KR100479921B1 - heat cable and manufacturing method for an electric heater - Google Patents

Abstract

The present invention disclosed is to maximize the electromagnetic wave blocking effect, thereby minimizing the harm caused by harmful electromagnetic waves on the human body.

In the present invention for realizing this, the heating wire member 10 is made to generate a resistance heat by the current applied in the insulating state; A non-resistive wire member 20 which is formed to be energized under an insulated state, is connected in series with the hot wire member 10, and is twisted in a spiral form in one direction with the hot wire member 10; It is formed so as to be energized in an insulated state, wound around the heating wire member 10 and the non-resistive wire member 20 in the form of a spiral in one direction, the both ends of the electromagnetic wave absorption conductor member 30; Provided is an electromagnetic wave attenuation heating wire, and a method for manufacturing the heating wire.

Description

Electromagnetic wave attenuation heating wire and method for manufacturing the heating wire {heat cable and manufacturing method for an electric heater}

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to an electromagnetic wave attenuating heating wire that generates heating by generating electrical resistance heat, and more particularly, to an electromagnetic wave attenuating heating wire which minimizes generation of harmful electromagnetic waves.

There are many ways to generate heat. That is, resistance heating to obtain electric heat by passing a current through a heating wire, arc heating to obtain electric heat while an arc is generated, and induction heating to obtain electric heat by flowing an electric current through a conductor such as a metal.

In particular, the resistance heating as described above may be heated by direct resistance heating, which transmits an electric current to the object to be heated, heat radiation and thermal conduction generated when an electric current is applied to a non-metal heating element such as a metal resistance wire or silicon carbide by approaching the object to be heated. It can be divided into indirect resistance heating, which heats and heats water.

On the other hand, as a heating apparatus using the heat obtained by using the indirect heating as described above, there are various such as electric rice cooker / electric heating apparatus / electric iron / electric stove.

In addition, in the case of using oil or gas as the heating fuel, not only combustion efficiency is low, but also the harmful effects of the combustion gas, and when using the night-time electricity can maximize the energy use efficiency, as described above Increasingly, the use of electric heating appliances using indirect heating is on the rise.

As such, when heating is to be performed using electric energy, a heating wire is provided to convert the electric energy into heat energy, and it is necessary to use a heating device having a structure capable of preventing a short circuit.

As described above, the heating wire provided in the heat transfer mechanism uses nichrome wire / iron chromium wire at a temperature of 1,000 ° C. or lower, silicon carbide / cantal wire at higher temperature, and molybdenum silicide wire at 1,400 ° C. or higher.

In particular, in order to obtain electric heat for heating, the core wire made of a metal such as nichrome or iron chromium is generally coated and used, but it is known that harmful electromagnetic waves are generated from such heating wires, and the purpose of reducing harmful electromagnetic waves As a result, many research efforts on heating wire have been made.

As part of this research effort, a 'electromagnetic shielding heating wire' is proposed as in Registration No. 192649. Looking at the structure, the heating element line 10 and the heating element line 10 are shown in FIG. The Teflon insulating layer 12 to be covered, the insulating tape 14 covering the Teflon insulating layer 12, the AL tape layer 16 coated thereon, and the fabric coated on the AL tape layer 16. It consists of the braid layer 18 and the insulating layer 20 coat | covered by the said woven braid layer 18. As shown in FIG.

The heating element wire 10 is formed in the form of twisted nichrome wire of 3 to 15 strands, the Teflon insulating layer 12 is formed by extrusion molding with Teflon to have a specific dielectric breakdown voltage, the A tape layer ( 16 is designed to increase the breakdown voltage of the Teflon insulating layer 12 and to absorb the electromagnetic waves generated from the heating element line 10.

In addition, the braided layer 18 is coated on the A1 tape layer 16 so as to absorb the electromagnetic waves emitted from the heat generator 10 when heat is applied and to facilitate heat dissipation. The insulating layer 20 coated on the same braided layer 18 is extruded from silicone rubber.

