DE3239903A1 - Integral melting conductor for electrical fuses - Google Patents

Abstract

The invention relates to an integral melting conductor for electrical fuses having at least one deposit of effective material in a groove, and constriction points which reduce the cross-section. The aim of the invention is to create a melting conductor which has low energy losses, is resistant to ageing, has a fixed characteristic and can be produced in a technologically advantageous manner. A melting conductor has been developed which melts through quickly at temperatures which are only slightly above the melting point of the effective material, as a result of the deliberate generation of flows in the fluid effective material and the utilisation of precipitation processes, and interrupts the current flow in that a local region of the carrier material web which is half covered with effective material is dissolved at right angles to the surface and simultaneously over the entire width of the web. Such melting conductors are used especially in low-voltage and high-power fuses. <IMAGE>

Description

Title of the invention One-piece fusible link for electrical fuses Field of application of the invention The invention relates to a one-piece fusible conductor for electrical fuses with at least one active substance depot in a channel and reduced cross-section constrictions.

Such fusible conductors are used in particular in low-voltage high-performance fuses used.

Characteristic of the known technical solutions by the DE-OS 2927660 a fusible conductor is known which has a soft solder application and a reduced cross-section Bottlenecks of different recess widths have a certain shutdown characteristic and low aging should be achieved by applying the active ingredient directly to a bottleneck is applied and the temperature maximum through additional cross-sectional ceremonies is placed in the drug-carrying site.

This fusible link has the disadvantage that the melting point required temperature due to unfavorably chosen resolution conditions far is above the melting point of the active ingredient.

This high warming sets the aging resistance harah and leads too great energy losses, since even at rated current there is already a high operating temperature is achieved.

From DE-PS 2428569 fusible conductors are known that at least have arranged an accumulation of active substances in front of the current-carrying constriction and only part of the active ingredient is in high temperature zones.

The disadvantage here is that the active ingredient in the case of dissolution of the Accumulation of active ingredients to the reaction site on the bottleneck is measured, especially after a long period of operation due to the reduced wettability of the carrier material is made more difficult. Another disadvantage is that the current-carrying Cross-section from the active ingredient center radially outwards, parallel to the surface is dissolved, whereby the ratio of the area of attack of the active substance to the one to be dissolved Volume of the carrier material necessary for the interruption is very small and the The melting process is delayed as a result.

At the same time, the flow of the active ingredient causes the reaction point towards a cooling of the same, whereby the melting process is additionally prolonged will.

In US PS 4227167 is finally. a fuse link described, in which the application of the active substance directly to the one intended for the shutdown Adjacent bottleneck. The disadvantage of this variant is that d'.er active ingredient is not in z. Ra of a gutter is geometrically fixed, which is an undefined flow and thus on the one hand strongly controlling melting characteristics and on the other hand leads to active ingredient cross-sections which are very unfavorable for the resolution process.

It should also be noted that the position of the active ingredient on ' the fusible conductor was not chosen so that the temperature distribution the melting process optimally favored, after all, can for the entire evaluated patent literature it can be established that the influence of external forces (3rd

Gravity, centrifugal force) on the dissolution process through conveyance or obstruction of flows within the active ingredient not recognized. will and that especially with fusible conductors with only one side of the temperature maximum the The solder depot located at the reaction point significantly reduces the melting characteristic the installation position depends on the object of the invention. The object of the invention is in it, a low-loss, aging and can line-resistant as well as technological to create advantageously manufacturable fusible conductors.

Laying down the essence of the invention The object of the invention is to provide a To create fusible conductors, which as quickly as possible at temperatures, aie only a little lie above the melting point of the active ingredient, melts and the current flow. interrupts. To do this, the current-carrying cross-sections of all constrictions must be in a row of constrictions perpendicular to their surface and very locally on the narrow spots. With this local resolution it is achieved that only a very small volume of carrier material must be dissolved in relation to the amount of active ingredient.

