MD1102Z - Installation and process for wire extension in insulation - Google Patents

Abstract

The invention relates to the technology of reducing the wire cross-section in insulation.The installation and process for wire extension in insulation consists in heating the wire and its insulation to various temperatures, followed by wire extension and its insulation by means of a load. The wire is heated with electric current, and the insulation heated from the wire is cooled to a temperature, at which its coefficient of viscosity becomes close or equal to the coefficient of viscosity of the heated wire.

Description

The invention relates to the technology of reducing the cross-section of insulated conductor wires.

The process of obtaining conductive microwire in glass insulation is known, called the Taylor-Ulitovsky process, which includes melting the conductive material inside a glass tube, by heating it in the inductor of a high-frequency generator. Under the action of the magnetic field of the inductor, the conductive material melts, at the same time the tube softens, which becomes a glass coating of the molten metal. Obtaining microwires by this process is based on the continuous heating of the metal material with broaching of the molten metal through viscous glass [1].

The disadvantage of this process is the impossibility of obtaining extrafine microwires, because the broaching of the molten metal jet through the viscous glass mass is limited by the maximum broaching speed, when further increase in speed leads to breaking the continuity of the metal (or alloy) wire. Therefore, obtaining microwire with a diameter of 1...2 micrometers and smaller, called extrafine, in glass insulation is limited by the maximum broaching speed and by the condition of wire continuity.

Another disadvantage of the Taylor-Ulitovsky process is the difficulty of obtaining a glass insulation thickness less than or equal to the thickness of the conductor wire.

The closest solution is the process of obtaining fine and extra-fine metallic microfiber in glass insulation by heating and physically stretching the wire obtained by the Taylor-Ulitovsky method, in which, prior to making the microfiber, the insulating material and the metal (alloy) of the conductive microfiber are chosen with similar melting viscosity coefficients, then the obtained microfiber is heated and expanded until obtaining the extra-fine microfiber, adjusting the force and speed of expansion [2].

The disadvantage of this process is that fine and extra-fine wires can only be obtained from conductive wire and insulating material with similar melt viscosity coefficients.

The problem solved by the proposed invention consists in eliminating the need to choose the insulating material and the conductive wire material with similar melt viscosity coefficients.

The installation, according to the invention, eliminates the above-mentioned disadvantages by including an insulated thermal tank 11, inside which are placed two copper plates, one rigidly fixed 12a, and the other mobile 12b, with the possibility of moving along the horizontal axis, where the plates 12 are galvanically connected to a conductive wire 2 in insulation 1, some insulation temperature measurement sensors 13, placed equidistantly along the wire 2, and an insulation cooling device 14; the conductive wire 2 is galvanically connected to a voltage source 4, connected to a voltage meter 5, to a current meter 6, to an energy meter 7, to a weight control device 22 and to a voltage value control device 10, connected to a current comparator 9, which is connected to a processing device 8 and to the current meter 6; the sensors 13 are connected to a data storage device 15, connected to a reference temperature source 16; the cooling device 14, the storage device 15 and the temperature source 16 are connected to a temperature comparator 17; the movable plate 12b is connected to the current meter 6 and to a strand 20, which slides on a ball bearing 18, the strand 20 is connected to a wire tension force meter 19, connected to a weight 21 and the weight directing device 22; a video camera 24 is mounted on the top of the tank 11, connected to a screen 23.

The method, according to the invention, eliminates the above-mentioned disadvantages in that the conductor wire in insulation is heated with electric current from the voltage source and is expanded using the aforementioned installation, in which the conductor wire material and the insulation, which have different viscosity coefficients, are heated to different temperatures, at which the viscosity coefficients of the conductor wire material ηm and the wire insulation ηiz become close or even equal; the conductor wire being heated to a temperature at which the viscosity coefficient of the conductor wire material ηm becomes sufficient for the plastic expansion of the conductor wire, at the same time, upon reaching a temperature value higher than the softening temperature of the wire insulation, it is cooled by the cooling device 14 of the installation, to the temperature at which its viscosity coefficient ηiz becomes close to or equal to the viscosity coefficient of the heated conductor wire material, at the same time, the conductor wire is heated with electric current, the value of which is calculated using the processing device according to the formula

where

d - diameter of the conductor wire, in µm,

D - diameter of the conductor insulation, in µm,

t - melting temperature of the wire, in °C,

λ - thermal conductivity coefficient of air, in W/m°C,

ρ - specific resistance of the conductive material, in Ω·mm/m2.

The invention is explained by the drawings in Fig. 1-3, which represent:

- Fig. 1, view of the positioning of the conductor wire in the insulation before heating and expanding it, highlighting the conductor wire and the insulation,

- fig. 2, equivalent electrical diagram of the electrical heating circuit of the conductive wire,

- Fig. 3, block diagram of the installation for heating and extending the conductor wire in insulation.

