JP2021136303A - Sheet-like conductive path - Google Patents

Abstract

To reduce costs.SOLUTION: A sheet-like conductive path A includes: flexible sheet materials 10; transmission paths 20, 30 arranged side by side on the sheet materials 10; and noise shielding members 40 respectively provided at the sheet materials 10. The transmission paths 20, 30 include a first transmission path 20 needing noise shielding and a second transmission path 30 which does not need noise shielding. Each noise shielding member 40 is disposed only along the first transmission path 20 of the transmission paths 20, 30.SELECTED DRAWING: Figure 3

Description

The present disclosure relates to a sheet-shaped conductive path.

Patent Document 1 discloses an electric wire assembly in which a flat cable in which a plurality of electric wires are arranged and a noise shielding sheet are superposed. The noise shielding sheet suppresses the influence of electromagnetic noise on electric wires.

Japanese Unexamined Patent Publication No. 2016-120759

Since the above noise shielding sheet covers the entire surface of the flat cable, even electric wires that do not require electromagnetic noise countermeasures are covered with the noise shielding sheet. Therefore, the cost of the noise shielding sheet becomes high.
The sheet-shaped conductive path of the present disclosure has been completed based on the above circumstances, and an object of the present disclosure is to reduce costs.

The sheet-shaped conductive path of the present disclosure is
Flexible sheet material and
A plurality of transmission lines arranged side by side on the sheet material and
A noise shielding member provided on the sheet material is provided, and the sheet material is provided with a noise shielding member.
The plurality of transmission lines include a first transmission line that requires noise shielding and a second transmission line that does not require noise shielding.
The noise shielding member is arranged so as to be along only the first transmission line among the plurality of transmission lines.

According to the present disclosure, the cost can be reduced.

FIG. 1 is a plan view of the sheet-shaped conductive path of the first embodiment. FIG. 2 is an exploded perspective view of the sheet-shaped conductive path. FIG. 3 is a cross-sectional view of the sheet-shaped conductive path. FIG. 4 is a schematic side view of the double-shielded conductive path whose shield performance is to be measured. FIG. 5 is a schematic side view of a first comparative example, which is a measurement target of the shield performance. FIG. 6 is a schematic side view of a second comparative example, which is a measurement target of the shield performance. FIG. 7 is a schematic side view of a third comparative example, which is a measurement target of the shield performance. FIG. 8 is a schematic side view of a sixth comparative example, which is a measurement target of the shield performance. FIG. 9 is a schematic side view of a seventh comparative example, which is a measurement target of the shield performance. FIG. 10 is a graph showing the shield performance of the double-shielded conductive path, the single-shielded conductive path, and the first comparative example. FIG. 11 is a graph showing the shield performance of the single-shielded conductive path, the second comparative example, and the third comparative example. FIG. 12 is a graph showing the shield performance of the single-shielded conductive path, the fourth comparative example, and the fifth comparative example. FIG. 13 is a graph showing the shield performance of the single shield conductive path, the sixth comparative example and the seventh comparative example. FIG. 14 is a graph showing the shield performance of the single-shielded conductive path, the eighth comparative example and the ninth comparative example. FIG. 15 is a graph showing the shield performance of the single-shielded conductive path, the tenth comparative example and the eleventh comparative example. FIG. 16 is a graph showing the shield performance of the single-shielded conductive path, the twelfth comparative example and the thirteenth comparative example. FIG. 17 is a schematic side view of the 14th Comparative Example, the 15th Comparative Example, and the 16th Comparative Example. FIG. 18 is a graph showing the shield performance of the single-shielded conductive path, the 14th comparative example, the 15th comparative example, and the 16th comparative example.

[Explanation of Embodiments of the present disclosure]
First, the embodiments of the present disclosure will be listed and described.
The sheet-shaped conductive path of the present disclosure is
(1) A flexible sheet material, a plurality of transmission lines arranged side by side on the sheet material, and a noise shielding member provided on the sheet material are provided, and the plurality of transmission lines are noise shielded. The noise shielding member is arranged along only the first transmission line among the plurality of transmission lines, including a first transmission line that requires the above and a second transmission line that does not require noise shielding. According to the configuration of the present disclosure, since the noise shielding member is arranged only along the first transmission line that requires noise countermeasures among the plurality of transmission lines, the material cost of the noise shielding member can be reduced. ..

