DE2121120B2 - OVER-TEMPERATURE SAFETY DEVICE FOR AN ELECTRIC WINDING - Google Patents

Description

sammenziehuug is effected _au f due to the reduction of the oxide skin of the molten metal under ball formation due to surface spam King the metal.

In the case of fuses without flux and reducing agents, there is a possibility that the melted Metal is held together by the non-reduced oxide skin, so that the current only passes through is interrupted at higher than expected temperatures if the change in position of the melted zenen metal not by other forces, e.g. B. gravity, is favored.

The inventive coordination of the melting temperatures of the metal or metal alloy used on the desired shutdown temperature can, for. B. by using an eutectic metal alloy for the fuse element and a flux whose melting temperature is at or above the melting temperature of the Eutckiischen metal alloy. ao

The alloy lying melting temperature used c iungsbereichs or above the upper limit of "5 softening: When using a non-eutectic metal alloy of a eutectic-forming metals, a flux enirnehlt over the melted away p ^r -ratur the eutectic, but within the Erwc!.

Non-eutectic, so-called edge alloys, may be preferable from case to case because they are easier to process, to obtain a certain switch-off temperature or from pi -. A feature of these alloys, however, is that they do not have a defined melting point, but rather ::! that in a so-called softening range eutectic alloy with a low melting temperature and alloys with a higher melting temperature exist side by side. Only above a DiaciY.mm line that delimits the softening areas are all alloys with certainty Γ them. The mechanical properties of the alloy. ngcn in the softening depend on c \ 1 they aiii acting temperature changes u; : d the duration of the temperature exposure.

If the target response temperature of a flow medium is now in the E. softening area of the alloys, see above iv-, shares the risk that the backup over the course of the / 'e completely undefined at any temperature responds within this range.

This disadvantage can be avoided by using fluxes with a melting temperature that is noticeable above the melting temperature of the eutectic alloy, but still in the softening range of non-eutectic alloys and in this area still below the temperature at which the alloy used for the fuse element is liquid.

Such fuses are briefly heated respond at a temperature at which the alloy is completely liquid. For longer Effect of temperature within the softening range. but below the melting temperature of the Alloy, the switch-off temperature can fall into the softening range, but never below the The melting temperature of the flux will decrease.

Increased security against undesired shutdown at temperatures within the softening range of non-eutectic alloys can be achieved by using a flux whose melting temperature is at or above the temperature at which the alloy is completely liquid.

Such fuses will ^{switch off at short T} f ^m P ^ ^a ' turbo loads with certainty at or above the melting temperature of the flux. In the case of prolonged exposure to temperature, the response temperature can fall into the melting temperature of the flux, but never into the softening range of the alloy.

Fluxes with different melting temperatures, which are suitable for the purposes of the invention, are in the form of urea with a? ^{ctun <} ^ r temperature of 133 ^C C and abietic acid with a melting temperature of 173 ° C available. Natural rosin, the 90 · /. Contains abietic acid. In addition to abietic acid, commercially available rosin also contains an admixture of isomeric resins and , depending on the amount of these resins, has a melting temperature of 1 O to 130 ° C. By hydrogenating the abietic acid content, the melting temperature of the rosin can be increased by a further 20 ° C So that just by the. Rosin a melting temperature range from 1.10 to 15Ü <- dl

can be deleted. n _m ; _t t, »in

Fuses according to the invention, with fluxes whose melting temperature is in the softening area of the selected low-melting alloys, are constructed as follows: f Alloy for the current-conducting part of the fuse element: 33.3 · /. Bi, 33.3 »0 Sn and" 3 4 0 0 Pb; softening range: 95 to 14U ^. Flux for this fuse element. Urea with a melting temperature of 133 c. "» Alloy for the conductive part of the fuse element: 60 »0 Sn. 40 0 /. Bi; Softening range: 138 to 170 ^c C: Flux for this fuse element: Hydrogenated rosin with a melting temperature of 15U- <~. Additional fuse elements are designed for even higher response temperatures. They contain: 3. An alloy for the conductive part of the fuse element made of 43 »0 Bi, 31.5% Pb, 25 ⁰ O Sn and 0.5 ° 0 Cu; softening range: 95 to 115"C; Flux: urea with a melting temperature of 133 ^ C or rosin with a melting temperature of 12U <-.

4 Alloy for the conductive part of the safety element: 50.5% / 0 Bi. 27.8 U Pb, 12 4 ° Sn, 9.3% Cd; Softening range: pa up to 163 C; Flux: abietic acid with a melting temperature of 173 ⁰ C.

5 Alloy for the conductive part of the fuse element: 60 "0 Sn, 40%>Bi; softening range: 138 to 170 ^c C; flux: abietic acid with a melting temperature of

173C. .

6 Eutectic alloy for the current-conducting part of the fuse element: 56.5% Bi, 43.5% Pb; Melting temperature. 120 ⁰ C; Flux: urea with a melting temperature of 133 ^C C.

Embodiments of securing elements that are made using those mentioned under 1. to 6. Fabrics are shown in FIG. 1 to 4 illustrated. It shows .

F i g. 1 a fuse element in a flat shape mn

simple safety strip with a flux pad for insertion into the winding body or the Winding a choke coil, and

F i g. 2 shows a section through the securing element according to FIG. 1,

3 shows a fuse element made from a low-melting point Hollow wire with flux filling and insulating sleeve, and

F i g. 4 a fuse element made from a solid wire of a low-melting metal with a flux coating in an insulating tube.

