 220, 222 facing the adjacent other conductive body 208, 210, and the terminal portion 220, 222 is convex towards the adjacent other conductive body 208, 210. The conductive body 208, 210 has a longitudinal extension toward the adjacent other conductive body 208, 210 and defines a longitudinal axis. The convex terminal portion 220, 222 may have a radial extension which exceeds the radial extension of the remainder portion of the conductive body 208, 210.

[0072] With reference to Fig. 3, a second embodiment of the nozzle 302 according to the present invention is schematically shown. The nozzle 302 includes three conductive bodies 308, 310, 312 all being entirely surrounded by the insulating material 304 of the nozzle 302 and electrically insulated from the contact members 102, 104, 108, 110 and from earth/ground. The electrically conductive bodies 308, 310, 312 are annular, ring-shaped or tubular, and adapted to be positioned around the insulating gap 106, and are spaced apart by distances, and are adapted to form capacitive couplings between them. For each conductive body 308, 310, 312, the nozzle 302 comprises one compartment 314 formed by the insulating nozzle material 302, each compartment 314 having a wall surface 316. Each conductive body 308, 310, 312 comprises at least one electrically conductive layer 318, and the wall surface 316 comprises the at least one electrically conductive layer 318. In Fig. 3, the compartment, the wall surface and the conductive layer are only shown with regard to one of the conductive bodies 310, but a plurality or all of the conductive bodies may naturally be designed in a corresponding way.

[0073] With reference to Fig. 4, a third embodiment of the nozzle 302 according to the present invention is schematically shown. The nozzle 402 includes four conductive bodies 408, 410, 412, 414 all being entirely surrounded by the insulating material 404 of the nozzle 402 and electrically insulated from the contact members 102, 104, 108, 110 and from earth/ground. The electrically conductive bodies 408, 410, 412, 414 are annular, ring-shaped or tubular, and adapted to be positioned around the insulating gap 106, and are spaced apart by distances, and are adapted to form capacitive couplings between them. Each conductive body 408, 410, 412, 414 is formed by an electrically conductive liquid material filled into a compartment which the insulating nozzle material 404 forms for each conductive body 408, 410, 412, 414.

[0074] Alternatively, the above-mentioned embodiments of the nozzle could also be provided with more conductive bodies, e.g. more than four conductive bodies, and the different kinds of conductive bodies could be mixed in one and the same nozzle. Other kinds and shapes of the conductive bodies are possible.

[0075] The second and third embodiments of the nozzle may also be provided with FGM in a corresponding way as is disclosed in connection with the first embodiment of Fig. 2.

[0076] The shape of each conductive body, the size of each conductive body in relation to the size of the nozzle, the distance between two adjacent conductive bodies, the position of each conductive body within the insulating nozzle material in relation to the surroundings are based on and optimized for the design of the arcing contact members, the arcing contact member separation speed, the overall structure of the breaker, the properties of the insulating nozzle material, the composition of the insulating gas used in the breaker, the critical distance between the arcing contact members where the risk of re-strike is highest, and the electric field pattern in the region of the insulating gap between the arcing contact members. Especially the distance between adjacent conductive bodies is important for the optimization.

[0077] The invention shall not be considered limited to the embodiments illustrated, but can be modified and altered in many ways by one skilled in the art, without departing from the scope of the appended claims.

Claims

1. A nozzle (202; 302; 402) for a medium and/or high voltage breaker, the breaker comprising at least two arcing contact members (102, 104) movable in relation to one another to at least one closed position where the arcing contact members are electrically connected to one another, and to at least one open position where the arcing contact members (102, 104) are disconnected from one another and form an electrically insulating gap (106) between them, the nozzle being made partially of an electrically insulating material (204; 304; 404) and being adapted to guide electrically insulating gas to the insulating gap (106), for preventing arcing between the arcing contact members when separating or connecting them, the nozzle comprises a nozzle portion (206; 306; 406) adapted to be positioned in the region of the electrically insulating gap, and the nozzle comprises a first electrically conductive body (208; 308; 408) and at least one second electrically conductive body (210; 310, 312; 410, 412, 414) which is at least partially surrounded by the insulating material of the nozzle and electrically insulated from the arcing contact members, the at least one second electrically conductive body being spaced from the first electrically conductive body by a distance, and the conductive bodies are adapted to form a capacitive coupling between them, for electric field control in the insulating gap, and at least one of the conductive bodies is electrically insulated from earth, characterized in that the first electrically conductive body (208; 308; 408) is entirely surrounded by the insulating material of the nozzle and electrically insulated from the arcing contact members, in that each conductive body (208, 210) comprises an outer surface (212, 214) facing the insulating material (204) of the nozzle, and in that at least one surface portion (216, 218) of the outer surface of at least one of the conductive bodies (208, 210) comprises a nonlinear field grading material.