(2) The noise shielding member preferably has a sheet shape containing a magnetic material. According to this configuration, the electromagnetic noise generated from the first transmission line is absorbed by the magnetic loss of the magnetic material, and a high noise shielding effect can be obtained.

(3) It is preferable that the pair of noise shielding members are arranged so as to face each other with the first transmission line interposed therebetween. According to this configuration, a higher noise shielding effect can be obtained as compared with the case where noise countermeasures for transmission lines are taken with only one noise shielding member.

(4) It is preferable that the noise shielding member is arranged along only a part of the total length of the first transmission line. According to this configuration, the material cost of the noise shielding member can be reduced without reducing the noise shielding effect.

(5) In (4), the length dimension of the noise shielding member in the wiring direction of the first transmission line is preferably 500 mm or more. According to this configuration, a higher noise shielding effect can be obtained as compared with the case where the length of the noise shielding member is less than 500 mm.

(6) In (4) or (5), an electric circuit is connected to the end of the first transmission line, and the noise shielding member is the end of the first transmission line. It is preferably arranged only in the vicinity area. According to this configuration, the electromagnetic noise generated in the electric circuit is reflected toward the electric circuit side at the end of the first transmission line. Therefore, as compared with the case where the noise shielding member is arranged at the central portion in the length direction of the first transmission line, the influence of the electromagnetic noise generated in the electric circuit is less likely to reach the first transmission line.

(7) The noise shielding member has a sheet shape, and the thickness dimension of the noise shielding member is preferably 200 μm to 400 μm. According to this configuration, a high noise shielding effect can be obtained.

(8) The noise shielding member has a sheet shape having a constant width, and the width dimension of the noise shielding member is preferably 15 mm or more. According to this configuration, a high noise shielding effect can be obtained.

[Details of Embodiments of the present disclosure]
[Example 1]
Example 1 embodying the sheet-shaped conductive path A of the present disclosure will be described with reference to FIGS. 1 to 18. It should be noted that the present invention is not limited to these examples, and is indicated by the scope of claims, and is intended to include all modifications within the meaning and scope equivalent to the scope of claims. In the first embodiment, with respect to the vertical direction, the directions appearing in FIGS. 2 and 3 are defined as upward and downward as they are.

The sheet-shaped conductive path A of the first embodiment includes a pair of sheet materials 10, a first transmission line 20, a plurality of second transmission lines 30, a plurality of pairs of noise shielding members 40, and a plurality of sheets. It is configured to include a connector 45. The sheet-shaped conductive path A is attached to a vehicle body (not shown). Targets for attaching the sheet-shaped conductive path A in the body include a roof, a door panel, and the like. The sheet-shaped conductive path A is connected between, for example, an external antenna (not shown) attached to the roof and an ECU (electronic control unit).

The pair of sheet materials 10 are made of a flexible synthetic resin material. As the material of the sheet material 10, a resin material such as PVC (polyvinyl chloride) is used. As the resin material of the sheet material 10, a material having high welding strength with the sheath 27 of the first transmission line 20 and the insulating coating 32 of the second transmission line 30, which will be described later, is selected. As shown in FIG. 1, the sheet material 10 has one trunk line wiring portion 11 and a branch line wiring portion 12 protruding from the side edge portion of the trunk line wiring portion 11 in a branched shape. In the following description, it is assumed that the sheet material 10 is arranged horizontally for convenience.

As shown in FIG. 2, the first transmission line 20 and the second transmission line 30 are horizontally arranged between the pair of upper and lower sheet materials 10. As shown in FIG. 1, the first transmission line 20 has a trunk line portion 21 arranged along the trunk line wiring portion 11 and a branch line portion 22 arranged along the branch line wiring portion 12. Although omitted in FIG. 1, the second transmission line 30 also has a trunk line portion (not shown) arranged along the trunk line wiring portion 11 and a branch line portion arranged along the branch line wiring portion 12 (not shown). Omitted) and.

Since the first transmission line 20 is a conductive line of a communication circuit, it is composed of a coaxial cable. As shown in FIG. 3, the coaxial cable includes a conductor 24, a cylindrical insulator 25 surrounding the conductor 24, a shield layer 26 composed of a braided wire or the like surrounding the outer circumference of the insulator 25, and a shield layer 26. It has a cylindrical sheath 27 that surrounds it. The sheath 27 is made of PVC (polyvinyl chloride).