By applying part of the active ingredient to half of each the narrow spots of a row of narrow spots facing the plumb line, which in turn is arranged perpendicular to the direction of flow, it is achieved that the active ingredient is constantly located directly on the reaction point, this reaction point itself but in the edge area of the drug depot and on the steles of the corresponding Narrow row is and the active ingredient also after melting its shape and.

Maintains position, d. H. there is no rear transport to the reaction point necessary, a cooling effect of the active ingredient does not occur and. the fluidic favorable arrangement of the active ingredient is retained.

The saturation determines the speed of the shutdown process of the active ingredient with dissolved carrier material.

By suitable arrangement of the fusible conductor in an external force field (Gravity, centrifugal force, etc.) flows are favored, which in connection with the colder part of the drug supply there led to excretions, so that the The active substance flowing back to the reaction point constantly maintains its dissolving power.

According to the invention the object is achieved; that according to FIG. 1a and 1b the active substance 3 spreads in at least one direction across the carrier material 1 running channel with aerodynamically favorable shape and size, their ratio of middle width b eu depth t is located at t, and the groove on the fusible link so. is to be arranged that each half the area of all narrow spots 2 of a row of narrow spots protrude into the drug channel so that the drug is in the vicinity of the reaction site a sufficiently large flow cross section 4 is guaranteed. According to Fig. 11c, f becomes the side of the narrow row is selected, in the case of the inL operating case of the fuse the Temperature decreases away from the row of narrow points and with it the larger part of the active ingredient depot is at lower temperatures than the reaction point 5.

This temperature difference should advantageously be as large as possible be designed. The fusible link is when only one active substance is used according to the invention to be arranged so that the focus of the active ingredient of the Row of narrow spots half covered with active ingredient, viewed always in the direction of force (e.g. F1 vertical installation, F 2 horizontal installation of the fuse element when using gravity). If, on the other hand, there are several drug depots on the Carrier material arranged, it must be ensured that all drug depots the The above requirements are equally sufficient.

As an active ingredient. advantageously one with the carrier material reactive solder with a low melting range, especially pure metal or eutectic mixture used who the.

Exemplary embodiment The invention is intended to be based on an exemplary embodiment and the associated drawings are explained in more detail in Fig. 1 and in Fig. Fusible conductor shown in FIG. 2 consists of a strip-shaped carrier material 1 an electrically conductive material z. Bo silver, copper or combinations corresponding materials) of the several rack rows 6, 7 and at least one Active ingredient depot has. The active ingredient is in a gutter whose ratio from each other channel already b to channel depth t (s.

Fig. 1b) is at a.

At least one row of narrow points 6 protrudes so far into an active ingredient depot 3 into it, that åed.e individual narrowness of this row of narrows is up to halfway is covered with active ingredient, so that at the same time in the vicinity of the reaction site sufficient flow cross section 4 is guaranteed. There is that Active substance depot on the side of the narrow row 6, the one on the fusible wire ends related, has the lower electrical resistance.

Advantageously, narrow rows with different electrical resistance auL the fusible conductor arranged so that the narrow rows with. lower electrical resistance 7 further out than the narrow rows are arranged with a higher electrical resistance. The different resistance contributions the narrow point rows 6 and 7 are realized by different narrow point shapes, the current-carrying cross-section at the narrowest point of the respective constriction but is the same size. The distance a indicated in FIGS. 2 and 3 can optionally be chosen equal to zero, so that the fusible link has both an even number and can also have an odd number of narrow rows. The positioning the fuse in the fuse shown in Fig. 2 must be done in such a way that that when operating the fuse, the center of gravity. of the active substance of the half Row of narrow spots covered with active ingredient from seen always in the direction of force (e.g. when using gravity: F1 vertical installation, F2 horizontal installation) is located.

If two drug depots are arranged on the fusible link, on To make it largely independent of the installation position, this must be done through their arrangement 3 ensures that the individual active substance channels are in size and location to each half! row of narrow spots coated with active substance match so that that in each case one of them the conditions for the shutdown mechanism to be shown below optimally fulfilled.