2. A nozzle according to claim 1, characterized in that the at least one second electrically conductive body (210; 310, 312; 410, 412, 414) is entirely surrounded by the insulating material (204; 304; 404) of the nozzle.

3. A nozzle according to claim 1 or 2, characterized in that both the first electrically conductive body and the at least one second electrically conductive body are electrically insulated from earth.

4. A nozzle according to any of the claims 1 to 3, characterized in that the at least one surface portion (216, 218) of at least one of the conductive bodies faces an adjacent other conductive body.

5. A nozzle according to claims 3 or 4, characterized in that the at least one surface portion (216, 218) of at least one of the conductive bodies (208, 210) is located at a shorter distance to an adjacent other conductive body in relation to the remainder portion of the outer surface of the conductive body (208, 210) comprising the at least one surface portion.

6. A nozzle according to any of the claims 1 to 5, characterized in that at least one of the conductive bodies (208, 210) has a terminal portion (220, 222) facing an adjacent other conductive body, and in that the terminal portion is convex towards the adjacent other conductive body (208, 210).

7. A nozzle according to any of the claims 1 to 6, characterized in that at least one conductive body (408, 410, 412, 414) comprises an electrically conductive liquid material filled into a compartment formed by the insulating material of the nozzle.

8. A nozzle according to any of the claims 1 to 7, characterized in that the nozzle (302) comprises at least one compartment (314) formed by the insulating material (304) of the nozzle, the compartment having a wall surface (316), in that at least one conductive body (310) comprises at least one electrically conductive layer (318), and in that the wall surface comprises the at least one electrically conductive layer.

9. A nozzle according to any of the claims 1 to 8, characterized in that the nozzle comprises at least two second electrically conductive bodies.

10. A breaker for medium and/or high voltage, comprising at least two arcing contact members (102, 104) movable in relation to one another to at least one closed position where the arcing contact members are electrically connected to one another, and to at least one open position where the arcing contact members are disconnected from one another and form an electrically insulating gap (106) between them, and a nozzle (202; 302; 402) adapted to guide electrically insulating gas to the insulating gap, for preventing arcing between the arcing contact members when separating or connecting them, characterized in that the nozzle (202; 302; 402) comprises the features mentioned in any of the claims 1 to 9.

11. A breaker according to claim 10, characterized in that the nozzle (202; 302; 402) is physically connected to a movable first arcing contact member (102) of the arcing contact members, and in that the nozzle is adapted to move together with the first arcing contact member in relation to the other arcing contact member (104).

12. A breaker according to claim 10 or 11, characterized in that the breaker comprises at least two rated current contact members (108, 110) movable in relation to one another to at least one closed position where the rated current contact members are electrically connected to one another, and to at least one open position where the rated current contact members are separated from each other, and in that the conductive bodies are insulated from the at least two rated current contact members.

13. A breaker according to any of the claims 10 to 12, characterized in that the breaker comprises a housing (114) which houses the contact members and the nozzle, in that the housing separates the insulating gap (106) from an atmosphere outside the housing (114), and in that the housing is filled with the insulating gas.

