DE3725907A1 - FUSE PROTECTION - Google Patents

Abstract

The invention relates to a fuse link for disconnecting an overcurrent in an electrical conductor. The hermetically sealed housing is filled with hydrogen which cools the fuse link in the event of slight overcurrents somewhat better than air, but considerably improves the cooling in the event of the fuse link melting with an arc being formed, and thus contributes to the arc being extinguished. The hydrogen filling allows the use of previously unused materials for the fuse link, specifically metals and the like which have low melting points and tend to oxidise, which have a relatively high electrical resistance. The thickness of the fuse conductor thus increases, so that the handling capability during production is improved. In addition, greater inertia in the response characteristic can be achieved.

Description

The invention relates to a fuse for switching off of an overcurrent in an electrical conductor coming from there is a housing and two contact bushings which a fuse element attached to the inside of the housing is.

Such fuses have long been known and are available in a wide variety of designs on the market offered. At such fuses, the under different requirements. In addition to a high Switching capacity becomes certain switch-off characteristics desired, in addition, a corresponding enamel be aging-resistant, even after a lot long operating time the original character Statistics on switching off.  

Especially for reasons of high aging resistance Precious metals are used as fusible conductors, in particular the silver that is often alloyed or in the vicinity Alloy components are kept available in the case the response of the fuse is the one that melts temperature-reducing alloy and thus an even faster one Result in responses. The alloying elements must however, often separated from the actual fuse element so that not an uncontrolled, very slow Alloy formation occurs, which in turn is comparable with aging.

With particularly small currents to be protected, the Fusible conductor extremely because of their very good conductivity be made thin so that they are particularly difficult are to be handled. In addition to expensive machines for processing the fuse element into a manageable form, for example by winding on a fiberglass core and the The committee rates are relatively high, so that relatively expensive to protect particularly small currents Fuses must be used.

It is an object of the invention to provide a fuse for the improve the type mentioned so that the sensitivity sensitivity to aging is greatly reduced and as a result the possible selection of materials that can be used the difficulties mentioned for the fuse element manufacturing can be avoided.

To achieve this object, the invention proposes that the housing is gas-tight and ge with hydrogen is filling.

Hydrogen behaves essentially towards metals neutral when talking about embrittlement of certain brass grades and high-alloy steels. By doing the context of interest here depends on the fact that the hydrogen with the metallic fuse element is none  Connection comes in and also no alloy formation promotes. It can therefore be used as a fuse be considered as a protective gas. That opens up the possibility ability to use fusible conductors that were previously used because of their Oxidation tendency and therefore because of their low aging resistance not suitable for fuses were.

The hydrogen has in relation to the ambient air which is in usually the housings of conventional fuses fills the property that the thermal conductivity is approximately is identical in a temperature range that the work temperature range of the fuse corresponds. These However, thermal conductivity increases extremely Temperature range of about 4000 ° C, i.e. in the range of Arc temperatures. This advantage can be for one Fuse can be used in the following way:

The greatly increased thermal conductivity in the range of Arc temperatures lead to a good extinguishing effect, which is equivalent to the switching reliability is particularly high, even with extreme electricity loads a safe shutdown is guaranteed. There with the molecular hydrogen present parts as a cooling and extinguishing medium, the other, previously be do not have to use used soldering chips.

A certain disadvantage of a hydrogen filling in one Fuse protection is that the hydrogen molecules are extremely small and therefore the escape of hydrogen must be mastered due to diffusion. For this Basically, metal housings are advantageous because they are hermetic are tightly welded and in which the contact leadership is effected with the help of glass, for example as the bottom of a bowl-like structure or as a tube like structures in a metallic floor. Furthermore can be ceramic bodies, especially ceramic tubes be set, the ends of which are metallized, so that  a metal plate or cap at these points can be soldered hard. In this way arise sufficient gas-tight housing that the hydrogen filling sufficient for a period of more than 10 years Maintain concentration. Even if a small amount of hydrogen would diffuse out of the housing, it does not mean that e.g. oxygen or nitrogen enters the housing. Because of the ge named molecular size exist for the Sauer Substance and the nitrogen significantly larger diffusion lock in metallic or ceramic housings as for the hydrogen.

A thinning of the hydrogen filling due to the fro diffusing out part of the hydrogen leads itself understandable to a deterioration in heat conduction in the operating state, so that fuses with a low Switch off the shutdown overcurrent automatically in rated operation. This will destroy the fuse itself if due to a slight leak or due to diffusion Boundary conditions have changed so far that the predicted function no longer occurs. The Self-destruction requires the fuse to be replaced against a new one, which in turn has the desired function Fulfills. It is particularly important that the enamel fuse according to the invention in this defect in the nominal operation shuts down and does not remain conductive security function no longer guaranteed.

A small amount of diffused into the case Oxygen can help to avoid an oxyhydrogen mixture with the help of earth deposited in the fuse housing alkali metals or alkali metals are bound. The Binding of possibly penetrated oxygen molecules also particularly important if another advantage of Filling a fuse according to the invention with With the help of hydrogen. Because of the quasi iner behavior of hydrogen towards metals  for the first time inferior electrical conductors such as tin, lead, Bismuth, aluminum or alloys thereof, and enamel conductor made of alkali metals or alkaline earth metals as their oxidation is no longer feared got to. If oxygen is invented in the housing appropriate fuse should have penetrated and at the same time fuse element of this or a similar type has been used is the binding of oxygen indispensable for the maintenance of aging resistance.

