DE2808319A1 - Thermal fuse with meltable substance between two wires - has shell of heat resistant resin surrounded by outer casing of inorganic material - Google Patents

Abstract

The meltable substance is so held between the fuse wires, as to provide a series path for the current flow. The external part of the meltable substance is coated with a flux material, and the entire assembly is completely coated by a heat-resistant resin (4). The resin coated assembly is covered by a casing (5), and each fuse wire (1a, 1b) and has a peripheral protrusion (10) at a point coated with the resin. The meltable substance is a powder, and a mixture of the latter and a flux material (3) is press formed into a compact, electrically conductive part. This part connects both fuse wires. The meltable substance may be an alloy of Sn-Pb-Cd with a melting point of 145 deg.C.

Description

Overheating fuse

The invention relates to an overheating fuse, which also can be referred to as a thermal fuse or thermal fuse and then, when an electrical apparatus, device or the like reaches a temperature, which is above a permissible range limit, is able to use the electrical Shut off electricity that is generated by the electrical apparatus, device or the like.

goes through.

An overheat fuse is used for thermal protection an electrical device, i.e. if the temperature of this Device has reached a temperature value that is above a permissible range limit an essential part of the fuse, i.e. an easily meltable metal part, is melted, which has the consequence of switching off the electrical current. Generally it is necessary, or at least highly desirable, that an overheat fuse Has the smallest possible dimension because it is preferable to use the overheat fuse in the smallest possible space in the electrical installation to accommodate or provide.

As shown in Fig. 1, in a previously practically used, very small overheating fuse an easily fusible metal part 2 ' between conductor wires 1a1, 1b1 present, through which both wires are electrically are interconnected; and the scope of this easily fusible metal 2 ' is covered with flux 30 '; and further covers a heat-resistant Resin 32 simultaneously both end portions of the lead wires and the periphery of the flux material.

When the overheating fuse is in use, it melts Flux always before the temperature of the electrical device has a temperature value which is above the permissible range limit9 and the easily fusible metal melts when the temperature of the electrical device has a temperature value reached, which is above the permissible range limit. It is recommended as a the aforementioned cover material to choose a heat-resistant resin that has a melting point higher than that of the easily fusible metal is; and the cover made of heat-resistant resin can make the molten metal and cover the molten flux without it melting, i.e. that the heat-resistant resp.

- Resistant resin stays in its solid state.

Since the flux is already in the molten state before the Easily fusible metal melts when the easily fusible metal melts, the contact resistance between the heat-resistant resin cover and the molten metal due to the fact that the molten flux behaves like a lubricant, diminished; and a ball is formed the molten mass of the easily fusible metal, so that due to the Surface tension of the molten metal results in putty-like masses; and furthermore, there is an electrical current interruption between the two lead wires caused due to the spheroidization of the molten metal in connection with the intervening of the molten flux through which the electrical Power is interrupted.

One of the most important requirements for an overheat fuse should meet, is to quickly comply with or respond to their Immediate actuation to be provided when the temperature of the electrical device reaches a temperature value that is above the permissible range limit.

In practical use, it is inevitable that the above-mentioned The overheating fuse is repeatedly exposed to heating that causes a Rise in temperature the overheating fuse to one Temperature value, which is below, but close to, the temperature the permissible range limit lies9 because there are some fluctuations in practical use or fluctuations in the conditions or states of the electric current of the electric Establishment can occur. As a result, the performance test should be in be carried out in such a way that the overheat fuse is repeated Exposure to temperature treatments that occur or are in their practical use. are detectable.

However, the above-mentioned test shows an unsatisfactory result for this known overheating fuse, as will be clear from the following Test example for the overheat fuse results.

In the example, an alloy was used as the easily fusible metal of the Sn-Pb-Cd type with a melting point of 0 145 ° C. is used. As a flux was a mixture of 80 parts rosin or rosin, 18 parts paraffin and 2 parts of surfactant used9 and as a heat-resistant cover insulator material epoxy resin was used. When taking over the epoxy resin, make sure that that the shape of the easily fusible metal during the process of covering is not mechanically and thermally deformed with the resin. Considering of the above must be the curing temperature and the operation of covering strictly controlled with epoxy resin, so that the curing condition is a temperature of 30 C for 12 hours was applied to harden the epoxy resin after it was applied with a hollow spatula The following conditions were used: The lead wire diameter is 0.6 mm, the length of the easily fusible metal is 4 mm; the amount of flux is approx. 2096 based on the weight of the light fusible metal, and the diameter of the outer periphery of the Epoxy resin cover is 3 mm.

