DE2220370A1 - Overcurrent fuse - Google Patents

Description

Overcurrent fuse The invention relates to an overcurrent fuse with an insulating housing, which is closed at both ends with metallic contact caps and contains quartz sand as a filling, in which a metallic fusible conductor is embedded is, which is electrically connected at its ends to the contact caps.

In the case of such overcurrent fuses, there is a current limitation achieved in that the overcurrent causes a conductor with a resistance is interrupted in the backup. For improving the effectiveness of such Numerous suggestions have been made for fuses. So it has been suggested to provide a fuse with a fusible metal element that in its phase from solid state to liquid state and then from the liquid State changes into the vapor state when it is heated by an overcurrent, that flows through the fuse, being the quartz sand that surrounds the fusible metal arranged around in contact with this metal, with the metal element in vapor form State reacts and creates a material with high resistance, thus creating a circuit interrupt by using the fuse.

In this fuse, the fusible metal element is made of silver and is in the form of a wire or a foil.

This backup has a number of drawbacks. One disadvantage is that that when relatively small overflows flow through the fuse, not with it Safety is guaranteed that the fuse completely interrupts the circuit.

If the overcurrent is less than three times the current, for which the fuse is designed, the highest temperature occurs with this fuse in or near the central portion of the fusible metal element Area so that the fusible link also has its melting point in this area achieved. Because the energy when melting the middle section of the fuse element is not sufficient to also melt the remaining sections of the fusible conductor an arc across the opposite ends of the remaining sections formed of the fusible conductor, which remains until the stopped Sections of the fuse element are melted. This arc becomes the Quartz sand, which is exposed to the arc, is heated, making the quartz sand semi-liquid which in turn reduces the insulation resistance of the quartz sand. Although the arc power per second is relatively small, the arc can occur Pull the length of the fuse until the fuse is bridged by the arc or short-circuited. In this way it is prevented that the Fuse interrupts the circuit.

Another disadvantage of the backup is that because of the slow Phase change of the fuse element made of silver when overcurrents flow or short-circuit currents through the fuse in the fuse housing such high pressures can arise that the fuse housing bursts explosively. To the phase transition To accelerate the fusible conductor, attempts have been made to give the fusible conductor a larger one Surface by using a multitude of thin wires in parallel to each other and through the use of mesh-like or foil-like metals as fusible conductors. However, such fuses are very bulky and are susceptible to electrical Impact loads, such as those in the charging current of an I capacitance, in voltage peaks when switching on inductances and as electrical impulses during thunderstorms.

The object of the invention is to provide a fuse of the type mentioned above to create with which effectively a wide range of currents from a small overcurrent up to large overcurrents can be interrupted without maintaining an arc without any dangerous pressure inside the fuse housing is produced. The fuse should at the same time be able to generate electrical Absorbing shock loads, such as those in voltage peaks in the charging current of a capacitanceX when switching on inductances and as electrical impulses during thunderstorms and the like occur.

The stated object is achieved according to the invention in that the fusible conductor has a metallic core made of a metal that has a lower one Has a melting point than the sheath of the fusible conductor.

The invention is illustrated in the drawing in one embodiment and described in detail below with reference to the drawings.

Fig. 1 shows a longitudinal section through a preferred embodiment a fuse according to the invention for current limitation.

Fig. 2 shows on an enlarged scale a section of a fusible conductor as used in the fuse of FIG. 1, the outer metal jacket of the fuse element is cut.

3 again shows, enlarged, a cross section through a fusible conductor according to Fig. 2.

Fig. 4 shows in cross section a modified embodiment of a Fusible conductor that can be used in a fuse according to the invention.

The fuse 1 shown in longitudinal section in Fig. 1 has a cylindrical housing 2 made of an insulating jacket such as porcelain, glass fiber reinforced Plastic or the like.

The insulating housing has metal contact caps at both ends 3 and 3 'closed, which overlap the housing and on the housing in the usual way are fastened. The inside of the fuse is sealed by seals q and 4 ', which are arranged between the end faces of the housing 2 and the contact caps. A fusible conductor 5 is arranged inside the housing, at the ends of which there are contacts 6 and 6 'are attached by the Dichtiii <en and. 4 'passed through and are electrically connected to the contact caps 3 and 3 '.

As can be seen from FIGS. 2 and 3, the fusible conductor 5 consists of two different metals, namely an inner Hetallseele 7 and an outer Metal jacket 8.

The soul 7 consists of a metal with a relatively low Melting point, so that the soul inside the jacket melts when an overcurrent occurs flows through the seal. The outer metal jacket 8 is in close contact with the soul 7 and consists of a metal that has a higher melting point than the netall of which the soul is made.

The core of the fusible conductor can be made of tin and the outer metallic jacket 8 are made of copper. There can also be other metal combinations for the soul and the sheath is used, for example a combination of lead and silver, of zinc and nickel, of aluminum and titanium or of silver and vanadium steel.

In the illustrated embodiment, the soul has the shape of a Wire, while the sheath is in the form of a thin tube. Soul and coat can but also received some other borm.

The core and the outer metal jacket can be made by that the inner metal link, in the embodiment discussed here a tin wire, is inserted into the outer metal member, here a copper pipe, and the copper pipe with the tin wire then drawn to the desired thickness, with the inner tin wire is tightly sheathed with the outer copper pipe. The fusible link in the inventive Arrangement with an internal soul can of course also be applied to others Way to be made.

