The present invention belongs to electricity, namely to basic electric components, in particular to protective components, in which the electric current is flowing through a part of a meltable material and is due to electric overloading interrupted by melting of said material, wherein the invention particularly refers to constructional details of high-voltage fuses and consequently pursuant to the International patent classification belongs to class H 01 H 085/042.

The invention is rest on a problem, how to modify an electric fuse, which generally comprises a melting member, which extends throughout a ceramic electrically insulating cylindrical casing, which is on each terminal portion thereof sealed and closed by means of an electrically conductive cover, to which said melting member is electrically connected, so that just by means of simple and cheap measures it could be assured, that despite to unchanged overall dimensions such fuse could be applied also in electric circuits, which could operate at much higher nominal voltage as a circuit protected by common prior art fuses, wherein however in the case of an electric overload such modified fuse would still have to be capable to interrupt the electric circuit extending there-through, by which also each potential mechanical damage or even destruction of said ceramic insulating casing would have to be avoided, which might otherwise lead to expansion of potentially generated arc from the interior of the casing towards the exterior of the fuse. Electric fuses with melting members, to which also the present invention refers, are commonly used in the field of protection of high-voltage electric circuits, and during the recent time period in particular in direct current circuits in photovoltaic power plants or similar high-voltage systems, in which the voltage usually reaches around 1.500 V, and the electric current value us around 25 A or sometimes even 30 A. Suitable fuses ere embedded in suitable carriers and must generally be replaceable, so that also dimensions thereof must be pre-defined. By limitation of dimensions also a condition is set, which type of fuse should be used in certain nominal voltage and current. This is however depending not only on material, resistance and squaring of its cross-section, but also on processes which occur by melting of said melting member. During interruption of the melting member the last is heated up to the melting temperature thereof, upon which at least one section thereof becomes molten and interrupted. Gasses are also generated in such processes, so that also the pressure within the fuse may essentially increase. In particular in direct current circuits it commonly happens that electric arc starts burning between both interrupted sections of the melting member, which may still further complicate the situation. Situation becomes extremely critical, if the fuse casing is broken or even crushed by explosion, since then the arch may freely access the surrounding, which may initiate a huge fire. Although the interior of the casing is normally filled with fireproof granulated material, the last is spread and lost, as soon as the casing is broken, and therefore cannot contribute in extinguishing of the arc anymore. The electrically insulating fuse casing is usually made of ceramics, which is fragile and may be by sufficiently increasing of pressure within the fuse at once totally crushed by explosion. Known are however also the fuses, by which said scenario should be eventually eliminated by using a casing, which consists of a composite material or a duroplastic electrically insulating material. In such cases there is another problem, which may occur, and is connected with overheating and carbonization of such material at least on the inner surface of the fuse casing due to burning of said electric arc. Such carbonized surface of the material, which has been initially electrically non-conductive, gradually becomes electrically conductive, which means that the fuse despite to interruption of the melting member may still conduct the electric current, and the overloaded electric circuit despite to the presence of the fuse still remains uninterrupted.

Electric fuse, which is disclosed in CN203398066 U, comprises a cylindrical tubular casing, which consists of an electric insulating material and is on each of its terminal portions sealed and closed with a cover, which consists of an electrically conductive material and is intended for integration of a fuse into each disposable electric circuit. An uninterrupted melting member is inserted through the passage within said fuse between said covers and is on each of its terminal portions electrically connected with each belonging cover. The melting member as such is either a wire or a band consisting of electrically conductive material having pre-determined electric resistance and melting temperature, and moreover, said melting member is furnished with weak areas, which are precisely manufactured and in which the member should be actually molten within a relatively small area and under well-defined conditions. Consequently, the distance between both two residual parts after melting of said melting member is relatively small, which may essentially contribute to formation and burning of the electric arc there-between. To this aim, the melting member is within said casing surrounded by granulated fireproof material, e.g. with silica sand, which should prevent formation and expansion of the electric arc upon interruption of the melting member.

In this case the electrically conductive covers are each per se on each belonging terminal portion of the fuse casing pressed on the external surface of the fuse cover and are therefore secured against removal exclusively by friction between the external surface of the fuse cover and the internal surface of the cover, which is rest thereon. Such approach is therefore applicable only in such electric circuits, in which any electric overload should not be such extensive that by interrupting of the melting member or burning the arc inside of the fuse the pressure could increase to such extent that the casing would broke or explode, or that anyone of said covers could be removed from the casing, namely, in such situation such damage of the fuse could be extremely dangerous for the surrounding of the fuse either due to explosion or due to burning arc.

Probably by taking into consideration all previously mentioned risks another electric fuse has been proposed, which is disclosed in CN 204289315 U and which also comprises a cylindrical tubular casing, which is made of an electrically insulating material and through which a melting member extends, which is by each of its terminal portion electrically connected with each belonging cover, which is however in this case screwed onto each corresponding terminal portion of the fuse casing. Thus, by screwing said cover instead of simply pressing it onto the fuse casing, is apparently achieved that the connection between the cover and the external surface of the fuse casing is capable to withstand much higher increasing of the pressure inside of the fuse. As a consequence, by increasing the pressure within the fuse the cover remains attached to the casing, but the generated gasses also remain jammed within the fuse casing without any possibility of gradually releasing them, which by sufficiently increased pressure then results in explosion of the fuse casing as such.

By taking into account all discussed circumstances the prior art fuses are within each pre-determined dimensions exposed to strict limitations in view of allowable nominal voltage and current values, and therefore cannot be further tuned for the purposes of application in electric circuits with some higher technical performances in view of the fuse capability.