On the other hand, the woven braid layer 18 is woven and braided with copper wire plated with tin so that the tensile strength is good.

By the way, the conventional heating line as described above absorbs the electromagnetic waves generated in the heating element line 10 by the A1 tape layer 16, but the A1 tape layer 16 is formed of the Teflon insulating layer 12. Although the dielectric breakdown voltage can be increased, the effect is only minimal for the absorption and removal of harmful electromagnetic waves.

Another design that can supplement the technical contents of the registration designation No. 192649 is the registration designation 249031. Looking at the configuration of such design, as shown in Figure 2, the core consisting of 20 to 30 resistive copper wire ( 11) is wrapped in a coating layer 12-1 such as Teflon or nylon, and spirally wound the heating conductor 13 commonly connected to the core 11 by soldering thereon, and the heating conductor 13 is wound. It is made by wrapping it again with a covering layer 12 such as nylon, spirally winding the temperature detecting conductor 14 thereon, and wrapping the temperature detecting conductor 14 with an insulating layer 15 such as PVC.

In this way, when the temperature of the heat generating conductor 13 rises as a current flows in the core 11 and the heat generating conductor 13 for a predetermined time, it is caused by the temperature change of the heat generating conductor 13. The impedance change of the coating layer 12-1 is detected by the temperature detecting conductor 14, and the current interruption to the heat generating conductor 13 is adjusted under the control of the controller which received the detected value.

However, although the registration proposal of No. 249031 described above has a noise power of 10 to 20 dBpW smaller than an average noise power, on the other hand, due to such a deterioration of the noise power, the harmful effects of harmful electromagnetic waves cannot be attenuated. .

On the other hand, the registration proposal of No. 233539, which employs carbon yarn known to generate the least electromagnetic waves as a heating wire, as shown in Fig. 3, winding the outer side of the carbon fiber 60 of a plurality of strands in the glass fiber chamber 70 The outer surface of the carbon yarn 60 and the glass fiber chamber 70 is covered with silicon 20, and the outer surface of the silicon 20 is covered with a glass fiber mesh 30, and the glass fiber network 30 A plurality of copper wires 40 are simultaneously wound on the outside of the wire), and the glass fiber net 30 and the outside of the copper wires 40 are covered with silicon 50.

In addition, the carbon yarn 60 may be made of 2400 strands, the copper wire 40 may be made of three strands.

As described above, the registered design of No. 233539 employs carbon yarn 60, which is known to generate the least electromagnetic waves, as a heating wire, and has a structure in which the copper wire 40 in an insulated state is wound in a spiral form and insulated again. Therefore, a slightly improved electromagnetic wave blocking effect can be expected compared to the above-mentioned registration proposals, but in addition to these factors, no means for blocking electromagnetic waves have been devised.

In addition, conventional general heating wires are usually wound around the heating wires 60 and 70 outside the heating wires 60 and 70 connected in parallel as in FIG. 4A, or are disposed at the center, as shown in FIGS. 4B and 4C. Although the structure of the non-resistive conductive wire 30 electrically connected to the outside of the heating wire 10 may be formed, the blocking effect of the electromagnetic wave and the electric wave emitted from the heating wire 10 is insignificant.

The present invention is to provide an electromagnetic wave attenuation heating wire that can maximize the electromagnetic wave blocking function, which is an inherent function as described above, thereby minimizing the harmful effects of harmful electromagnetic waves on the human body. have.

In order to achieve the above object, the present invention, the heating wire member 10 is made to be generated by the resistance heat by the current applied in the insulating state; A non-resistive wire member 20 which is formed to be energized under an insulated state, is connected in series with the hot wire member 10, and is twisted in a spiral form in one direction with the hot wire member 10; It is formed so as to be energized in an insulated state, wound around the heating wire member 10 and the non-resistive wire member 20 in the form of a spiral in one direction, the both ends of the electromagnetic wave absorption conductor member 30; It provides an electromagnetic wave attenuation heating line characterized in that made.

