KR20200000316A - Twist type high-frequency power cable - Google Patents

Abstract

The present invention relates to a technique for improving a structure of an extension line connecting an alternating current power supply and a track cable to minimize a magnetic field formed around the alternating currents flowing through the extension line, and for blocking the generation of induced currents in the extension line by offsetting magnetic fields generated from a plurality of cables arranged to flow alternating currents in opposite directions in the extension line. In particular, the present invention relates to a technique for easily arranging each cable while overcoming a proximity effect between a plurality of cables arranged so that the alternating currents flow from the inside of the extension line in opposite directions. According to the present invention, there is an advantage in that the extension line having paired cables A and B can be easily produced.

Description

Twist type high-frequency power cable

The present invention relates to a technique for minimizing the magnetic field formed around the alternating current flowing through the extension line by improving the structure of the extension line connecting the AC power supply and the track cable.

More specifically, the present invention relates to a technique for blocking the generation of induction current in the extension line by canceling each other magnetic fields generated from a plurality of cables arranged to flow in the opposite direction in the extension line.

In particular, the present invention relates to a technique that can easily arrange each cable while overcoming the proximity effect between the plurality of cables arranged so that alternating current flows in the opposite direction inside the extension line.

In general, OHT (Overhead Hoist Transfer) devices are widely used in production lines of semiconductors and OLEDs. The OHT is installed on the ceiling of the production line and is connected to a so-called 'coupler' that is wirelessly powered.

1 is an exemplary diagram of a wireless power supply system using a high frequency cable. Referring to FIG. 1, the coupler 12 moving along the track cable 13b is wirelessly powered from the track cable 13b.

To this end, the track cable 13b is connected to the inverter 11 which is a power supply and receives alternating current from the inverter 11.

In addition, the track cable 13b and the inverter 11 are connected through an extension line 13a. An extension line 13a through which the track cable 13b having an endless track shape is energized is disposed close to the inverter 11.

As a result, the magnetic field generated by the alternating current flowing through the extension line 13a affects the components of the inverter 11. To solve this, it is necessary for the extension line 13a to bind the alternating current flowing in opposite directions to one cable and cancel the magnetic field generated by the respective opposite alternating current.

2 is an exemplary view showing a coaxial type high frequency power cable according to the prior art. Referring to FIG. 2, the high-frequency power cable, which is an extension line, is configured such that the insulating sheath 23 receives a plurality of cables and conductors inside thereof.

That is, the magnetic field formed by the plurality of cables A (21) and the plurality of cables A (21) flowing through the alternating direction of the outgoing direction and the plurality of cables (B) 22 through the alternating direction of the entering direction are arranged coaxially The magnetic fields formed by the cables B 22 of C are canceled with each other.

As such, since no magnetic field is generated in the insulation shell 23 and the insulation shell 24, the induced current does not occur. As a result, even when the thermal wire 26 is adopted as a normal metal other than an expensive material such as ferrite, the thermal wire 26 does not generate induction current by the plurality of cables A, B (21, 22). You won't generate heat yourself.

However, in the case of the coaxial type as shown in FIG. 2, the effective cross-sectional area occupied by the plurality of cables B 22 disposed at the center due to proximity effect occupies the plurality of cables A 21 arranged at the outer side. Less than the effective cross-sectional area.

As a result, the phenomenon that the alternating current density of the direction which the some cable B 22 flows in becomes high arises.

In order to solve the imbalance between the central part and the outer part due to the proximity effect, the cross-sectional area occupied by the plurality of cables A 21 arranged at the outer side must be increased to increase the plurality of cables A 21 and the plurality of cables B 22. The magnetic field formed by) can be exactly canceled out.

As such, manufacturing a high frequency power cable to be used for the extension line 13a on [FIG. 1] in the coaxial type as shown in FIG.

3 is an exemplary view showing a conventional non-twist type high frequency power cable.

Referring to FIG. 3, the high-frequency power cable, which is an extension line, may be configured such that the insulation jacket 33 receives a plurality of cables and conductors inside thereof, in which case the cable A flowing AC in different directions, B (31, 32) is shown in a non-twisted state paired one by one.

In the case of FIG. 3, the cables A, B (31, 32) flowing in alternating directions in different directions have the worst arrangement in which the cables are twisted non-twisted one by one.

For example, unlike the coaxial type of FIG. 2, in the case of [FIG. 3], since the number of strands of the cables having different AC directions is the same, when the magnetic field is not canceled, the proximity effect is adopted to overcome the proximity effect. There is a problem that there is no way to add the outer cable A (31).

Accordingly, there is a demand for the implementation of a technology that can solve the above conventional problem by simply arranging each cable while overcoming the proximity effect between a plurality of cables arranged so that alternating current flows in the opposite direction inside the extension line. It is becoming.