The fuse element according to FIGS. 1 and 2 has a simple metal strip 10 which, for. B. an alloy of 33.3 Vo Bi, 33.3%> Sn and 33.4 ° / o Pb may be made, which softens in the range of 95 to 140 ° C. At the two ends of the strip 10 connecting wires 11 are welded and on part of its surface urea is applied with a melting temperature of 133 ° C, either directly on the metal itself or in a urea-enriched strip 12 (Fig. 2) made of porous Material. The entire sealing element is located between two transparent plastic films 13 which are welded to one another at their edges all around with a weld seam indicated by small crosses.

The fuse element according to Fig. 3 consists of a tube 15 with 5 passages, which with 173 ° C melting abietic acid 16 are filled and clamped in the connecting wires 17. That Tube 15 itself consists of an alloy of 60% Sn and 40% Bi, which eats in the range 138 to 170 ° C

softened. There is still one closed at its ends by softening and squeezing Insulating tube cover 18, which prevents molten parts of the fuse element from falling out.

The securing element according to FIG. 4 differs from that according to FIG. 3 in that it from a solid fusible wire 20 with welded connecting wires 21 and from one Flux 22 applied to the outside of the wire 20 is made. The fuse wire 20 can consist of a Alloy of 50.5 »/ 0 Bi, 27.8% Pb, 12.4» / 0 Sn and 9.3% Cd consist, which softens at 158 to 163 ° C, and the flux 22 of abietic acid with a Melting temperature of 173 ° C. In this case it is particularly important that the melting temperature of the Flux is above that of fuse wire 20 so that the flux does not melt prior to melting the wire drips off.

By inserting the fuse element in a heat-resistant insulating tube 23, for. B. made of polycarbonate, which is welded tightly to the connecting wires at its ends under pressure and heat is, it is achieved that the melting of the wire and the thereby under the influence of the flux occurring dissolution of the metal parts with ball formation all rudiments of the fuse element within of the insulating tube remain.

On the other hand, there is also the possibility of the fuse elements with a solid cover, z. B. to be provided by overmolding or pressing with thermoplastic or thermosetting plastics.

1 sheet of drawings

Claims (9)

element in a heat-resistant insulating patent claims: hose is used, the interior of which is not completely filled by the fuse element 1. Overtemperature protection for an electrical winding with an iron core of this type 5
spatial expansion that a winding or Short to ground, regardless of his the same temperature distribution
and where the hottest spot is unchangeable and known, consisting of an io
in good thermal contact with the one to be protected The invention relates to an over-temperature metal or an alloy of metals with door fuse for an electrical winding with a melting point of up to 250 ° C, the over-iron core of such spatial extent that a temperature fuse is dimensioned and arranged - 15 winding or short to ground, regardless of whether the sum of the melting temperature at the place of origin, the same temperature distribution of the fuse metal and the temperature causes and where the hottest point and temperature difference between the hottest point is variable and known, consisting of a metali device in the winding and the point at which there is good thermal contact with the winding fuse to be protected, in the eye-eye of the disconnection, and where the metal or an alloy of Metals with one or the metal alloy of the fuse elements s Melting point up to 250 ° C, with the excess temperature expanding when the metal melts - door lock is dimensioned and arranged in such a way that the or gas-emitting substance is used as flux - the sumrue is given from the melting temperature of the lock, according to patent 14 88 992, thereby 25 nmgsmetalls and the temperature difference zwigekmarks that the melting points see the hottest point of the winding and that of the metal or the metal alloy and the point at which the fuse is located in the flux to the desired switch-off temperature- instant of switch-off about 250 ^? C is matched to the temperature. and where the metal or the metal alloy des 2. Overtemperature protection according to claim 1, 30 fuse element is added when the metal is melted by the use of an expanding or gas-releasing substance as a eutectic metal alloy for the fuse flux, according to patent 14 88 992.
element and a flux, the fusible temperature. 35 pending temperature switch off safely. this will 3. Overtemperature protection device according to claim 1, characterized by the selection of a suitable alloy by using a range. non-eutectic metal alloy from a Eutek- The invention is based on the object of a tikum-forming metals and a flux to create fuse, which up to a certain, with a limit temperature above the melting temperature of the eutectic 40 below the switch-off temperature, but does not respond within the softening range temperature with certainty. These grenaders The alloy used has a melting temperature of approx. B. at the drying and imprinting temperature. kidney temperature of the electrical winding or one 4. Overtemperature protection according to claim 1, complete device with built-in fuse or characterized by the use of a 45 at the temperature which the fuse at annihilating eutectic Metal alloy obtained from an Eutek-sharpened test or from the permanent test forming metals and a flux, operated a device under unfavorable conditions its melting temperature at or above the occurring temperature. The smaller the distance upper limit of the softening range between the switch-off temperature of the fuse and alloy used. 50 of the limit temperature mentioned, the less 5. Overtemperature protection according to claim 1 usable alloys are available for the appropriate to 4, characterized by the use of fuse available. But also is Abietic acid as a flux. still to consider that the response temperature of the 6. Overtemperature protection device according to claim 1 protection when using non-eutectic Legiebis 4, characterized by the use of 55 stanchions in continuous operation at high temperatures essentially of hydrogenated abietic acid as a result of recrystallization downwards or upwards standing rosin as a flux. may differ. 7. Overtemperature protection according to claim 1 The object of the invention is thereby bis 6, characterized in that the Flußmit- solves that the melting point of the metal or the Tel firmly bonded to the metal alloy and the flux with the securing metal is. desired switch-off temperature are matched. 8. Overtemperature protection according to claim 1 It has been shown that when responding to 7, characterized in that they are in one of fuses according to the main patent, which z. B. Fixed enclosure is built with free space of a 10 to 20 mm long, with urea or for the tubes filled with rosin melted from a low when the fuse was triggered substances. melting metal can exist, the lower 9. Overtemperature protection device according to claim 8, breaking the passage of current by expansion characterized in that the securing of the melted rosin and by adding