In the event of the fuse being triggered, the active substance is activated by the resistance contributions the constrictions in the liquid state.

transferred, whereby by the arrangement of the active ingredient on the fusible link and d.the developing temperature distribution as a result of the arrangement and shape of the Twisting the greater part of the active ingredient to a lower temperature than constricting d.the active ingredient part that is located at the reaction site. That. target of the invention. promoted thereby. that the different resistance contributions of the various rows of embankments increase this temperature difference even further.

A flow process occurs under the action of the external force 8 (Fig. 1av within the active ingredient it, whereby as a result of the flow against the carrier material Forming turbulence at the reaction point 5, which facilitates particularly good evacuation of the dissolved carrier material and thus a much faster dissolution at the locally very limited reaction site than at others covered with active ingredient Place the carrier material takes place. This local, rapid dissolution of the carrier material is favored by the fact that the active ingredient rich in carrier material through colder active ingredient zones flows and the carrier material is deposited there. The further to the The active substance flowing back into the reaction point always has a high dissolving power and its responsiveness is thereby maintained. The inventive Fusible link enforces these optimal flow conditions and thus achieves the required Melting times at very low temperatures, i.e. at temperatures that are only lie little above the melting point of the active ingredient.

The active ingredient remains in the case of electrical currents down to a small test current on the other hand solid and there is no reaction between the active ingredient and the carrier material, Currents are still developing in the active ingredient resistant to aging. At the same time, these low temperatures also played a role low-energy work of the safety List of reference symbols 1 - carrier material 2 - frame 3 - active ingredient depot 4 - flow cross section 5 - Reaction points 6 - Narrow point row with high electrical resistance 7 - Narrow point row with lower electrical resistance 8 - flow process F1 - direction of force with vertical installation F2 - direction of force with horizontal installation a - narrow point row spacing b - mean width of the channel t - depth of the channel L e r s e i t e

Claims (4)

Invention claim 1. One-piece fusible conductor for electrical Fuses in the form of a metal band with reduced cross-section bottlenecks, at least one active substance depot in a channel and one active substance with little Melting interval, preferably pure metal or entectic mixture, characterized in that that the active substance depost 3 has such a shape and size. That internal currents 8 b favor the narrow spots of a row of narrow spots up to halfway into the Active substance depot protrude that in the active substance in the vicinity of the reaction point 5 a enough; large flow cross section 4 is guaranteed and the active ingredient depot is located on the side of the narrow row 6, which is based on the fusible wire ends has the smaller electrical resistance, whereby the positioning of the fuse element in the backup like this. has to be done that the focus of the active substance is in front the narrow point half covered with active ingredient, viewed in the direction of force (e.g. Schwerkradt, centrifugal force) is located. 2. One-piece fusible link for electrical fuses according to point 1 characterized in that the ratio of each other channel width to channel depth is 1, but the absolute width is at least so large that the flow processes not significantly impaired in the liquid active ingredient. but at most is so large that the liquid active ingredient flows away from the. Active ingredient depot Avoid exposure to external forces (e.g. gravity, centrifugal force, impacts) will. 3. One-piece fusible link for electrical fuses according to point 1 and 2 characterized in that the shutdown process is favored by that recesses with different geometries are arranged in such a way; are that current-carrying Narrow rows are created, the smallest cross-sections of which are the same size, but the effective resistance. at room temperature of the current-carrying narrow frame rows like that. is different> that the. Narrowing with less electrical Resistance are arranged further outside on the fusible link than the narrow points with greater electrical resistance. 4. One-piece fusible link for electrical fuses according to point 1, 2 and 3, characterized in that at least two drug depots accordingly Fig. 3 are arranged on the fusible conductor. That the individual active substance channels in shape, size and position in relation to the row of narrow spots each half covered with active ingredient match and opposite to the longitudinal axis of the fusible conductor are shaped. -There are 2 pages of drawings-