The present invention has been proposed in view of the above, and an object of the present invention is to generate an induced current in an extension line by canceling each other magnetic fields generated from a plurality of cables arranged to flow in opposite directions in the extension line. It is to provide a twist type high frequency power cable to block the.

In addition, an object of the present invention is to provide a twist-type high-frequency power cable that can easily arrange each cable while overcoming the proximity effect between the plurality of cables arranged to flow alternating current in the opposite direction inside the extension line In providing.

In order to achieve the above object, a twist-type high frequency power cable according to the present invention includes a plurality of cables A (110) each of which is surrounded by an insulation coating and flows AC independently from an adjacent cable; A plurality of cables B 120 which are respectively surrounded by an insulating coating to flow alternatingly with adjacent cables and flow alternatingly in the opposite direction to the cable A and are arranged in a twisted structure with each of the cables A; It is configured to include; insulation jacket 130 for receiving a plurality of cables A and a plurality of cables B inside.

At this time, the cable A and the cable B is preferably paired in the same number and arranged in a twisted structure.

In addition, the two strands of the thermal conductor 141 are each twisted in contact with each other in a state in which they are covered with the fusion coating 142, and are provided with one or more inside of the insulation shell to be melted by heat generated by at least one of the cable A and the cable B. When the coating is melted, the thermal wires 140, in which two strands of the thermal conductors are short-circuited to each other, may be further configured.

In addition, the thermal lines 140 may be arranged symmetrically with respect to the center portion of the cross-section of the insulating envelope.

On the other hand, as a long extending in the longitudinal direction of the insulating sheath in the central portion of the cross-section of the insulating sheath, the dummy member 150 for supporting the cable A, cable B, the thermal wire in the insulating sheath; may be further included.

According to the present invention, the arrangement of the plurality of cables A and the plurality of cables B in a twisted structure mutually cancels the magnetic fields generated from the respective cables A and B, thereby minimizing the generation of induced currents in the adjacent portions.

In addition, the present invention, as a plurality of cable A and a plurality of cable B by the same number of pairs arranged in a twisted structure to overcome the proximity effect between the plurality of cables (extensions) having each paired cable A, B The advantages of simplicity of production.

1 is an illustration of a wireless power supply system using a high frequency cable,
Figure 2 is an illustration showing a coaxial type high frequency power cable of the prior art,
3 is an exemplary view showing a conventional non-twist type high frequency power cable;
4 is an exemplary view showing a twist type high frequency power cable according to the present invention;
5 is an exemplary view showing a twist type high frequency power cable according to the present invention.

1 is an exemplary diagram of a wireless power supply system using a high frequency cable. Referring to FIG. 1, the coupler 12 moving along the track cable 13b is wirelessly powered from the track cable 13b.

To this end, the track cable 13b is connected to the inverter 11 which is a power supply device as a high frequency power cable and receives alternating current from the inverter 11.

In addition, the track cable 13b and the inverter 11 are connected through an extension line 13a which is a high frequency power cable, and the extension line 13a that is energized with the track cable 13b having an endless track shape is disposed close to the inverter 11. Therefore, the influence of the magnetic field generated from the alternating current flowing through the extension line 13a on the inverter 11 must be eliminated.

That is, it is necessary to bind the alternating currents flowing opposite to each other to the extension line 13a, which is a high-frequency power cable, in one cable to cancel the magnetic field generated by the opposite alternating currents.

The present invention is a twist type high frequency power cable corresponding to the extension line 13a, which will be described below in detail with reference to the accompanying drawings.

4 is an exemplary view showing a twist type high frequency power cable according to the present invention, and FIG. 5 is an exemplary view showing a twist type high frequency power cable according to the present invention.

4 and 5, the twist type high frequency power cable according to the present invention includes a cable A 110, a cable B 120, an insulation jacket 130, a thermal wire 140, and a dummy member. And 150.

Cable A (110) is provided with a plurality as shown in [4] and [5], each surrounded by an insulating coating to flow alternating current independently of the adjacent cable.

In addition, the cable A 110 is indicated by the flow of alternating current in the direction of exit in FIGS. 4 and 5.

Cable B (120) is provided with a plurality as shown in [4] and [5], each surrounded by an insulating coating to flow alternatingly with the adjacent cable independently of the cable A (110) in the opposite direction (entering direction) Flowing alternating current is arranged in a twisted structure with each cable A (110).

In this way, the cable A 110 and the cable B 120 as the extension line 13a of FIG. 1 are connected to the track cable 13b having an endless track shape in FIG. 1 only when AC flows in different directions. You can flow.

The insulating jacket 130 accommodates the plurality of cables A 110 and the plurality of cables B 120 inside, as shown in FIGS. 4 and 5.