The first transmission line 20 transmits, for example, a signal received by an external antenna (not shown) attached to the roof to the ECU at a high speed of 1 Gbps or more. A high frequency current of 1 GHz or more flows through the first transmission line 20. High-frequency current causes common mode noise and the like. Therefore, regarding the first transmission line 20, a coaxial cable is used as a countermeasure against electromagnetic noise, and a noise shielding member 40 is provided in order to further improve the reliability of the noise countermeasure.

The second transmission line 30 surrounds the outer circumference of the core wire 31 with a cylindrical insulating coating 32. The insulating coating 32 is made of PVC (polyvinyl chloride) like the sheath 27 of the first transmission line 20. The second transmission line 30 is used as a conductive line for power supply and the like. No measures against electromagnetic noise are required for the second transmission line 30.

In the trunk line wiring portion 11 of the sheet material 10, the trunk line portion 21 of the first transmission line 20 and the trunk line portion (not shown) of the second transmission line 30 are arranged so as to be arranged in parallel with each other. In the branch line wiring portion 12, the branch line portion 22 of the first transmission line 20 and the branch line portion (not shown) of the second transmission line 30 are arranged so as to be parallel to each other, or the branch line of the first transmission line 20 is arranged. Only the part 22 is laid out, or only the branch line part (not shown) of the second transmission line 30 is laid out.

The noise shielding member 40 has a flexible sheet shape. As shown in FIG. 3, the noise shielding member 40 is a thin-film magnetic layer 41, a thin-film welding layer 42, and a thin-film protective layer 43 laminated in this order. The magnetic material layer 41 is obtained by dispersing and mixing powder made of a soft magnetic material such as ferrite, electromagnetic pure iron, and silicon iron in a synthetic resin. The magnetic material layer 41 converts high-frequency electromagnetic noise into heat and eliminates it due to magnetic loss. The magnetic material layer 41 is sandwiched between the welding layer 42 and the protective layer 43. In FIG. 3, for convenience, the thicknesses of the magnetic layer 41, the welding layer, and the protective layer 43 are exaggerated. The welding layer 42 is made of PVC (polyvinyl chloride) like the sheath 27 of the first transmission line 20 and the insulating coating 32 of the second transmission line 30. The protective layer 43 is made of PET (polyethylene terephthalate).

As shown in FIG. 1, the noise shielding member 40 has an elongated shape along the trunk line portion 21 and the branch line portion 22 of the first transmission line 20. The noise shielding member 40 is arranged only in the vicinity region of both ends of the trunk line portion 21 and the vicinity region of the extension end portion of the branch line portion 22 in the first transmission line 20. The noise shielding member 40 is not arranged in the region other than these. An electric circuit 46 such as an antenna or an ECU is connected to the connector 45 provided at the end of the first transmission line 20. The noise shielding member 40 is arranged in the vicinity of these electric circuits 46.

When manufacturing the sheet-shaped conductive path A, the first transmission line 20 and the second transmission line 30 are arranged on a horizontal jig (not shown) so as to be along a predetermined wiring path, and the first transmission line 20 and the second transmission line 30 are arranged on the horizontal jig (not shown). One sheet material 10 is placed on the sheet material 10, and a plurality of noise shielding members 40 are placed on the sheet material 10 so as to be overlapped with each other. At this time, the noise shielding member 40 is arranged so as to be along only both ends of the trunk line portion 21 and the extension ends of the branch line portion 22 in the wiring path of the first transmission line 20. In this state, ultrasonic welding is performed. In the ultrasonic welding step, the sheet material 10 and the sheath 27 of the first transmission line 20 are welded, the insulating coating 32 of the second transmission line 30 is welded to the sheet material 10, and the welding layer of the noise shielding member 40 is welded. 42 and the sheet material 10 are welded together.

The first transmission line 20, the second transmission line 30, one sheet material 10, and one noise shielding member 40 integrated as described above are turned upside down. Then, the other sheet material 10 is placed on the first transmission line 20 and the second transmission line 30, and the noise shielding member 40 is placed on the sheet material 10 so as to be overlapped with each other. Also at this time, the noise shielding member 40 is arranged so as to be along only both ends of the trunk line portion 21 and the extension ends of the branch line portion 22 in the distribution path of the first transmission line 20. After that, ultrasonic welding is performed in the same manner as described above, and the first transmission line 20, the second transmission line 30, the other sheet material 10 and the other noise shielding member 40 are fixed and integrated. As described above, the sheet-shaped conductive path A is completed.