The hot wire member 10, the carbon yarn bundle (2) provided with a plurality of thin wires overlapping; In order to insulate the carbon lumps (2), it is characterized by consisting of a coating (4) forming the outer shell of the carbon lumps (2).

The hot wire member 10, the bundle of nichrome wire (6) is provided with a plurality of thin nichrome wire twisted in the left direction conductive; In order to insulate the nichrome wire bundle 6, it is characterized by consisting of another coating (8) forming the outer shell of the nichrome wire bundle (6).

The non-resistive wire member 20 includes a non-resistive wire 12 having a plurality of conductive lines twisted in a left direction; In order to insulate the non-resistive conductor 12, it is characterized in that it is made of another coating 14 forming the outer shell of the non-resistive conductor 12.

The electromagnetic wave absorbing conductive member 30 includes: another non-resistive conductive wire 22 having a plurality of conductive lines twisted in a left direction; In order to insulate the other non-resistive conductor 22, it is characterized in that it is made of another coating (24) forming the outer shell of the non-resistive conductor 22.

The electromagnetic wave absorbing wire member 30 is a bundle of carbon wires formed by varnish in a form in which a plurality of conductive wires overlap and are unfolded in a predetermined width, and the heating wire member 10 and the non-resistive wire member 20 are described above. It is characterized by being wound in a spiral form in one direction.

The heating member 10, the non-resistance member 20 and the conductive member 30 for absorbing electromagnetic waves is characterized in that it is formed of a structure wrapped by another coating (40).

The multiple coatings 4, 14, 24 and 40 are characterized in that they are silicon materials.

The multiple coatings 4, 14, 24 and 40 described above are characterized in that they are Teflon materials.

The multiple coatings 4, 14, 24, 40 are characterized by being flame retardant PVC.

On the other hand, the electromagnetic wave absorbing wire member 30 is characterized in that the winding having a spiral pitch of 3mm.

In addition, in the present invention, the heating wire member 10 and the non-resistance wire member 12 are twisted in a spiral form in one direction, and the heating wire member 10 and the non-resistance wire member 12 are connected in series, and the heating wire member 10 is described above. ) And the non-resistive wire member 12 is wound around the electromagnetic wave absorbing wire member 30 so as to secure a spiral pitch of 3 mm, and the heating wire member 10, the non-resistive wire member 20, and the electromagnetic wave absorbing wire member ( It provides a method for producing an electromagnetic wave attenuating heating wire formed by wrapping 30) with another coating 40.

Hereinafter, a preferred embodiment of the present invention will be described in more detail.

Example 1

6 to 9, according to the present invention, the heating wire member 10 is formed to generate resistance heat by current applied under an insulated state, and is formed to be energized under an insulated state. It relates to an electromagnetic wave attenuation heating line consisting of the non-resistive wire member 20 and the electromagnetic wave absorbing wire member 30 is formed so as to be energized under an insulating state.

That is, as shown in FIG. 5, in a state in which the heating member 10 and the resistanceless member 20 are connected in series, the wires 10 and the resistanceless member are twisted in a spiral form in one direction. The electromagnetic wave absorbing lead member 30 is wound in a spiral form in one direction, and both ends of the electromagnetic wave absorbing lead member 30 are electrically grounded.

On the other hand, the heating wire member 10 as described above has a structure insulated with the coating 4, the carbon yarn bundle (2) provided with a plurality of strands of thin wire overlapping, the non-resistive wire member 20 In addition, it has a structure in which the non-resistive conductive wire 12 provided with many thin wires twisted to the left is insulated by another coating 14.

In addition, the electromagnetic wave absorbing wire member 30 as described above also has another non-resistive wire 22 provided with a plurality of conductive wires twisted to the left as another coating material 24. 4) (14) (24) may each be silicone, teflon or flame retardant PVC.