The materials mentioned point to the previously usual fine fusible conductors made of silver, copper and the like lower electrical conductivities on, so higher specific resistances. That leads in Result in fusible conductors with a larger cross-section, which are consequently easier to use. Also theirs Manufacturing is much easier, since thicker ones Fusible conductors more easily maintained closer tolerances than with thin fuse elements. About that are also using the materials mentioned as enamel ladder sluggish characteristics achievable. The landfill of one Getter material in the form of the alkaline earth metals mentioned or alkali metals is therefore advantageous in any case, be it to prevent the detonation of detonating gas, or be it about the oxidation and thus the aging of billi to avoid fusible conductors.

Due to another consideration, the getter material to be deliberately left out in case of intrusion of acid just oxidizing the inferior enamel conductor and thus the premature melting under Bring about nominal load. The oxidation is namely a sign for a diffused or a leak flowed oxygen, so that the originally dist Visible function of the fuse no longer fully is guaranteed. It heals this deficiency to the extent that when it will soon be destroyed under nominal load, i.e. by a functional fuse must be replaced. The  Introducing a getter material is therefore one of two ways to deal with intruded oxygen. At the choice of a corresponding fuse element can be Step deliberately omitted, and yet you get a fuse that has a critical error in Do not have a form of failure to switch off becomes.

It is assumed that in a specific individual case Melting insert according to the invention due to a fault stick through part of its hydrogen filling Has lost diffusion. Regardless of whether oxygen has penetrated or not and regardless of a possible Binding of the penetrated oxygen with the help of a Getter material must meet two other conditions be before the meltdown to a critical misfunction tion can lead:

• 1. The backup was made before the load case in which the critical error occurs, not taking a long time Normal conditions operated because, for example, a associated device was switched off for years.
• 2. The critical error occurs during a shutdown process at which the limit switching capacity of the melt sentence is required, which is just about safely controlled shutdown current occurs.

The coincidence of these two coincidences in connection with a leaky housing has such a low probability sensitivity to an error rate that arises below the one that has already been observed in melting operations Error rate lies.

Exemplary embodiments of the invention are which are shown in the drawing, explained in more detail; show in the drawing:  

Fig. 1 is a cross-sectional view through a first embodiment of a fuse according to the invention and

Fig. 2 is a cross-sectional view through another embodiment of a fuse according to the invention.

In FIG. 1, a typical embodiment of a fuse according to the invention is given again. It essentially consists of a metallic housing 1 with a metallic base 2 . The connection point is either assembled with the aid of hard solder 3 or welded (not shown), in particular using a resistance welding process or an electron welding process. In two places, the bottom 2 is provided with tubular contact bushings 4 made of glass, through which contact pins 5 are passed. In this way, a hermetically sealed structure is present, which has previously been seen with a hydrogen filling 10 .

A fuse element 6 is fastened between the inner ends of the contact pins 5 , in the usual way by clamping, cold pressure welding, soldering, thermal welding and the like. The fuse element can consist of a material of inferior quality, that is, be oxidative, since the interior of the housing 1 is provided with the hydrogen filling 10 . This filling acts like an inert gas filling, since hydrogen does not react with metals to the extent that is of interest here.

For neutralization of possibly incorporated in the housing 1 drungenem oxygen at the bottom are opposed to the inside of the housing 1, a getter material 7 is introduced, is condensed in a binder rylliumspänen from Be the example. Due to its violent reaction with oxygen, it binds penetrated oxygen molecules that may have penetrated into the housing 1 through diffusion or an undetected leak. In this way, the inert effect of the hydrogen filling is retained, and no oxyhydrogen gas is formed.

In Fig. 2, another embodiment is shown, which is used in particular for a fuse, which is used as a device fuse in this form in millions. It consists essentially of a ceramic tube 8 , which is metallized on the end faces. With the help of hard solder 3 metal caps 9 are soldered, it being important to ensure that the fused conductor 6 has a higher melting point than the hard solder. For example, the fuse element is made of silver, while the brazing alloy has a melting point between 600 and 700 °.

Again, a hydrogen filling 10 is present, in addition to which the fuse according to FIG. 2 contains two landfills of getter material 7 , which is brought into the ceramic tube 8 , with a binder in the vicinity of the wall.

The melt inserts shown in FIGS. 1 and 2 are shown much larger than in reality. The diameter of the housing 1 shown in Fig. 1 is in reality about 6 to 8 mm at about the same housing height. It is comparable in size to housings of low-power transistors, with similarities in terms of welding and hermetic tightness.

Claims (10)

1. Fuse for switching off an overcurrent in an electrical conductor, with a housing and two contact bushings, on which a fuse element is attached inside the housing, characterized in that the housing ( 1 ) is gas-tight and is filled with hydrogen. 2. A fuse according to claim 1, characterized in that the housing ( 1 ) consists of metal and the contact bushing ( 4 ) made of glass. 3. A fuse according to claim 1 or 2, characterized in that the housing ( 1 ) is welded shut. 4. Fuse according to one of the preceding claims, characterized in that the fuse conductor ( 6 ) consists of Sn, Pb, Bi, Al or from an alloy of these elements. 5. Fuse according to one of the preceding claims, characterized in that the housing ( 1 ) contains a getter material ( 7 ) for binding oxygen. 6. A fuse according to claim 5, characterized in that the getter material ( 7 ) is an alkaline earth metal and / or an alkali metal. 7. A fuse according to claim 5 or 6, characterized in that the getter material ( 7 ) is held in a binder. 8. A fuse according to claim 5 or 6, characterized in that the getter material ( 7 ) is present as a pellet or as granules and is housed in a divided housing section. 9. A fuse according to any one of claims 4 to 8, characterized in that the housing consists of a ceramic tube ( 8 ) metallized on its end faces, and that plates or caps ( 9 ) made of metal are soldered onto the end faces. 10. Fuse according to one of claims 1 to 3, characterized in that the fuse conductor ( 6 ) consists of an alkali metal or alkaline earth metal.