Next, the shielding performance when the shielding form was different was measured by a triaxial measuring method based on IEC62153-4-4. The measurement targets are the first comparative example to the 16th comparative example in which the arrangement and dimensions of the double-shielded conductive path W, the single-shielded conductive path S, and the noise shielding member 40 are different. The double-shielded conductive path W is provided with a noise shielding member 40 having a magnetic material layer 41 having the same dimensions as the magnetic material layer 41 of the first embodiment in a first transmission line 20 made of the same coaxial cable as in the first embodiment. Is. The single-shielded conductive path S performs noise shielding only by the shield layer 26 of the coaxial cable of the first embodiment without providing the noise shielding member 40.

FIG. 4 is a schematic side view of the double-shielded conductive path W. In the double-shielded conductive path W, a pair of noise-shielding members 40 are provided so as to sandwich the first transmission path 20. Hereinafter, the arrangement form in which the pair of noise shielding members 40 sandwich the first transmission line 20 is referred to as “double-sided arrangement”. The pair of noise shielding members 40 are arranged at both ends of the first transmission line 20. Hereinafter, the form in which the noise shielding member 40 is arranged at both ends of the first transmission line 20 is referred to as “both ends arrangement”. The length dimension of the magnetic material layer 41 in the wiring direction of the first transmission line 20 is 500 mm. The thickness dimension of the magnetic material layer 41 is 200 μm. The width dimension of the magnetic material layer 41 is 15 mm.

FIG. 5 is a schematic side view of the first Comparative Example C1. In the first comparative example C1, the noise shielding member 40 arranged on both sides is arranged at the central portion in the length direction of the first transmission line 20. Hereinafter, the form in which the noise shielding member 40 is arranged in the central portion in the length direction is referred to as “center arrangement”. The dimension of the magnetic material layer 41 of the noise shielding member 40 is the same as the dimension of the double shield conductive path W.

FIG. 10 is a graph showing the shielding performance of the double-shielded conductive path W, the shielding performance of the single-shielded conductive path S, and the shielding performance of the first comparative example C1. From the graph of FIG. 10, the shielding performance of the double-shielded conductive path W is superior to the shielding performance of the single-shielded conductive path S. On the other hand, the shielding performance of the first comparative example C1 is generally the same level as that of the single-shielded conductive path S. Therefore, the shielding performance of both ends arrangement is superior to the shielding performance of the central arrangement.

FIG. 6 is a schematic side view of the second comparative example C2. In the second comparative example C2, both ends are arranged, but at each end, only one noise shielding member 40 is arranged along the first transmission line 20. Hereinafter, a form in which only one noise shielding member 40 is arranged along the first transmission line 20 is referred to as “single-sided arrangement”. FIG. 7 is a schematic side view of Third Comparative Example C3. In the third comparative example C3, the noise shielding member 40 arranged on one side is arranged in the center.

The graph of FIG. 11 shows the shielding performance of the single-shielded conductive path S, the shielding performance of the second comparative example C2, and the shielding performance of the third comparative example C3. As shown in the graph of FIG. 11, the shielding performance of the second comparative example C2 arranged at both ends is generally at the same level as the shielding performance of the single-shielded conductive path S. On the other hand, the shield performance of the third comparative example C3 arranged in the center is lower than the shield performance of the single shield conductive path S and the shield performance of the second comparative example C2. From the graph shown in FIG. 11, it can be seen that the shielding performance at both ends is superior to the shielding performance at the center.

The graph of FIG. 12 shows the shielding performance of the single-shielded conductive path S, the shielding performance of the fourth comparative example C4, and the shielding performance of the fifth comparative example C5. The fourth comparative example C4 has the same double-sided arrangement and both ends arrangement as the double-shielded conductive path W, but the length of the magnetic material layer 41 is 250 mm. In the fifth comparative example C5, the length of the magnetic material layer 41 is changed to 250 mm as in the fourth comparative example C4 in the first comparative example C1 arranged on both sides and in the center.

