CN211788283U - High-heat-conductivity wear-resistant glass fiber covered insulated electromagnetic wire - Google Patents

Abstract

The utility model discloses a high heat conduction stand wear and tear's glass silk package insulated electromagnetic wire, simple structure not only, it is main including the conductor, conductor temperature-resistant layer, glass silk covering and extexine, wherein, be equipped with conductor temperature-resistant layer on the conductor in proper order, glass silk covering and extexine, glass silk covering has good heat conductivility simultaneously around the package on conductor temperature-resistant layer, can obtain longer life when daily use, be difficult to by the wearing and tearing damage, conductor temperature-resistant layer has increased the heat resistance of electromagnetic wire, the extexine provides the electromagnetic wire and provides good protection, ensure that the electromagnetic wire has better wearability.

Description

High-heat-conductivity wear-resistant glass fiber covered insulated electromagnetic wire

Technical Field

The utility model belongs to new material metal material preparation processing field, in particular to high heat conduction stand wear and tear's glass silk package insulated electromagnetic wire.

Background

Magnet wires (magnet wires) are insulated wires used to make coils or windings in electrical products, and the magnet wires must meet various requirements in use and manufacturing processes, and are often used in special environments, which have high requirements on heat resistance and wear resistance.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing a high heat conduction stand wear and tear glass silk package insulated electromagnetic wire not only can possess the characteristic of high heat conduction, still has the glass silk package electromagnetic wire of stand wear and tear performance.

The technical scheme is as follows: a high-heat-conductivity wear-resistant glass fiber covered insulated electromagnetic wire comprises a conductor, a conductor temperature-resistant layer, a glass fiber covering layer and an outer surface layer.

Wherein, a conductor temperature-resistant layer, a glass fiber cladding and an outer surface layer are sequentially arranged on the conductor. The glass fiber covering is wrapped on the conductor temperature-resistant layer.

The utility model discloses a high heat conduction stand wear and tear's glass silk package insulated electromagnetic wire, simple structure not only has good heat conductivility simultaneously, can obtain longer life when daily use, is difficult to be damaged by wearing and tearing, and conductor temperature resistant layer has increased the heat resistance of electromagnetic wire, and the extexine provides good protection for the electromagnetic wire, ensures that the electromagnetic wire has better wearability.

Furthermore, the high-thermal-conductivity wear-resistant glass fiber covered insulated electromagnetic wire has a wrapping angle of 30 degrees between the glass fiber covering and the conductor temperature-resistant layer. As the utility model discloses an it is preferred, glass silk covering around the package angle be 30 degrees, can provide more intensive package around, can increase the number of turns around the package, provide better around the package performance.

Furthermore, the high-thermal-conductivity wear-resistant glass fiber covered insulated electromagnetic wire is characterized in that the glass fiber covering layer is formed by fusing glass fibers into glass fibers. As the utility model discloses an it is preferred, the glass silk that glass fiber made has that insulating nature is good, the heat resistance is strong, corrosion resistance is good, characteristics that mechanical strength is high, can provide better protection for the electromagnetic wire.

Furthermore, the high-thermal-conductivity wear-resistant glass fiber covered insulated electromagnetic wire is characterized in that the glass fiber covering layer is formed by wrapping two layers of glass fibers in a reverse angle. As the utility model discloses an it is preferred, double glazing silk is reverse angle and winds the package, and the performance around the package that provides that can be better promotes at the performance of insulating nature, heat resistance, corrosion resistance direction has more apparent effect

Furthermore, the high-thermal-conductivity wear-resistant glass fiber is wrapped by the insulated electromagnetic wire, and the conductor temperature-resistant layer is made of silica gel. As an optimization, the conductor temperature resistant layer adopts the thin layer that silica gel made, and silica gel can provide better heat stability, has fine adsorptivity simultaneously.

Furthermore, the high-thermal-conductivity wear-resistant glass fiber is wrapped by the insulated electromagnetic wire, and the conductor temperature-resistant layer is thermally sealed on the conductor. As the utility model discloses a preferred, the form that the conductor temperature resistant layer passes through the heat-seal covers on the conductor, has guaranteed the area of contact of conductor temperature resistant layer and conductor, has ensured simultaneously that can not produce the gap between conductor temperature resistant layer and the conductor.

