DE3243892A1 - Melting lamina for electrical fuses - Google Patents

Description

Melting lamella for electrical fuses

The invention creates electrical fuse links a melting lamella, the special geometric design of which enables the interruption of a power line in the event of an overcurrent or short circuit under the influence not only of the usually used heat f ect, but the mechanical tensioning effect that occurs at the same time takes place.

The known mechanism of action of the fuses exists in that in a section of the current path in series a fuse is arranged, which the The thermal effect of a certain nominal current can still be tolerated, but with a heat development that corresponds to the nominal current value exceeds what belongs, the line is interrupted by melting. This basic mechanism of action is a common feature of all - incidentally, variously designed - contemporary fuse types. Both the critical parameters (threshold values) and the shape (geometry) of the fusible thread are also shown in different areas of application - according to the differing requirements - selected differently. The fuse types can be grouped according to various properties, including: even after the basic Interruption criterion. There are types of backups in which the interruption must always occur when the Current is only slightly above the nominal value Exceeds threshold value, i.e. in any case if overcurrent occurs at all; this is the case e.g. with types with the so-called gl characteristic. Other types - e.g. those that correspond to the so-called aM characteristic

speak - should endure a sudden overload can and only melt when a clear short circuit occurs.

In any case, the interruption is the case with all known types - be it as a result of a short-circuit current or because of an overcurrent exceeds a current threshold value for a longer period of time than the prescribed time threshold value allows - take place in that the worn overcurrent generated amount of heat causes the melting of the melt filament.

The conditions for melting off should be able to be influenced by several independent variables. Therefore Different shapes for fusible conductors that differ from one another in terms of their geometry have also been developed. For one Safe handling of the criteria and the possibility of adapting to different operating circumstances are special the lamellar fusible link cheap; in the current path a lamella made of conductive material is inserted in series with a - within a tolerance range Thickness and nominal width (where the real Width in different sections by means of recesses represents a smaller cross-section compared to the product of the thickness and the nominal width). The strip-shaped The lamella is shaped so that the main flow path is parallel to the longitudinal axis of the lamella. In one or several sections lying in a plane perpendicular to the longitudinal axis, the cross-section of the lamella is reduced, so that an increased current density occurs in these sections as a result of the cross-sectional reduction and peak warming is to be expected. The recesses can be formed by punching on the edge of the lamella holes can be punched in the middle of the slats and these two possibilities can be used within of a section, whereby this combination can be the same for all sections, but also alternately different shapes in the sections following one another along the longitudinal axis of the lamella

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can arise. It is possible that only edge punchings are provided in one section and in the next only hole punching can be used, or alternately different combinations of the different recess types can be used be united. The melting should therefore take place at this cross-section with reductions or consequences and through the Shape of the recesses - d. H. rather by the shape of the means of the recesses between these formed current-conducting webs (i.w .: current bridges) - should both the Shape, as well as the direction of propagation of the resulting arc can be determined or at least influenced.

The shape and direction of the recesses can be chosen so that in the reduced cross-section sections resulting current bridges to the longitudinal axis of the melting lamella

- or to an axis parallel to this - are formed symmetrically; in this case the local one also runs Current path parallel to the main current path. Very often they will Recesses shaped so that the current bridge does not have an axis of symmetry that is parallel to the longitudinal axis of the fusible lamella has, but the current bridge

- has an axis of symmetry that is at an acute angle to the longitudinal axis (this axis of symmetry is also the perpendicular to the shortest straight connecting line to each other neighboring recesses in the middle of the connecting straight line of gravity of the river bridge), or

- is not at all axially symmetrical; also in

In this case the local current path runs along the center of gravity of the current bridge, where: i this center of gravity 1 in i π to the longitudinal axis both parallel, as; also lie at an acute angle can.

The choice of a peculiar shape is useful for g In j chwe ι r; e drr Influence of the reproductive direction of the light arch and the optimization of the heat distribution.