Considering a cycle of heat treatment of the overheating fuse, this consists of a treatment at a temperature of 1250C for 30 minutes and a subsequent treatment at a temperature of 25 ° C. for 30 minutes. The aforementioned one cyclic heat treatment was repeated on the test sample the overheating fuse, up to 700 times. According to the above The overheating fuse was subjected to heat treatments in an oil bath at 1500C immersed, and at the same time an electric current of 200 V, 2 A was passed through the overheat fuse passed through; and it was then found that it took 60 seconds for the electrical current to flow to the overheat fuse or was interrupted or switched off by this. At this result of the above It is noteworthy that testing of the above-mentioned overheat fuse of the type shown in Fig. 1, this time delay in terms of the desired immediate actuation of the overheating fuse considerably is great.

In the context of the present invention, investigations were carried out to clarify the cause of the occurrence of the above time lag, and it was found that this time lag in the heat treatment originated in the The epoxy resin cover has swelling caused by the swelling expansion pressure of the molten flux. Here it has to be from the industrial one From the point of view of avoiding the thickness of the epoxy resin cover becoming so large make that the puffing of the epoxy resin can be prevented because it is important is, desirably smaller spaces for the overheat fuse choose, so the overheating fuse to the smallest possible Restrict space. With a view to maintaining the dimensional stability of the easily fusible metal in the overheat fuse against heat and mechanical treatments, in particular the processes of epoxy resin application and smoothing process can be strictly controlled, and so the thickness of the epoxy resin cover not be great.

As a result, in the case of this type, it is the overheat fuse inevitably, the epoxy resin is caused to expand when heated caused by the expansion pressure of the molten flux.

In such a swollen state, the epoxy resin cover can void formation can be observed within the cover, and so the Heat transfer from the outside to the inside, i.e. through to the easily meltable metal9 this void generation is reduced, and the pressure of the molten flux, which serves to separate the ball from each melted, easily meltable metal "Breaking open" balls becomes weak due to the fact that it is used to White space generation is coming. As a result, a long period of time is required Ball of easily fusible metal melted to break 11 ??, and even if the overheating fuse is exposed below a temperature in which the easily fusible metal can be melted.

According to the present invention, a housing is made of inorganic Substance that has great mechanical strength under a high temperature used to encompass the flux and the easily fusible metal or to include, and it has the purpose of delaying the actuation mentioned or triggering of the overheating fuse, which in this inflation of the cover Their origin has to reduce and as far as possible to eliminate.

Because this void formation inside the cover caused by the heating cycles caused can be prevented according to the invention, the expansion pressure the molten flux is high when the easily fusible metal is melted, and as a result, the resulting ball can be made of molten, easily fusible Metal can be divided into pieces or small spheres. But in this case it is it is inevitable that a new difficulty will arise, and that the little that both opposite surfaces of the lead wires are subjected to this high pressure, and as a result, the wires tend to slide out of the overheat fuse.

The present invention provides an overheat fuse made available, which have a lower delay in their actuation or Has triggering and which is of great usefulness because it prevents it at the same time becomes that the lead wires slide out.

In accordance with the present invention, the overheat fuse includes Conductor wires that hold an easily fusible piece of metal through which electrical Current can pass from one of these lead wires to the other lead wire; as well as flux that is used at the same time as

in addition to the easily fusible metal is present or with the easily fusible metal is coexistent; a housing made of inorganic substance or inorganic material covering both lead wire ends along the same; a heat-resistant resin that is placed inside the housing or in the housing is loaded; and at least one protrusion formed on a portion of each lead wire end is arranged, and deeply sunk into the heat-resistant resin.

According to the present invention, the flux and the Easily fusible metal can be present or coexist at the same time, in particular the following embodiments can be selected. That means 9 in one Embodiment, the flux can cover the easily fusible metal, and In another embodiment, after one powder from easily meltable Metal mixed with flux and the resulting mixture heated to a temperature which is higher than the melting point of the flux but lower than the melting point of the easily fusible metal, the heated mixture obtained is subjected to a compression pressure exposed so that they are in rod or

Rod shape is poured or shaped or compression molded. With these Embodiments is flux in an amount of 15 to 40% by volume, based on the easily fusible metal.