14. A breaker according to claim 13, characterized in that the insulating gas comprises CO₂.

Ansprüche

1. Eine Düse (202; 302; 402) für einen Mittelspannungs - und/oder Hochspannungsschalter, wobei der Schalter mindestens zwei Lichtbogenkontaktstücke (102, 104) aufweist, die relativ zueinander beweglich sind zu mindestens einer geschlossenen Position, in der die Lichtbogenkontaktstücke miteinander elektrisch verbunden sind, und zu mindestens einer offenen Position, in der die Lichtbogenkontaktstücke (102, 104) voneinander getrennt sind und einen elektrisch isolierenden Spalt (106) zwischen einander bilden, wobei die Düse teilweise aus einem elektrisch isolierenden Material (204, 304, 404) hergestellt ist und angepasst ist, elektrisch isolierendes Gas zu dem isolierenden Spalt (106) zu führen zum Verhindern einer Lichtbogenbildung zwischen den Lichtbogenkontaktstücken, wenn diese getrennt oder verbunden werden, die Düse weist einen Düsenabschnitt (206, 306, 406) auf, welcher angepasst ist im Bereich des elektrisch isolierenden Spalts angeordnet zu werden, und die Düse weist einen ersten elektrisch leitenden Körper (208, 308; 408) und mindestens einen zweiten elektrisch leitenden Körper (210, 310, 312, 410, 412, 414) auf, welcher zumindest teilweise von dem isolierenden Material der Düse umgeben istund von den Lichtbogenkontaktstücken elektrisch isoliert ist, wobei der mindestens eine zweite elektrisch leitende Körper von dem ersten elektrisch leitenden Körper um einen Abstand beabstandet ist, und die leitenden Körper angepasst sind um eine kapazitive Kopplung zwischen einander zu bilden zum Steuern elektrischen Feldes in dem isolierenden Spalt, und mindestens einer der leitenden Körper von der Erde elektrisch isoliert ist, dadurch gekennzeichnet, dass der erste elektrisch leitende Körper (208, 308; 408) von dem isolierenden Material der Düse vollständig umgeben ist und von den Lichtbogenkontaktstücken elektrisch isoliert ist, dass jeder leitende Körper (208, 210) eine äußere Oberfläche (212, 214) aufweist, welche dem isolierenden Material (204) der Düse zugewandt ist, und dass mindestens ein Oberflächenabschnitt (216, 218) der äußeren Oberfläche (212, 214) mindestens eines der leitenden Körper (208, 210) einen nichtlinearen Feldsteuerungsmaterial aufweist.

2. Düse nach Anspruch 1, dadurch gekennzeichnet, dass der mindestens eine zweite elektrisch leitende Körper (210, 310, 312, 410, 412, 414) von dem isolierenden Material (204, 304, 404) der Düse vollständig umgeben ist.

3. Düse nach Anspruch 1 oder 2, dadurch gekennzeichnet, dass sowohl der erste elektrisch leitende Körper und der zumindest eine zweite elektrisch leitende Körper von der Erde elektrisch isoliert sind.

4. Düse nach einem der Ansprüche 1 bis 3, dadurch gekennzeichnet, dass der mindestens eine Oberflächenabschnitt (216, 218) mindestens eines der leitenden Körper einer benachbarten anderen leitenden Körper zugewandt ist.

5. Düse nach Anspruch 3 oder 4, dadurch gekennzeichnet, dass der mindestens eine Oberflächenabschnitt (216, 218) mindestens eines der leitenden Körper (208, 210) in einer geringeren Entfernung zu einem benachbarten anderen leitenden Körper angeordnet ist im Verhältnis zu dem verbleibenden Abschnitt der äußeren Oberfläche des leitenden Körpers (208, 210), welcher mindestens einen Oberflächenabschnitt aufweist.

6. Düse nach einem der Ansprüche 1 bis 5, dadurch gekennzeichnet, dass mindestens einer der leitenden Körper (208, 210) einen Endabschnitt (220, 222) hat, der einem benachbarten anderen leitenden Körper zugewandt ist, und dass der Endabschnitt konvex zu dem benachbarten anderen leitenden Körper (208, 210) ist.

7. Düse nach einem der Ansprüche 1 bis 6, dadurch gekennzeichnet, dass mindestens ein leitender Körper (408, 410, 412, 414) ein elektrisch leitendes flüssiges Material aufweist, das in eine von dem isolierenden Material der Düse ausgebildete Kammer gefüllt ist.

8. Düse nach einem der Ansprüche 1 bis 7, dadurch gekennzeichnet, dass die Düse (302) mindestens eine Kammer (314) aufweist, die von dem isolierenden Material (304) der Düse ausgebildet ist, wobei die Kammer eine Wandfläche (316) hat, dass mindestens ein leitender Körper (310) mindestens eine elektrisch leitende Schicht (318) aufweist, und dass die Wandfläche die mindestens eine elektrisch leitende Schicht aufweist.

9. Düse nach einem der Ansprüche 1 bis 8, dadurch gekennzeichnet, dass die Düse mindestens zwei zweite elektrisch leitende Körper aufweist.