There are therefore fusible lamellas in which cross-section reductions are made in sections following one another along their longitudinal axis are made. In a gene according to the invention Enamel lamella it is also possible to adjust the proportion of the Cross-section reduction according to the course of the heat distribution in dor Schmel / 1amelIe to adapt: the cross-section of the this way shaped current bridges should be in the section, where the greatest warming is to be expected, be greater than in the sections where less warming is to be expected is. If one takes the plane through which the enamel lamella is perpendicular to its longitudinal axis in two halves of equal length is divided, i.e. the transverse median plane as the reference plane, then the melting sections on both sides of the transverse center plane are shaped so that their cross-section is in the direction of the The transverse median plane increases monotonically; he has in that of the Cross-sectional median plane at the most distant section the smallest and the largest value in the section closest to the transverse center plane (possibly in the transverse center plane). It can also be advantageous here be that the length of the cross-sectional reduced sections measured in the longitudinal axis of the lamella is in the same Direction monotonically decreased, and that this course is different from each other for the two lamellon halves, that is from one end of the lamella to the transverse center plane, the cross-sections are always larger than the cross-sections of the similarly spaced sections in the other half.

The invention is based in particular on the knowledge ^ O nis that the operating conditions for enamel lamellae are still can additionally be improved if a geometry is found, according to which the electrodynamic force effects of the current flowing in the current bridges do not balance each other, but a resulting electrodynamic Distorted force directed perpendicular to the main current path is; this resulting force is then sought be to move this section of the melting lamella and in the reduced cross-section can in the texture of the current

bridge, which, according to the higher temperature, is also a lower one Has strength, a break will occur before the melting has occurred completely.

This mode of action can be achieved according to the invention in that in the successive along the longitudinal axis Sections with reduced cross-section the resulting current bridges are shaped so that the median lines the current bridges at an acute angle to the longitudinal axis of the Melting lamella lie and in the successive sections the sense (the sign) of the angle alternately is opposite. If the cross-sections and / or the length of the current bridges in the one described above Way depending on their distance from the transverse median plane of the lamella are different, the tearing effect of the electrodynamic differential force can be increased by not only the sense of the acute angles alternately opposite but also the value (size) of the angle is not the same for all fused sections: the size the angle that the median line of the respective current bridge forms with the longitudinal axis of the melting lamella decreases with decreasing Distance of the respective melting section from the transverse center plane of the melting lamella (monotonous). The restriction "monotonous" is in brackets because such a restriction only makes sense if there are more than four Sections of reduced cross-section in the enamel lamella available. If there are only three sections in total, the angle in the middle section is larger than in the two Outer sections. If there are four sections in total, then

there are two sections - on both sides - of the transverse center plane closer to this than the other two (the outer sections) and the angle is larger in the closer sections than in the outer sections.

The invention is explained in more detail with reference to the drawing. From the figures of the drawing of the indungs.gcrnäßf ¹ melt lamella can be seen, in there a total of four melt sections with a reduced cross-section, nufsgßh i I d / »t

are; however, the information given is equally valid if only three or more than four melting sections are present. Fig. 1 shows recesses with circular arc-shaped outline sections, Fig. 2 those with angled outline. The figures show the first and second melting sections Kl and K2 with reduced cross-section successively from the upper lamella end Vf and the first and second melting sections Kl 'and K2' successively reduced in cross-section from the lower lamella end Va, and also the transverse center plane Sf and perpendicular to the longitudinal axis Ht of the lamella the recesses, whose edge points Pf and Pa lying in the longitudinal axis of the lamella limit the length of the respective reduced-cross-section sections Kl, ..., Kl '. In the sections Kl, ..., Kl 'the direction of the local current path is determined by the direction of the median lines Vs between the recesses, two of which in each section are incisions of the lamella edges, and one between them in the transverse center of the strip-shaped lamella as Punched out are formed, resulting current bridges determined. It can be seen that the median lines Vs of the current bridges of all sections Kl, ..., Kl 'run at an acute angle ¹ ^ i to the longitudinal axis Ht (i is 1 or 2 in the case shown; if there are more than four sections, i can be larger than be 2). The meaning of the angle ^ i is negative in the upper left half in the first section K1 and in the lower left half in the second section K2 ', i.e. the acute angle enclosed between the respective median line Vs and the longitudinal axis Ht opens in the sections K1 and K2 'towards the upper end of the lamella Vf, on the other hand, is positive in the upper left half in the second section K2 and in the lower left half in the first section Kl', ie the acute angle enclosed between the respective median line Vs and the longitudinal axis Ht opens into the Sections K2 and Kl 'towards the lower end of the lamellae Va. The direction of opening of the angles between the median lines of the current bridges in the right half of the lamella is opposite to that shown and described for the left half of the lamella. So the direction of the median lines Vs is