The melting point of the flux is lower than that of the easily fusible metal.

The flux increases the fluidity of the molten, easily meltable one Metal, and consequently the "breaking" of the cohesion of the mentioned metal promoted by the thermal expansion pressure. A mixture of Turpentine or rosin resin, paraffin and surfactant are used will.

According to the present invention is used as a raw material for manufacture of the housing a material that is superior in mechanical strength and excellent Has heat transfer properties at a temperature higher than the melting point of the easily fusible metal, i. e.

ceramics and glass are particularly recommended. As heat resistant Resin can be a resin that is at the melting temperature of the easily fusible metal does not melt and outstanding Has thermal conductivity, e.g. epoxy resin, Silicone resin. This resin can be poured into the case, which, striding along or in the longitudinal direction, covers both conductor wires. This The process of pouring the resin is preferably carried out under a vacuum state executed. According to the present invention, the height of the projection is the Lead wire particularly preferably 10 to 30 / cm of the wire diameter, and the number of projections, in particular of projections running around the wire circumference, can be one or more.

The invention is described below with reference to the drawing explained in more detail with reference to some particularly preferred exemplary embodiments; show it: Fig. 1 shows a prior art overheating fuse which is already shown has been explained in more detail above; Fig. 2 shows a first embodiment of a Overheating fuse according to the invention; and FIG. 3 shows a second exemplary embodiment an overheating fuse according to the invention.

Reference is first made to FIG. 2, in which a first exemplary embodiment an overheat fuse according to the present invention is. In FIG. 2, lead wires are denoted by la, lb, while the reference numeral 2 is assigned to the easily fusible piece of metal that the lead wires la, 1b can mutually electrically connect and its diameter is equal to that the lead wires la, Ib is. The flux 3 is painted on or applied in such a way that that it covers the easily fusible metal 2. With 4 is the heat-resistant resin denotes that, for example, a hollow spatula has been placed on the surface, namely by walking along it or along the two lead wires; at 5 is a pipe made of inorganic material denotes which the includes heat-resistant resin and tightly or closely adheres to the resin 4. 10, 10 are each a projection, hump or the like. That formed on the end part of the lead wires 1 a, 1 b and buried in the resin 4 are.

Fig. 3 shows an embodiment of the packet or

Block type. In Fig. 3, 1a, 1b are lead wires, 10 is one, respectively Protrusion made on the lead wires 1a and 1b, respectively, 20 is easily fusible metal, 3 is flux, 5 is an inorganic casing Material, and 4 is heat-resistant resin. The heat-resistant resin 4 can be incorporated into the Housing 5 to be cast9 which has an air outlet 51, from the gas that is generated or is formed, expelled or let out so that there are no pores inside of the heat-resistant resin.

According to the present invention, there is the heat-resistant resin and the easily fusible metal airtight from the inorganic material case includes9 there is no air layer and the thermal conductivity from the outside to the inside, i.e. to the easily fusible metal, is excellent. Both The above-mentioned cyclic heat treatments can be made of inorganic material a protective wall against the increasing pressure of the molten flux due to the heat form, and as a result, there is no void formation between the Housing and the easily fusible metal. As a result, if the temperature of the Outside of the housing has reached the melting point of the easily fusible metal9 the temperature of the easily fusible metal quickly becomes equal to the melting temperature of this metal, and it melts, and at the same time the thermal expansion pressure becomes of the flux increased suddenly. As a result, it then occurs when the temperature the outside of the housing the temperature value of the melting point of the easily fusible Metal achieved, to that this easily fusible Metal in molten state is quickly "broken up" into balls.

According to the present invention, in the stage in which the Easily fusible metal melts and is "broken up", causing thermal expansion pressure of the molten flux noticeably or considerably increased due to the protective behavior or the protective effect of the housing, so that the two opposite, cut end sides of the lead wires, the cross-sectional area of which is equal to that this separated end or end face is subject to high pressure. However the protrusion on the lead wire strictly prevents it from sliding out in this case of the lead wire-made of the part made of heat-resistant resin, so that thereby the lead wire can withstand the above-mentioned high pressure.

As described above, according to the invention, an overheating fuse of practical usefulness or

Usability are established, the triggering or

Actuation takes place with less delay.

The following are the results of an actuation or

Trip tests of an overheat fuse according to the present Invention described.