10. Ein Schalter für Mittel- und/oder Hochspannung, aufweisend mindestens zwei Lichtbogenkontaktstücke (102, 104), die relativ zueinander beweglich sind zu mindestens einer geschlossenen Position, in der die Lichtbogenkontaktstücke miteinander elektrisch verbunden sind, und zu mindestens einer offenen Position, in der die Lichtbogenkontaktstücke voneinander getrennt sind und einen elektrisch isolierenden Spalt (106) zwischen einander bilden, und eine Düse (202, 302, 402), die angepasst ist, elektrisch isolierendes Gas zu dem isolierenden Spalt zu führen zum Verhindern einer Lichtbogenbildung zwischen den Lichtbogenkontaktstücken, wenn diese getrennt oder verbunden werden, dadurch gekennzeichnet, dass die Düse (202; 302; 402) die Merkmale aufweist, die in einem der Ansprüche 1 bis 9 genannt sind.

11. Schalter nach Anspruch 10, dadurch gekennzeichnet, dass die Düse (202; 302; 402) mit einem beweglichen ersten Lichtbogenkontaktstück (102) der Lichtbogenkontaktstücke physisch verbunden ist, und dass die Düse angepasst ist, um sich gemeinsam mit dem ersten Lichtbogenkontaktstück in Bezug auf das andere Lichtbogenkontaktstück (104) zu bewegen.

12. Schalter nach Anspruch 10 oder 11, dadurch gekennzeichnet, dass der Schalter mindestens zwei Nennstromkontaktstücke (108, 110) aufweist, welche im Verhältnis zueinander beweglich sind zu mindestens einer geschlossenen Position, in der die Nennstromkontaktstücke miteinander elektrisch verbunden sind, und zu mindestens einer offenen Position, in der die Nennstromkontaktstücke voneinander getrennt sind, und dass die leitenden Körper von den mindestens zwei Nennstromkontaktstücken isoliert sind.

13. Schalter nach einem der Ansprüche 10 bis 12, dadurch gekennzeichnet, dass der Schalter ein Gehäuse (114) aufweist, das die Kontaktstücke und die Düse aufnimmt, dass das Gehäuse den isolierenden Spalt (106) von einer Atmosphäre außerhalb des Gehäuses (114) trennt, und dass das Gehäuse mit dem isolierenden Gas gefüllt ist.

14. Schalter nach Anspruch 13, dadurch gekennzeichnet, dass das isolierende Gas CO₂ aufweist.

Revendications

1. Buse(202; 302; 402) pour un disjoncteur moyenne et/ou haute tension, le disjoncteur comprenant au moins deux éléments de contact d'arc (102, 104) mobiles l'un par rapport à l'autre vers au moins une position fermée où les éléments de contact d'arc sont connectés électriquement ensemble, et vers au moins une position ouverte où les éléments de contact d'arc (102, 104) sont déconnectés l'un de l'autre et forment un espace électriquement isolant (106) entre elles, la buse étant faite partiellement d'un matériau électriquement isolant (204; 304; 404) et étant adaptée pour guider électriquement du gaz isolant vers l'espace isolant (106), pour empêcher la formation d'un arc entre les éléments de contact d'arc lors de leur séparation ou de leur connexion, la buse comprend une partie de buse (206; 306; 406) adaptée pour être positionnée dans la région de l'espace électriquement isolant, et la buse comprend un premier corps électriquement conducteur (208; 308; 408) et au moins un second corps électriquement conducteur (210; 310, 312; 410, 412, 414) qui est au moins en partie entouré par le matériau isolant de la buse et isolé électriquement des éléments de contact d'arc, l'au moins un second corps électriquement conducteur étant espacé du premier corps électriquement conducteur d'une certaine distance, et les corps conducteurs sont adaptés pour former un couplage capacitif entre eux, pour une commande du champ électrique dans l'espace isolant, et au moins l'un des corps conducteurs est isolé électriquement de la terre, caractérisé en ce que le premier corps électriquement conducteur (208; 308; 408) est entouré entièrement par le matériau isolant de la buse et isolé électriquement des éléments de contact d'arc, en ce que chaque corps conducteur (208, 210) comprend une surface extérieure (212, 214) faisant face au matériau isolant (204) de la buse, et en ce qu'au moins une partie de surface (216, 218) de la surface extérieure d'au moins l'un des corps conducteurs (208, 210) comprend un matériau à gradient de champ non linéaire.

