SU1188804A1 - Fuse element - Google Patents

Abstract

1. FUSIBLE FUSE ELEMENT, containing a fusible conductor, made in the form of a solid metal strip with areas of reduced cross section and at least one of the sections of reduced cross section, shunted by a metal element, the opening of which with a section of reduced section is carried out by heat generated by a current predetermined values, characterized in that, in order to expand the scope of application by providing 2 possibilities of use in fuses with it is equipped with an insulating chamber; impermeable to the filler, and elastic U-shaped brackets, the insulating chamber is fixed in the cut-out of the reduced section section on the fixed parts of the shunt, the moving parts of the shunt are placed in the chamber of insulating material, and the shunt is made of two flat metal elements overlapped with each other L-shaped ends with holes by soldering, a. other ends of the shunt. they are bent in the area of their exit from the isolation chamber, attached by soldering to the reverse surfaces. a low-melting conductor on both sides of the shuntable region, the flat metal elements of the shunt are spring-loaded with elastic U-shaped brackets, so that their ends are freely placed in the openings of the L-shaped ends of the flat metal elements 00 00 00 cops, and their other ends are rigidly fixed on the body isolation chamber.

Description

(rig.

2. The fusible element according to claim 1, characterized in that the solder at the joint portion of the L-shaped ends of the flat metal elements has a melting point lower than the solder connecting these elements with the fusible conductor

The invention relates to devices for protection against accidents, namely fuses. The aim of the invention is to expand the field of use by allowing the liver to be used in fuses with filler. FIG. 1 shows the fusible conductor of the fusible element; in fig. 2 is an external view of a shunt isolation chamber; in fig. 3 - shunt section of a low-melting conductor; in fig. 4 - the position of the parts of the fusible element with the shunt open. The fuse element of the fuse comprises a flat fusible conductor 1 with sections 2 of reduced cross section and a shunt section 3 of reduced cross section. In the shuntable section 3 of a reduced cross section, there is a cutout 4. In the cutout 4 is placed on an insulating chamber 5, which is fixed on the stationary curved parts of the flat metal elements of the shunt 6. The flat metal elements of the shunt are made of metal with high electrical conductivity. The fixed, curved parts of the flat metal elements of the shunt 6 by the solder 7 are attached to the reverse surfaces 8 and 9 of the conductor 1 on both sides of the shunt section. The movable l-shaped ends of the flat metal elements of the shunt .6 are connected with each other with an overlap of solder 10. The l-shaped ends of the flat metal elements of the shunt 6 have 11 holes. rigidly mounted on the housing of the insulation chamber 5. The fuse with the proposed fusible element works as follows. When a rated current or a short-term overload current, for example, a current of multiplicity (1.2, -1.3) 1 |, flows, the heat absorbed in the low-melting conductor and the shunt has time to dissipate. At the same time, most of the heat, which is melted in the low-melting conductor 1, is absorbed by the filler, which, due to the placement of the insulating chamber in the recess 4, has a maximum contact surface with the low-melting conductor. The heat released in the flat metal elements of the shunt 6 is transferred mainly to the low-melting conductor 1 and to the filler through portions of the said elements in contact with the filler. In addition, part of the heat from the L-shaped ends of the flat metal elements of the shunt 6 is removed into the filler along the straps 12 and the walls of the insulating chamber. As a result, the temperature to which the l-shaped ends of the flat metal elements of the shunt 6 are heated does not exceed the critical one at which the solder 10 melts. A current of this magnitude passes unhindered through the fusible element. When current flows through a fuse of greater frequency or when a current flows for a long time (I-, 2-1.3) 1, the heat generated in the low-melting conductor and shunt does not have time to dissipate. The temperature of the heating of the L-shaped ends of the flat metal elements of the shunt 6 increases and when the critical temperature is reached, the solder 10 melts. Solder 7 has a melting temperature higher than that to which parts of the fusible element can warm up both in normal operation and tripping fuse. 3 Therefore, the connection of the flat metal elements of the shunt 6 with the low-melting conductor at the critical temperature is not broken, and the coupling of the G-shaped ends of these elements with each other weakens when melting, and under the pressure of elastic U-shaped brackets 12 they flex tied to FIG. 4. As a result. . in the fusible element, a section with the smallest cross section is formed, which melts at a current of a given magnitude, forming an open circuit. With an increase in the multiplicity of current passed through the fuse, the heating rate of the parts of the fusible element will increase. At some current multiplicity, the heating rate will become such that the melting of the unshunted sections of the low-melting conductor will be faster than the opening of parts of the shunt. In this case, the circuit will be broken due to the burnout of the non-shunted sections, which will provide the necessary speed of the fuse. Due to the fact that the moving parts of the shunt are placed in an insulating chamber impermeable to the filler, the proposed fusible element can be

44 use in fuse with filler. At the same time, despite the reduction in the path traveled by the extreme points of the moving parts of the ptun, when it is opened, it is possible to make a gap p between the opening parts not less than if there is one mobile part, as was done in the prototype. This is made possible by the presence in the proposed fusible element of a shunt with two elements opening in different directions. Thus, the field of application of a fusible element containing a shunting section of reduced cross section is expanded due to the fact that the moving parts of the shunt are placed in an insulating chamber impervious to the filler, and the shunt is made of two spring-loaded flat metal elements. The proposed fusible element of the fuse will expand the scope of application of the fusible element with the shunting area by using it in fused fuses. Fuses with the proposed fusible element can be used to protect semiconductor devices.

Claims (2)

1. FUSELY SAFETY ELEMENT, comprising a low-melting conductor, made in the form of a continuous metal strip with sections of a reduced cross section and at least one of the sections of a reduced cross section, a shunted metal element, the opening of which with a section of a reduced section is carried out by heat generated by a current of a predetermined value characterized in that, in order to expand the scope by providing the possibility of use in fuses with oil, it is equipped with an insulating chamber; impermeable to the filler, and with elastic U-shaped brackets, the insulation chamber is fixed in the cutout of a section of a reduced section on the fixed parts of the shunt, the moving parts of the shunt are placed in the chamber of insulating material, and the shunt is made of two flat metal elements interconnected overlapping by L-shaped ends with holes by soldering, a. the other ends of the shunt are bent in the area of their exit from the insulating chamber, connected by soldering to the return surfaces of the low-melting conductor on both sides of the shunt section, and the flat metal elements of the shunt are spring-loaded with elastic U-shaped brackets, so that one of their ends is freely placed in the holes Г -shaped ends of flat metal elements, and their other ends are rigidly fixed to the housing of the insulating chamber. figure 1 2. Fusible element in π. 1, cop has a melting point characterized in that it is lower than the solder connecting these solders at the junction of the G-shaped elements with a low-melting conductor., Other ends of flat metal elements