Test Result 1 The test was made for an overheat fuse carried out of the type shown in FIG. As a housing made of inorganic material a ceramic tube was used with an outer diameter of 2.5 mm and an inner diameter 1.5 mm and its length was 10 mm. A mixture was used as the heat-resistant resin made of Araldite AY 103 and Araldite HY 930 (both manufactured by Ciba-Geigy) used. The diameter of the lead wire was 0.6 mm and the The height of its protrusion was 0.1 mm. As an easily fusible metal, a Sn-Pb-Cd type alloy used, which had a melting point of 145 ° C; and A mixture of 80 parts of turpentine or turpentine was used as a flux.

Rosin resin, 18 parts paraffin and 2 parts of a surfactant Used by means. The amount of flux used was 20 vol. Based on the volume of the easily fusible metal.

While electrical alternating voltage of 200 V, 2 A, through the test sample the overheating fuse made under the above conditions was passed through, this test sample was placed in an oil bath at 145 ° C immersed. The length of time from immersion to shutdown or interruption of the electric current passed was 15 sec. As for the heat cycle test, so a test was carried out by cyclic treatment 700 times, each of these cycling treatments consisted of sitting at 1250C. for 30 minutes heated and then left the test specimen or the test sample at room temperature for 30 h.

At the time when the aforementioned interruption of the electrical Stroms took place, the lead wires slipped out of the overheating fuse on what by the fixation or attachment of the projection on the lead wires was eliminated.

Test result 2 The test was carried out under the conditions those mentioned above under "Test result 1, but with the exception that a very easily fusible metal of an alloy of the Sn-Pb-Bi type was used, which had a melting point of 980C, and that as the heating temperature of the cyclic Heat treatment a temperature value of 85 0C was taken, and that the oil bath temperature Was 1000C.

In this test, the time was from immersion to shutdown or interruption of the electrical current was required 17 sec, and it occurred no sliding out of the lead wires.

Test result 3 The test was carried out as described under "Test result 1" but with the exception that flux covering was omitted, and that instead of the easily fusible piece of metal, a piece of rod was used that by compression molding a mixture made from a powder of an alloy of the Sn-Pb-Cd type of 100 to 200 mesh size (corresponding to a maximum particle size of 0.074 to 0.147 mm) and a flux, the latter consisting of 80 parts of rosin or rosin resin, 18 parts of paraffin and 2 parts of a surfactant, and also wherein the volume ratio between the powder and the flux was 80:20.

In this test, the length of time was from immersion to interruption of the electric current passed 13 seconds, and the lead wires did not slip out on.

Test result 4 The test was carried out under the conditions as described under "Test result 2", with the exception that one Covering with flux was omitted, and that instead the easily meltable one Metal was a piece of rod made by compression molding a mixture made of Sn-Pb-Bi type alloy powder of 100 to 200 mesh dimension (corresponding to a maximum particle size of 0.074 to 0.147 mm) and a flux, which in turn consisted of 80 parts of rosin or rosin, 18 parts paraffin and 2 parts a surfactant and the volume ratio between the powder and the flux 80:20 was.

In this test result, 4 was the length of time from immersion to 15 seconds passed before the electric current was interrupted, and there was no sliding out of the lead wires.

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Claims (2)

Claims overheating fuse with a pair of lead wires made of electrically conductive material, between which a part made of easily fusible Material is arranged or held that an electric current through them three materials can flow through in series; as well as with a flow material that covers the outside part of the easily fusible metal part; and with one heat-resistant resin material, which continues the scope, the periphery, the Outer surface, edge or the like of the flux and each opposite end portion of the conductors covered, in that it is not shown that a housing, Container, box, an outer shell, a jacket or the like. (5) of inorganic material the circumferential, edge, outer surface, Peripheral or the like surface of the heat-resistant resin material (4) is covered and each lead wire (la, lb) in each case at least one, preferably around its Has circumferential, projection (10) at one point, which with the heat-resistant Resin (4) is covered. 2. overheating fuse according to claim 1, characterized in that that the easily fusible metal (20) is in powder form, and that a mixture from the powder of this easily fusible metal (20) and the flux (7) through Compression is cast, shaped or compression molded so that a massive or massive, electrically conductive part (20) is formed, and that the resulting massive or solid part (20) forms a connection between the two line wires (1a, 1b), so that electricity resp. electric current can pass through.