2. Buse selon la revendication 1, caractérisée en ce que l'au moins un second corps électriquement conducteur (210; 310, 312; 410, 412, 414) est entièrement entouré par le matériau isolant (204; 304; 404) de la buse.

3. Buse selon la revendication 1 ou 2, caractérisée en ce qu'à la fois le premier corps électriquement conducteur et l'au moins un second corps électriquement conducteur sont isolés électriquement de la terre.

4. Buse selon l'une quelconque des revendications 1 à 3, caractérisée en ce que l'au moins une partie de surface (216, 218) d'au moins un des corps conducteurs fait face à un autre corps conducteur adjacent.

5. Buse selon les revendications 3 ou 4, caractérisée en ce que l'au moins une partie de surface (216, 218) de l'au moins un des corps conducteurs (208, 210) est situé à une distance plus courte d'un autre corps conducteur adjacent en relation à la partie restante de la surface extérieure du corps conducteur (208, 210) comprenant l'au moins une partie de surface.

6. Buse selon l'une quelconque des revendications 1 à 5, caractérisée en ce qu'au moins un des corps conducteurs (208, 210) a une partie terminale (220, 222) faisant face à un autre corps conducteur, et en ce que la partie terminale est convexe vers l'autre corps conducteur (208, 210) adjacent.

7. Buse selon l'une quelconque des revendications 1 à 6, caractérisée en ce qu'au moins corps conducteur (408, 410, 412, 414) comprend un matériau liquide électriquement conducteur versé dans un compartiment formé par le matériau isolant de la buse.

8. Buse selon l'une quelconque des revendications 1 à 7, caractérisée en ce que la buse (302) comprend au moins un compartiment (314) formé par le matériau isolant (304) de la buse, le compartiment ayant une surface de paroi (316), en ce qu'au moins un corps conducteur (310) comprend au moins une couche électriquement conductrice (318), et en ce que la surface de paroi comprend l'au moins une couche électriquement conductrice.

9. Buse selon l'une quelconque des revendications 1 à 8, caractérisée en ce que la buse comprend au moins deux seconds corps électriquement conducteurs.

10. Disjoncteur pour moyenne et/ou haute tension, comprenant au moins deux éléments de contact d'arc (102, 104) mobiles l'un par rapport à l'autre vers au moins une position fermée où les éléments de contact d'arc sont connectés électriquement ensemble, et vers au moins une position ouverte où les éléments de contact d'arc sont déconnectés l'un de l'autre et forment un espace électriquement isolant (106) entre eux, et une buse (202; 302; 402) adaptée pour guider électriquement du gaz isolant vers l'espace isolant, pour empêcher la formation d'arc entre les éléments de contact d'arc lors de leur séparation ou de leur connexion, caractérisé en ce que la buse (202; 302; 402) comprend les équipements mentionnés dans l'une quelconque des revendications 1 à 9.

11. Disjoncteur selon la revendication 10, caractérisé en ce que la buse (202; 302; 402) est connectée physiquement à un premier élément de contact d'arc mobile (102) des éléments de contact d'arc, et en ce que la buse est adaptée pour se déplacer conjointement avec le premier élément de contact d'arc en relation à l'autre élément de contact d'arc (104).

12. Disjoncteur selon la revendication 10 ou 11, caractérisé en ce que le disjoncteur comprend au moins deux éléments de contact à courant nominal (108, 110) mobiles en relation l'un par rapport à l'autre vers au moins une position fermée où les éléments de contact à courant nominal sont connectés électriquement ensemble, et vers au moins une position ouverte où les éléments de contact à courant nominal sont séparés, et en ce que des corps conducteurs sont isolés des aux moins deux éléments de contact à courant nominal.

13. Disjoncteur selon l'une quelconque des revendications 10 à 12, caractérisé en ce que le disjoncteur comprend un boîtier (114) qui loge les éléments de contact et la buse, en ce que le boîtier sépare l'espace isolant (106) d'une atmosphère à l'extérieur du boîtier (114), et en ce que le boîtier est rempli avec le gaz isolant.

14. Disjoncteur selon la revendication 13, caractérisé en ce que le gaz isolant est composé de CO₂.

Drawing