Furthermore, the high-thermal-conductivity wear-resistant glass fiber is wrapped with the insulated electromagnetic wire, and the outer surface layer is a mica tape made of mica materials. As the utility model discloses a preferred, mica material has very high insulation, heat conductivility good, and chemical stability is good, has anti strong acid, alkali and compressive capacity, not only can provide good stand wear and tear performance, makes the holistic stability of electromagnetic wire better simultaneously.

Furthermore, the outer surface layer of the high-thermal-conductivity wear-resistant glass fiber covered insulated electromagnetic wire is wrapped on the glass covering layer, and the wrapping direction is opposite to that of the glass fiber covering layer. As the utility model discloses a preferred, the surrounding layer is around the package on the glass layer, and not only the time extexine is more abundant with the glass layer contact, improves the comprehensive properties of electromagnetic wire simultaneously, and reverse simultaneously is around the package for the structure is more stable.

Above-mentioned technical scheme can find out, the utility model discloses following beneficial effect has: the utility model discloses a high heat conduction stand wear and tear's glass silk package insulated electromagnetic wire, simple structure not only, good heat conductivility has simultaneously, can obtain longer life when daily use, be difficult to by wearing and tearing damage, the conductor temperature resistant layer has increased the heat resistance of electromagnetic wire, the extexine provides the electromagnetic wire and provides good protection, ensure that the electromagnetic wire has better wearability, the chooseing for use of each item material simultaneously makes the holistic performance of electromagnetic wire obtain the promotion with the cooperation.

Drawings

Fig. 1 shows the high thermal conductivity and wear resistance glass fiber covered insulated electromagnetic wire of the present invention.

In the figure: conductor 1, conductor temperature-resistant layer 2, glass fiber cladding 3, extexine 4.

Detailed Description

The invention will be further elucidated with reference to the drawings and the specific embodiments.

Example 1

The high-thermal-conductivity wear-resistant glass fiber covered insulated electromagnetic wire shown in fig. 1 comprises a conductor 1, a conductor temperature-resistant layer 2, a glass fiber covering layer 3 and an outer surface layer 4. Wherein, a conductor temperature-resistant layer 2, a glass fiber cladding 3 and an outer surface layer 4 are sequentially arranged on the conductor 1. The glass fiber cladding 3 is wrapped on the conductor temperature-resistant layer 2. Meanwhile, the wrapping angle between the glass fiber wrapping layer 3 and the conductor temperature-resistant layer 2 is 30 degrees. Furthermore, the glass filament coating 3 is composed of glass fibers fused into a glass filament. In addition, the conductor temperature-resistant layer 2 is made of silica gel. Wherein, the outer surface layer 4 is a mica tape made of mica material.

Example 2

The high-thermal-conductivity wear-resistant glass fiber covered insulated electromagnetic wire shown in fig. 1 comprises a conductor 1, a conductor temperature-resistant layer 2, a glass fiber covering layer 3 and an outer surface layer 4. Wherein, a conductor temperature-resistant layer 2, a glass fiber cladding 3 and an outer surface layer 4 are sequentially arranged on the conductor 1. The glass fiber cladding 3 is wrapped on the conductor temperature-resistant layer 2. Meanwhile, the wrapping angle between the glass fiber wrapping layer 3 and the conductor temperature-resistant layer 2 is 30 degrees. Furthermore, the glass filament coating 3 is composed of glass fibers fused into a glass filament. In addition, the conductor temperature-resistant layer 2 is made of silica gel. Wherein, the outer surface layer 4 is a mica tape made of mica material. In addition, the glass fiber cladding 3 is formed by wrapping two layers of glass fibers in a reverse angle.