The finished fusible conductor preferably has a solid cylindrical one Cross-section as shown in FIG. 3. However, other cross-sections can also be used be used. Thus, Fig. 4 shows in cross section a fusible link 5 in which the core 7 and the jacket 8 each have a rectangular cross-section.

The fusible conductor 5 is preferably wound in a helical manner, see above that the required length is housed in the relatively short insulating housing can be.

However, other shapes can also be used for the fuse element will.

The mode of operation of a fuse with a fuse element according to the invention shall now be described below.

As shown in Fig. 1, the insulating housing is made of quartz sand 9 filled as a filler under atmospheric pressure. In the filler lies the Fusible link. The filler is used to react with the metal of the fuse element, if this is overexanated into the vaporous state of aggregation in order to in this way to produce a material of high resistance, with which an overcurrent through the seal is reliably interrupted if by the described current limiting fuse a relatively small overcurrent flows, the greatest amount of heat in the fuse element 5 is generated roughly in the middle section and this heat is from this section transferred to the ends of the fusible conductor. The netall soul reaches which consists of tin, a temperature close to the melting point below atmospheric pressure is equivalent to. The soul - however, remains in its solid state since the soul is under to the Pressure of the outer metal jacket, here the copper pipe, which encloses the soul. The temperature then continues to rise, with heat moving towards the ends of the metal core 7 is transferred until the metal core has a temperature over its entire length which is higher than the melting point. of metal under atmospheric Pressure. However, the soul remains in its solid state.

When the soul is above the temperature above the melting point has reached the entire length of the fusible conductor, the core 7 tears the copper pipe 8 and at the same time changes its solid aggregate state to the liquid aggregate state. Since the liquefied soul 7 is now relieved of the high pressure that is applied to the Soul was exercised by the outer metal jacket 8, an evaporation of the metal occurs the soul on, being. the metal vapor into the quartz sand that forms the filler 9 diffuses, in which the fusible conductor is embedded. The torn outer Metal jacket 9 made of copper is simultaneously by an electric arc evaporates, which forms over the torn metal particles of the copper jacket.

The insulating housing 2 is in this way with tin and Tvupferdämnfen filled, which come into contact with the quartz sand 9 and react. In the reaction of the fumes with the quartz sand becomes a high resistance material between the contact caps 6 and 6 'formed.

The transformation of tin and copper from the solid state to the vapor state happens extremely quickly.

The then-forming material with high resistance extinguishes the arc and interrupts the flow of current through the fuse. The resistor material that is produced, contains reaction products of silicon, tin and oxide and of Silicon, copper and oxide, substances which are known to have high electrical properties Have resistance.

If a relatively large overcurrent flows through the fuse, it will the transformation of the tin and copper that make up the fuse element through the strong current accelerates. Again, the tin core 7 is heated to a temperature, which is higher than the melting point of tin at atmospheric pressure, being up to remains solid at an even higher pressure and therefore in the serving as a filler Quartz sand escapes explosively, with the copper being shattered which consists of the outer metal jacket.

The tin is thus almost simultaneously with the sharp rise of the current flowing through the fuse element evaporates, and the copper is also evaporated immediately.

As can be seen from the description above, both Both the tin and the copper that make up the fuse element come from the solid phase transferred directly to the vapor phase. The copper and tin fumes come with that quartz sand used as a filler in contact and react with it to generate of high resistance material, causing an overcurrent to flow through the Backup is prevented.

Since the response time t is much shorter than that of a usual one Fuse, the generated energy I2t is also smaller. So it is in other words only a small amount of energy is required to interrupt a circuit when a Fuse is used in the embodiment of the invention.

It should be pointed out again that in the invention Fuse although an arc occurs when the fuse responds that this However, the arc is extinguished immediately after its occurrence. The reason for that lies in that the phase transition of both tin and copper from the solid in the vapor state momentarily takes place over the entire length of the fusible conductor. The arc is thus formed over the copper particles that are formed, when the copper jacket is torn or atomized. These copper particles become but then immediately converted into steam. Copper vapor and tin vapor react then with the quartz sand and create the high-resistance material so that the Arc can be extinguished.

The table below shows the melting characteristics of a fuse according to the invention with a fusible conductor with a wire-shaped tin core a diameter of 0.8 mm and a metal jacket in the form of a copper tube with an inner diameter corresponding to the outer diameter of the soul, so about 0.8 mm, and an outer diameter of 1 mm.

Table of current flow through the melting time * arc time ** fuse 30 not melted -32 500 5 50 20 1 100 1.3 0.5 1,000 0.01 0.2 10,000 0.005 0.15 * The melting time is the time between switching on and interrupting the current specified.

** The arc time is the time during which the arc is sustained became.

Claims (6)

Patent claims: 1. Overcurrent fuse with an insulating housing attached to both Ends with metallic contact caps is rounded as a filling of quartz sand contains, in which a metallic fusible conductor is embedded, which at its ends is electrically connected to the contact caps, characterized in that the Fusible conductor has a metallic core made of a metal that has a lower one Has a melting point than the sheath of the fusible conductor. 2. Fuse according to claim 1, characterized in that the inner Metal core has the shape of a wire and the outer metal jacket has the shape of a pipe has, whereby the coat and soul are in close contact with each other. 3. Fuse according to claim 1, characterized in that the soul made of tin and the jacket made of copper. 4. Fuse according to claim 1, characterized in that the soul made of zinc and the jacket made of nickel. 5. Fuse according to claim 1, characterized in that the soul made of aluminum and the sheath made of titanium. 6. Fuse according to claim 1, characterized in that the soul made of silver and the jacket made of vanadium steel.