The present invention refers to an electric fuse with a melting member, wherein such fuse comprises a cylindrical tubular casing, which consists of an electrically insulating material and through which a melting member consisting of an electrically conductive material having a pre-determined electric resistance and a pre-determined melting temperature is inserted, wherein said casing is on each terminal area thereof closed and sealed by means of an axially apart from said casing protruding cartridge-like cover, which is closed on its one terminal area and consists of an electrically conductive material and is electrically connected with said melting member, and wherein the interior of said casing is filled with a suitable quantity of granulated fireproof and electrically insulating material, by which said melting member is surrounded.

The invention provides that on each terminal area of the fuse casing, namely between said casing and said cover, a separating barrier is inserted, which consists of an electrically conductive and plastically deformable material and on which on that side, which is faced towards the interior of the fuse casing, a layer consisting of an elastic and electrically insulating material is available and is connected therewith in a non-detachable manner, so that the melting member is on each terminal portion of said fuse electrically connected with each belonging electrically conducting cover via said electrically conductive separating barrier and simultaneously extends also through said electrically insulating layer of elastic material, such that in the area within said layer it is furnished with at least one bending or meander, by means of which it is anchored therein and secured against being pulled-out. An a preferred embodiment of the invention said elastic electrically insulating layer consists of silicone, namely of such silicone, which is at least during a certain time period resistant against increased temperature, while that area on the melting member, which is located outside of said layer and within the interior of the fuse casing, is surrounded by granulated material, which is silica sand.

The invention will be disclosed in more detail on the basis of an embodiment, which is presented in the attached drawings, in which

Fig. 1 is a high-voltage electric fuse according to the invented, schematically presented as a partial cross-section along its diametrical longitudinal plane and during its regular exploitation; and Fig. 2 is a high-voltage electric fuse according to Fig. 1 after interruption of the melting member due to electric overload, also as a partial cross-section along its diametrical longitudinal plane.

Just one of both terminal areas of the electric fuse is presented in Fig. 1, wherein said fuse comprises a cylindrical tubular casing 1 , which consists of an electrically insulating material and through which a melting member 2 consisting of an electrically conductive material having a pre-determined electric resistance and a pre-determined melting temperature is inserted. Although said casing 1 is just partially shown in Figs. 1 and 2, it is on each terminal area 11 thereof closed and sealed by means of an axially apart from said casing 1 protruding cartridge-like cover 3, which is closed on its one terminal area and consists of an electrically conductive material. Such formed covers 3 together with the previously disclosed shape of the casing 1 as such in view of it shape and dimensions together form an overall concept of a high-voltage fuse, which is as such well-known to those skilled in the art and is widely used in daily practice. As a consequence, by means of said covers 3 the fuse can be integrated into each disposable electric circuit. A melting member 2, which is inserted through the passage within said casing 1, is electrically connected with each of said covers 3. The interior of said casing 1 is filled with a suitable quantity of granulated fireproof and electrically insulating material 10, by which said melting member 2 is surrounded, and which in the shown embodiment represents silica sand.

The invention however provides that on each terminal area 11 of the fuse casing 1 , namely between said casing 1 and said cover 3, a separating barrier 4 is inserted, which consists of an electrically conductive and plastically deformable material, wherein on that side thereof, which is faced towards the interior of the fuse casing 1, a layer 5 is foreseen, which consists of an elastic and electrically insulating material, in this particular embodiment of silicone, and is connected in a non- detachable manner to said barrier 4.

The melting member 2 is on each terminal portion of said fuse electrically connected with each belonging electrically conducting cover 3 via said electrically conductive separating barrier 4 and simultaneously extends also through said electrically insulating layer 5 of elastic material. In this, in the area within said layer 5 the melting member 2 is properly bent or is formed as a meander 21, by which it is anchored within the interior of the layer 5 and secured against being pulled-out.

In Fig. 1 the fuse is presented during its regular use, when the melting member 2 is uninterrupted, so that each electric current can flow between both covers 3 along the melting member 2 and also through both belonging separating barriers 4.

As soon as an electric overload occurs through the fuse due to excessive current through covers 2, separating barriers 4 and the melting member 2, the melting member 2 is heated and then overheated, so that at least one section thereof is molten, which leads to interruption of the melting member 2. Since the casing 1 is closed and sealed on both sides by means of said covers 3 and also by means of said separating barriers 4, increasing of temperature and generating of gasses within its interior leads to increasing of pressure therein. Increasing of pressure leads to an essential deformation i.e. bowing of both separating barriers 4 and consequently also the layers 5, which are firmly attached thereto, apart of each other i.e. in a direction outwardly with respect to the casing 1 as such.

Since each of the terminal portions of the melting member 2 is due to its bending area or a meander-like section jammed within the interior of each belonging layer 5, each part of such interrupted melting member 2 is during said bowing of the separating barriers 4 together with simultaneously displacing said layers oppositely apart from each other displaced away from the other part of the melting member 2, so that the distance between both parts of the interrupted melting member 2 is essentially increased, by which the probability of formation of an electric arc between them is essentially reduced.

Thanks to the concept according to the invention an essential portion of energy, which is released by interruption of the melting member 2, is used for bowing of said barriers 4 instead for generating excessive or even critical mechanical stresses in the contact area between each cover 3 and the casing 1 or within the wall of the casing 1, while at the same time also the gap between both parts of each interrupted melting member 2 is automatically extended, so that such extended gap is then also much easily filled by said granulated electrically insulating material 10, which is present within said casing 1, which no doubt also leads to reduction of probability of formation of an electric arc. Those skilled in the art will no doubt understand that such concept of a fuse, despite to unchanged dimensions thereof, allows integration of the fuse into an electric circuit, in which the electric loads and similar technical requirements are much higher than in a circuit, in which any of the fuses known from the prior art could be applied.