In addition, the heating member 10, the non-resistive wire member 20 and the electromagnetic wave absorbing conductive member 30 may be formed in a structure wrapped by another coating 40, on the other hand, the electromagnetic wave absorbing conductive member 30 may be wound with a spiral pitch of 3 mm.

Example 2

Figure 7 shows another embodiment according to the present invention, as in '(Example 1)', consisting of the heating member 10, the non-resistance member 20 and the conductive member 30 for absorbing electromagnetic waves In order to insulate the nichrome wire bundle 6 and the nichrome wire bundle 6 provided with a plurality of conductive thin nichrome wires twisted to the left side, the nichrome wire bundle ( The other coating 8 which forms the outer shell of 6) is made.

Example 3

8 and 9 show yet another embodiment according to the present invention, as in (Example 1), the heating member 10, the non-resistance member 20 and the conductive member 30 for absorbing electromagnetic waves 30 The electromagnetic wave absorbing wire member 30 is a bundle of carbon wires formed by varnish in a form in which a plurality of conducting wires overlap each other and are spread in a predetermined width. The resistance wire member 20 is provided with a heating wire wound in a spiral form in one direction.

Example 4

The present invention provides a method of manufacturing an electromagnetic wave attenuating heating wire by twisting or winding the heating wire member 10, the non-resistive wire member 12, and the electromagnetic wave absorbing conductive wire member 30 (see FIGS. 10 to 12).

That is, as shown in Figure 10, the two wires ④ of the turning plate ③ through each of the heating wire member (10) and the non-resistive wire member 12, while rewinding from the wire bundle (① ② wound with a bobbin rotatably mounted to the lower portion of the turning plate ③ To the other bobbin via the pull roller ⑤ driven by the motor.

At this time, by turning the turning plate ③ together with the wire bundles ①②, the heating wire member 10 and the non-resistance wire member 12, which are rewound from the wire bundle ①②, are twisted in a spiral form in one direction, and the heating wire cut to an appropriate length. One end of the member 10 and the non-resistive wire member 12 are connected in series.

On the other hand, the heat-wire member 10 and the non-resistance wire member 12 prepared as twisted as described above is a bundle hole ⑧ of the electromagnetic wave absorption conductor member 30 is wound on another bobbin as shown in Figs. Penetrate through ⑨ to be wound on another bobbin via another pull roller ⑤ driven by another motor.

At this time, by rotating the spindle, the electromagnetic wave absorbing wire member 30 is wound in a spiral form on the heating wire member 10 and the non-resistive wire member 12, and the winding spiral pitch at this time is adjusted to 3 mm. It is desirable to.

In addition, the heating wire member 10, the non-resistive wire member 20, and the electromagnetic wave absorbing conductive member 30 may be further covered with another coating 40.

The heating wire according to the present invention as described above, it can be seen that it has the 'test results' characteristics as in the 'test report' of Table 1 ('test report' of the table 1 is 'Korea Electric' shown in Table 2 Certified by the Director of Electronic Testing & Research Institute).

Table 1

TABLE 2

TABLE 3

That is, as shown in Table 1, it can be seen that the magnetic field average detection value in the entire section and the plurality of positions is 616.84 [uG], and the electric field average detection value is 4.5839 [V / m]. As certified by the head of Quality Assurance Team of the Korea Electrical and Electronic Testing and Research Institute shown in Table 3, it can be seen that the condition is in a very good condition within the standard value (electric field: 10V / m or less, magnetic field: 2mG or less).

In addition, Table 4-1 is a graph showing the relationship between the magnetic field detection value measured a number of times in the entire heating line section, any one position and the frequency of these values according to the present invention, Table 4-2 As a graph of the graph, it can be seen that the maximum value of the magnetic field detection value is 620.32 [uG], and the maximum frequency at this time is 3.7881 Hz.