alternately opposite along the longitudinal axis Ht Sense. Also the value of a given angle ^ i is smaller, than the value of the following towards the transverse center plane Sf Angle ^ (i + 1). If four or more than four sections

c Kl, ..., Kl 'are present, this condition can be formulated in this way that in the order of the transverse center plane Sf towards the value of the angle ^ i increases monotonically.

In a preferred embodiment, it also increases in size

2Q of the electrically conductive narrowest cross-sections of the melting sections Kl, ..., Kl ', each measured perpendicular to their median line Us, with a decreasing distance between the sections from the transverse center plane Sf increases (monotonically) and, furthermore, the length of the sections of reduced cross-section preferably increases Kl, ..., Kl 'each measured between their edge points Pf and Pa, with a decreasing distance from the transverse center plane Sf (monotonous). In an advantageous embodiment are in addition, the cross-sections of the current bridges in the corresponding order, measured from the transverse center plane Sf Sections e.g. in the lamella half lying between the upper end Vf and the transverse center plane Sf larger than in the other, in this example in the between the lower end Va and the transverse center plane Sf lying lamella half.

In the manner shown in the drawing are in accordance with 1 shows the recesses from intersecting circular arc recesses, and according to FIG. 2 from triangular recesses formed, of which those located in the middle of the lamellae Triangles of the respective section intersect.

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Claims (1)

VIERING & JENTSCHURA admitted to the European Patent Office European Patent Attorneys - Mandataires en Brevets Europeens DipWng. Hans-Martin Viering · Dipl.-Ing. Rolf Jentschura · Steinsdorfstrasse 6 · D-8000 Munich 22 Attorney File 4189 Villamosberendezes es Elektronikai V / allalat Budapest / Hungary MELTING BLADE FOR ELECTRICAL FUSES EXPECTATIONS Melting lamella for electrical fuses for use in an arrangement where the main current path is parallel to the longitudinal axis of the enamel lamella, in which more than two cross-section reduced melt sections available are, in which the current-conducting webs (current bridges) left between recesses are shaped so that their Median lines are employed at an acute angle to the longitudinal axis of the melting lamella, characterized in that the respective acute angle ('fi) between the longitudinal axis (Ht) the fusible lamella and the respective median lines (Vs) of the current bridges each of a reduced cross-section tapered section (Kl, ..., Kl ') in the order of the sections (Kl, ..., Kl ') alternately opposite each other 293413 and 293414 ■ Fax (089) 222066 · Telex 5212306 jepa d · Telegram Steinpat Munich BATH ι sense, so in each case to a positive angle (^ i) of one section (Ki) is a negative angle (-0> (i + l)) in the following section (K (i + l)), resp. to a negative angle (-Φι) in one section ρ- (Ki) a positive angle (^ P (i + 1)) in the following Section (K (i + U) follows, where i is the ordinal number of the respective section within the order of Sections means. , Q 2. Melting lamella according to claim 1, characterized in that that the respective size of the angle (Φι) between the Longitudinal axis (Ht) of the melting lamella and the respective median lines (Vs) of the current bridges in the respective section (Ki, i = 1,2, ...) with decreasing distance of the sections in the sequence from the transverse center plane (Sf) of the lamella (monotonically) increases. 3. Melting lamella according to claim 1 or 2, characterized in that that with decreasing distance of the sections from the transverse center plane (Sf) of the lamella the narrowest Cross section of the current bridges of the respective section (Ki) (monotonically) increases and preferably the length of the Sections (Ki) (monotonically) decreases.