As described above, since the plurality of cables A 110 and the plurality of cables B 120 are paired with each other to form a twisted structure, the alternating current density represented by the plurality of cables A 110 and the alternating current represented by the plurality of cables B 120 are represented. The density is the same.

As a result, a plurality of cable A 110 and a plurality of cable B 120 paired with each other cable the cable of the same specification without difficulty to consider the effective area of the inner line and the outer line to overcome the proximity effect in the existing coaxial type. A 110 and the cable B 120 can be utilized.

That is, it is easy to produce a twist type high frequency power cable as shown in FIG. 4 that does not cause a problem due to the proximity effect.

4 and 5 illustrate a case in which the cable A 110 and the cable B 120 are paired in a one-to-one manner, and the cable A 110 and the cable B 120 are 2 × 2, 3. The same number of pairs, such as × 3, may be arranged in a twisted structure.

The thermal wire 140 is twisted in contact with each other in a state in which the two thermal conductor wires 141 are covered with the fusion coating 142 as shown in [FIG. 4] and [FIG. 5], and the insulating jacket 130 When one or more inside of the cable A (110) and the cable B (120) is melted fusion coating 142 due to any one or more heat generated by the two strands of the thermal conductor 141 is stuck together and short-circuited.

In addition, the thermal lines 140 may be arranged symmetrically with respect to the central portion of the cross section of the insulating jacket 130.

Here, the two strands of the thermal conductor 141 having a mutual twisted structure in a state surrounded by the fusion coating 142 is accommodated in the insulating shell 143 on the outer side, even when the fusion coating 142 is melted and the other configuration of the outside It can remain insulated.

As described above, the magnetic field generated from the cables A, B (110, 120) in the insulating jacket 130 according to the twisted structure in which the plurality of cables A (110) and the plurality of cables (B 120) are paired with the same number. As mutually canceled, it is possible to prevent the generation of induced current by the plurality of cable A (110) and the plurality of cable B (120) in the thermal line 140.

As a result, since the thermal wire 140 does not generate heat by itself by the alternating current of the plurality of cable A 110 and the plurality of cable B 120, the plurality of cable A 110 and the plurality of cable B ( It is possible to properly detect the heating state of the 120).

As the dummy member 150 extends along the longitudinal direction of the insulating jacket 130 at the central portion of the cross section of the insulating jacket 130 as shown in FIGS. 4 and 5, the cable A in the insulating jacket 130 is formed. 110, the cable B 120, and the thermal wire 140 may be supported.

On the other hand, the cable A (110) and the cable B (120) shown in the upper portion of FIG. 5 is conceptually illustrated by extracting only one pair of a plurality of pairs disposed in the insulating jacket (130).

And, the arrangement structure of the cable A (110) and the cable B (120) shown in the lower portion of [5] conceptually shows the cross-section at each of the (A) position, (B) position, (C) position Since it will actually be randomly arranged, it will show a layout structure close to that of FIG.

11: inverter
12: coupler
13a: extension line
13b: track cable
21: cable A
22: cable B
23: insulation jacket
24: insulation inner shell
25: core
26: heat ray
31: cable A
32: cable B
33: insulation jacket
34: core
35: heat ray
110: cable A
120: cable B
130: insulation jacket
140: heat ray
141: thermal conductor
142: Fusion Cover
143: insulation jacket
150: dummy member

Claims (5)

A plurality of cables A (110) each surrounded by an insulating coating and flowing alternating current with adjacent cables;
A plurality of cables B 120 each surrounded by an insulating coating to flow alternating currents adjacent to the adjacent cables and flow alternating currents in the opposite direction to the cable A, and arranged in a mutually twisted structure with each of the cables A;
An insulation jacket 130 accommodating the plurality of cables A and the plurality of cables B therein;
High frequency power cable of the twist type configured to include.
The method according to claim 1,
Twisted-type high-frequency power cable, characterized in that the cable A and the cable B are paired in the same number and arranged in a twisted structure.
The method according to claim 2,
The two strands of thermal conductor 141 are twisted in contact with each other in a state in which they are respectively covered with a fusion coating 142 and are provided with at least one inside of the insulation shell to generate heat of at least one of the cable A and the cable B. A thermal wire 140 in which two strands of the thermal conductor are shorted to each other when the fusion coating is melted;
Twisted-type high-frequency power cable, characterized in that it further comprises.
The method according to claim 3,
The thermal wire 140 is a twist-type high-frequency power cable, characterized in that arranged mutually symmetrical with respect to the center of the cross-section of the insulated jacket.
The method according to claim 4,
A dummy member 150 for supporting the cable A, the cable B, and the thermal wire in the insulating jacket as it is formed to extend in a longitudinal direction of the insulating jacket at a central portion of the cross section of the insulating jacket;
Twisted-type high-frequency power cable, characterized in that it further comprises.

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