Table 4-1

4-2

In addition, Table 5-1 is a graph showing the relationship between the magnetic field detection value measured at multiple times in the entire heating line section, different locations and the frequency of these values according to the present invention, Table 5-2 is a graph of Table 5-1 By plotting, it can be seen that the maximum value of the magnetic field detection value is 593.65 [uG], and the maximum frequency at this time is 3.7796 Hz.

Table 5-1

Table 5-2

In addition, Table 6-1 is a graph showing the relationship between the magnetic field detection value measured a plurality of times in the entire heating line section, another position and the frequency for these values according to the present invention, Table 6-2 Graphing the graph, it can be seen that the maximum value of the magnetic field detection value is 626.28 [uG], and the maximum frequency at this time is 3.7925 Hz.

Table 6-1

Table 6-2

In addition, Table 7-1 is a graph showing the relationship between the magnetic field detection value measured at multiple times in the entire heating line section, another position and the frequency for these values according to the present invention, Table 7-2 Graphing the graph, it can be seen that the maximum value of the magnetic field detection value is 609.02 [uG], and the maximum frequency at this time is 3.7653 Hz.

Table 7-1

Table 7-2

In addition, Table 8-1 is a graph showing the relationship between the magnetic field detection value measured multiple times at the entire heating line section, another position and the frequency for these values according to the present invention, Table 8-2 Graphing the graph, it can be seen that the maximum value of the magnetic field detection value is 634.94 [uG], and the maximum frequency at this time is 3.7929 Hz.

Table 8-1

Table 8-2

In addition, Table 9-1 is a graph showing the relationship between the electric field detection value measured multiple times in the entire heating line section, one location and the frequency for these values according to the present invention, Table 9-2 Graphing the graph, it can be seen that the maximum value of the electric field detection value is 5.3649 [uG], and the maximum frequency at this time is 60.05 Hz.

Table 9-1

Table 9-2

In addition, Table 10-1 is a graph showing the relationship between the electric field detection value measured at multiple times in the entire heating line section, different locations according to the present invention and the frequency of these values, Table 10-2 is a graph of Table 10-1 By plotting the maximum value of the electric field detection value is 6.5026 [uG], it can be seen that the maximum frequency at this time is 59.963 Hz.

Table 10-1

Table 10-2

In addition, Table 11-1 is a graph showing the relationship between the electric field detection value measured several times at the entire heating line section, another position and the frequency for these values according to the present invention, Table 11-2 Graphing the graph, it can be seen that the maximum value of the electric field detection value is 1.3055 [uG], and the maximum frequency at this time is 59.958 Hz.

Table 11-1

Table 11-2

In addition, Table 12-1 is a graph showing the relationship between the electric field detection value measured at multiple times in the entire heating line section, different locations and the frequency for these values according to the present invention, Table 12-2 is a graph of Table 12-1 Table 2 shows that the maximum value of the electric field detection value is 3.4744 [uG] and the maximum frequency at this time is 60.025 Hz.

Table 12-1

Table 12-2

In addition, Table 13-1 is a graph showing the relationship between the electric field detection value measured multiple times at the entire heating line section, another position and the frequency for these values according to the present invention, Table 13-2 Graphing the graph, it can be seen that the maximum value of the electric field detection value is 6.2724 [uG], and the maximum frequency at this time is 60.026 Hz.

Table 13-1

Table 13-2

As described above, the present invention employs carbon yarns known to generate the least amount of electromagnetic waves as heating wires, twists them in the form of spirals in both directions, and winds non-resistance wires at a tight pitch. The blocking effect was shown to be superior, thereby providing the advantage that it is possible to minimize the harm caused by harmful electromagnetic waves on the human body.