Example 3

The high-thermal-conductivity wear-resistant glass fiber covered insulated electromagnetic wire shown in fig. 1 comprises a conductor 1, a conductor temperature-resistant layer 2, a glass fiber covering layer 3 and an outer surface layer 4. Wherein, a conductor temperature-resistant layer 2, a glass fiber cladding 3 and an outer surface layer 4 are sequentially arranged on the conductor 1. In addition, the glass fiber cladding 3 is wrapped on the conductor temperature-resistant layer 2. Meanwhile, the wrapping angle between the glass fiber wrapping layer 3 and the conductor temperature-resistant layer 2 is 30 degrees. Furthermore, the glass filament coating 3 is composed of glass fibers fused into a glass filament. In addition, the conductor temperature-resistant layer 2 is made of silica gel. Wherein, the outer surface layer 4 is a mica tape made of mica material. In addition, the glass fiber cladding 3 is formed by wrapping two layers of glass fibers in a reverse angle. In addition, the outer surface layer 4 is wrapped on the glass fiber wrapping layer 3, and the wrapping direction is opposite to the wrapping direction of the glass fiber wrapping layer 3.

Example 4

The high-thermal-conductivity wear-resistant glass fiber covered insulated electromagnetic wire shown in fig. 1 comprises a conductor 1, a conductor temperature-resistant layer 2, a glass fiber covering layer 3 and an outer surface layer 4. Wherein, a conductor temperature-resistant layer 2, a glass fiber cladding 3 and an outer surface layer 4 are sequentially arranged on the conductor 1. In addition, the glass fiber cladding 3 is wrapped on the conductor temperature-resistant layer 2. Meanwhile, the wrapping angle between the glass fiber wrapping layer 3 and the conductor temperature-resistant layer 2 is 30 degrees. Furthermore, the glass filament coating 3 is composed of glass fibers fused into a glass filament. In addition, the conductor temperature-resistant layer 2 is made of silica gel. Wherein, the outer surface layer 4 is a mica tape made of mica material. In addition, the glass fiber cladding 3 is formed by wrapping two layers of glass fibers in a reverse angle. In addition, the outer surface layer 4 is wrapped on the glass fiber wrapping layer 3, and the wrapping direction is opposite to the wrapping direction of the glass fiber wrapping layer 3. In addition, the conductor temperature-resistant layer 2 is heat-sealed to the conductor 1.

The foregoing is only a preferred embodiment of the present invention, and it should be noted that, for those skilled in the art, a plurality of modifications can be made without departing from the principles of the present invention, and these modifications should also be regarded as the protection scope of the present invention.

Claims (8)

1. The utility model provides a high heat conduction stand wear and tear glass silk package insulated magnet wire which characterized in that: comprises a conductor (1), a conductor temperature-resistant layer (2), a glass fiber cladding (3) and an outer surface layer (4); wherein, a conductor temperature-resistant layer (2), a glass fiber cladding (3) and an outer surface layer (4) are sequentially arranged on the conductor (1); the glass fiber cladding (3) is wrapped on the conductor temperature-resistant layer (2).

2. The high thermal conductivity and wear resistance glass-covered insulated magnet wire of claim 1, wherein: the wrapping angle between the glass fiber wrapping layer (3) and the conductor temperature-resistant layer (2) is 30 degrees.

3. The high thermal conductivity and wear resistance glass-covered insulated magnet wire of claim 2, wherein: the glass fiber cladding (3) is formed by fusing glass fibers into glass fibers.

4. The high thermal conductivity and wear resistance glass-covered insulated magnet wire of claim 3, wherein: the glass fiber cladding (3) is formed by wrapping two layers of glass fibers in a reverse angle.

5. The high thermal conductivity and wear resistance glass-covered insulated magnet wire of claim 1, wherein: the conductor temperature-resistant layer (2) is made of silica gel.

6. The high thermal conductivity and wear resistance glass-covered insulated magnet wire of claim 1, wherein: the conductor temperature-resistant layer (2) is thermally sealed on the conductor (1).

7. The high thermal conductivity and wear resistance glass-covered insulated magnet wire of claim 1, wherein: the outer surface layer (4) is a mica tape made of mica materials.

8. The high thermal conductivity and wear resistance glass-covered insulated magnet wire of claim 1, wherein: the outer surface layer (4) is wrapped on the glass fiber wrapping layer (3), and the wrapping direction is opposite to that of the glass fiber wrapping layer (3).

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