The installation that performs the process operates in the following way. At the plates 12a and 12b, the wire 2 is galvanically joined to the insulation 1 in such a way that the conductive wire 2 has a galvanic connection with the said plates, while its insulation with the plates has only a physical connection. Next, the following are powered: voltage source 4, voltage meter 5, current meter 6, energy meter 7, processing device 8, current comparator 9, voltage value control device 10, insulation cooling device 14, storage device 15, reference temperature source 16, force meter 19, device 22 that controls with the weight value 21 during the extension of the wire, screen 23 and video camera 24 that projects on screen 23 the shape of the wire during its extension. Next, the values of the quantities d and C corresponding to the physical dimensions of the wire subject to expansion are entered into the device 8, in which the value of the current I0 is automatically calculated; by varying the voltage U, the current I=I0 is ensured, after which the weight 21 is connected to the value corresponding to the physical dimensions of the microwire at the measuring device 19, after which the expansion begins.

During the extension of the wire, its cross-section decreases and, respectively, its resistance per unit length increases, the current I that heats it inversely decreases while the extension force remains at the initial value. The latter can increase the speed of extension of the wire. The increased extension force can lead to wire breakage. In order to avoid wire breakage, the device 22, which by measuring the voltage U and the current I calculates the resistance of the conductor wire and its cross-section, automatically changes (reduces) the value of the weight 21, so that the wire extension force does not exceed the admissible extension value corresponding to the actual wire section (it is assumed that the insulation thickness decreases proportionally and simultaneously with the decrease in the cross-section of the conductor wire). In this way, the microwire is extended to the preset value of its cross-section.

The measurement of the wire insulation temperature and the control of its value takes place in the following way.

The device 17 consecutively in time collects the temperature from the sensors 13 and compares it with the reference temperature collected from the temperature source 16. Next, these two temperatures are compared by the comparator 17 and in the case of deviation of the real temperature from the sensors from the reference temperature from the source 16, this temperature difference is transformed by the comparator 17 into an electrical signal and acts on the system 14 which cools the wire insulation along the entire length or on certain portions of the wire, bringing it to the preset value. This control of the insulation temperature with its maintenance at the preset value takes place throughout the extension of the wire.

1. SU 161325 A1 1964.01.01

2. MD 1546 F1 2000.09.30

Claims (2)

1. Installation for extending the conductor wire in insulation, which includes an insulated thermal reservoir (11), inside which are placed two copper plates, one rigidly fixed (12a), and the other mobile (12b), with the possibility of moving along the horizontal axis, where the plates (12) are galvanically connected to a conductor wire (2) in insulation (1), some insulation temperature measurement sensors (13), placed equidistantly along the wire (2), and an insulation cooling device (14); the conductor wire (2) is galvanically connected to a voltage source (4), connected to a voltage meter (5), a current meter (6), an energy meter (7), a weight control device (22) and a voltage value control device (10), connected to a current comparator (9), which is connected to a processing device (8) and the current meter (6); the sensors (13) are connected to a data storage device (15), connected to a reference temperature source (16); the cooling device (14), the storage device (15) and the temperature source (16) are connected to a temperature comparator (17); the movable plate (12b) is connected to the current meter (6) and to a strand (20), which slides on a ball bearing (18), the strand (20) is connected to a wire tension force meter (19), connected to a weight (21) and the weight directing device (22); a video camera (24), connected to a screen (23), is mounted on the top of the tank (11). 2. Method for expanding the conductor wire in insulation, which consists in the conductor wire in insulation being heated with electric current from the voltage source and being expanded using the installation defined in claim 1, in which the conductor wire material and the insulation having different viscosity coefficients are heated to different temperatures, at which the viscosity coefficients of the conductor wire material ηm and the wire insulation ηiz become close or even equal; the conductor wire being heated to a temperature at which the viscosity coefficient of the conductor wire material ηm becomes sufficient for the plastic expansion of the conductor wire, at the same time upon reaching a temperature value higher than the softening temperature of the wire insulation, it is cooled with the cooling device (14) of the installation defined in claim 1, to the temperature at which its viscosity coefficient ηiz becomes close to or equal to the viscosity coefficient of the heated conductor wire material, at the same time the conductor wire is heated with electric current, the value of which is calculated using the processing device according to the formula where d - diameter of the conductor wire, in µm, D - diameter of the conductor wire insulation, in µm, t - melting temperature of the wire, in °C, λ - coefficient of thermal conductivity of air, in W/m·°C, ρ - specific resistance of the conductor material, in Ω·mm/m2.