1 is a perspective view for showing an example of the configuration of a conventional heating wire,

2 is a perspective view for illustrating another configuration example of a conventional heating wire;

3 is a perspective view for illustrating another configuration example of a conventional heating wire;

Figure 4a to 4c is a schematic view for showing a wiring structure of a conventional general heating wire,

5 is a schematic view for showing the wiring structure of the heating wire according to the present invention,

6 is a partial perspective view for illustrating a configuration of an embodiment of a heating wire according to the present invention;

7 is a partial cross-sectional view for showing a configuration of another embodiment of a heating wire according to the present invention;

8 is a partial perspective view for illustrating a configuration of another embodiment of a heating wire according to the present invention;

FIG. 9 is a partial cross-sectional view for illustrating a configuration of another embodiment of a heating wire according to the present invention as shown in FIG. 8.

10 to 12 are schematic diagrams of a device for showing a heating wire manufacturing process according to the present invention.

Explanation of symbols on the main parts of the drawings

10: heating wire member

20: resistive conductor member

30: electromagnetic wave absorbing wire member

Claims (9)

A heating member 10 formed to generate resistance heat due to a current applied in an insulated state; A non-resistive wire member 20 which is formed to be energized under an insulated state, is connected in series with the hot wire member 10, and is twisted in a spiral form in one direction with the hot wire member 10; It is formed so as to be energized in an insulated state, wound around the heating wire member 10 and the non-resistive wire member 20 in the form of a spiral in one direction, the both ends of the electromagnetic wave absorption conductor member 30; Electromagnetic attenuation heating line, characterized in that made. The method of claim 1, wherein the heating member 10, Carbon strands (2) provided with a plurality of strands overlapping; Electromagnetic attenuation heating line, characterized in that made of a coating (4) forming an outer shell of the carbon bundle (2) to insulate the carbon bundle (2). The method of claim 1, wherein the heating member 10, Nichrome wire bundle 6 provided with a plurality of conductive thin nichrome wire twisted in the left direction; Electromagnetic attenuation heating wire, characterized in that made of another coating (8) forming the outer shell of the nichrome wire bundle (6) to insulate the nichrome wire bundle (6). According to claim 1, wherein the non-resistive wire member 20, A non-resistive conductive wire 12 having a plurality of conductive thin lines twisted in a left direction; Electromagnetic attenuation heating wire, characterized in that made of another coating 14 to form an outer skin of the non-resistive conductor (12) to insulate the non-resistive conductor (12). The method of claim 1, wherein the electromagnetic wave absorption conductor member 30, Another non-resistive wire 22 having a plurality of conductive thin lines twisted in a left direction; Electromagnetic attenuation heating wire, characterized in that it is made of another coating (24) forming the outer skin of the non-resistive conductor (22) to insulate the other non-resistive conductor (22). The method of claim 1, wherein the electromagnetic wave absorption conductor member 30, Carbon wire bundles formed by varnish in a form in which a plurality of conductive thin wires are overlapped and spread in a predetermined width are wound and formed in a spiral form in one direction on the heating member 10 and the resistanceless member 20. Electromagnetic wave attenuation heating wire. The method of claim 1, wherein the heating member 10, the non-resistive wire member 20 and the electromagnetic wave absorbing wire member 30, the electromagnetic wave attenuation heating wire, characterized in that formed in a structure wrapped by another coating (40). . The method of claim 1, wherein the electromagnetic wave absorption conductor member 30, An electromagnetic wave attenuation heating wire, characterized by being wound with a spiral pitch of 3 mm. Twist the heating wire member 10 and the non-resistance wire member 12 in a spiral form in one direction, connect the heating wire member 10 and the non-resistance wire member 12 in series, and the heating wire member 10 and the non-resistance wire member. Winding the electromagnetic wave absorbing wire member 30 to secure a spiral pitch of 3 mm to (12), and the heating wire member 10 and the non-resistive wire member 20 and the electromagnetic wave absorbing wire member 30 is another The manufacturing method of the electromagnetic wave attenuation heating wire formed by wrapping with the coating | cover 40.