As shown in the graph of FIG. 12, the shielding performance of the fourth comparative example C4 arranged at both ends is superior to the shielding performance of the single-shielded conductive path S in the high frequency band of 2.5 GHz to 3.0 GHz. On the other hand, the shield performance of the fifth comparative example C5 arranged in the center is generally the same level as the shield performance of the single shield conductive path S. From the graph of FIG. 12, it can be seen that if the length of the magnetic material layer 41 is shortened to about 250 mm, there is no significant difference in the shielding performance between the both end arrangement and the center arrangement.

FIG. 8 is a schematic side view of the sixth comparative example C6. In the sixth comparative example C6, the noise shielding member 40 arranged on both sides is provided only at the end of the first transmission line 20 on the side close to the electric circuit 46 which is the noise source. Hereinafter, a form in which the noise shielding member 40 is arranged only at one end of both ends of the first transmission line 20 is referred to as “single end arrangement”. FIG. 9 is a schematic side view of the seventh comparative example C7. The seventh comparative example C7 is also arranged on both sides and at one end like the sixth comparative example C6, but in the seventh comparative example C7, contrary to the sixth comparative example C6, of both ends of the first transmission line 20. The noise shielding member 40 is provided only at the end on the side far from the electric circuit 46 that is the source of noise. The length of the magnetic layer 41 is 500 mm.

The graph of FIG. 13 shows the shielding performance of the single-shielded conductive path S, the shielding performance of the sixth comparative example C6, and the shielding performance of the seventh comparative example C7. According to this graph, it can be seen that the shielding performance is superior when the noise shielding member 40 is arranged on the side closer to the noise generation source than when the noise shielding member 40 is arranged on the side far from the noise generation source.

The graph of FIG. 14 shows the shielding performance of the single-shielded conductive path S, the shielding performance of the eighth comparative example C8, and the shielding performance of the ninth comparative example C9. Both the eighth comparative example C8 and the ninth comparative example C9 are arranged on both sides and on one end. The difference between the 8th Comparative Example C8 and the 9th Comparative Example C9 is that the length of the magnetic material layer 41 of the 8th Comparative Example C8 is 500 mm, whereas the length of the magnetic material layer 41 of the 9th Comparative Example C9 is It is 250 mm. From the graph of FIG. 14, it can be seen that the longer the magnetic material layer 41 is, the better the shielding performance is.

The graph of FIG. 15 shows the shielding performance of the single-shielded conductive path S, the shielding performance of the tenth comparative example C10, and the shielding performance of the eleventh comparative example C11. Both the tenth comparative example C10 and the eleventh comparative example C11 are arranged on both sides and arranged on both ends. In the tenth comparative example C10, the length of the magnetic material layer 41 at each end of the first transmission line 20 is 750 mm, and the total length of both ends is 1500 mm. In the eleventh comparative example C11, the length of the magnetic material layer 41 at each end of the first transmission line 20 is 250 mm, and the length of 500 mm is secured when both ends are combined. According to the graph of FIG. 15, it can be seen that there is no significant difference between the shielding performance of the tenth comparative example C10 and the shielding performance of the eleventh comparative example C11 in the high frequency band. Therefore, it can be seen that if the total length of the magnetic material layer 41 in one first transmission line 20 is 500 mm, a sufficient noise shielding effect can be obtained.

The graph of FIG. 16 shows the shielding performance of the single-shielded conductive path S, the shielding performance of the twelfth comparative example C12, and the shielding performance of the thirteenth comparative example C13. Both the twelfth comparative example C12 and the thirteenth comparative example C13 are arranged on both sides and both ends. The length of the magnetic material layer 41 at each end of the first transmission line 20 is 250 mm, and a total length of 500 mm is secured when both ends are combined. In the twelfth comparative example C12, the thickness of each magnetic material layer 41 is 200 μm, whereas in the thirteenth comparative example C13, the thickness of each magnetic material layer 41 is 100 μm. According to the graph of FIG. 16, it can be seen that the twelfth comparative example C12 having the thick magnetic material layer 41 is superior in the shielding performance to the thirteenth comparative example C13 having the thin magnetic material layer 41.

FIG. 17 is a cross-sectional view of the 14th Comparative Example C14, the 15th Comparative Example C15, and the 16th Comparative Example C16. The 14th Comparative Example C14, the 15th Comparative Example C15, and the 16th Comparative Example C16 are all arranged on both sides and both ends. The length of the magnetic material layer 41 at each end is 250 mm for all Comparative Examples C14, C15, and C16. The thickness of each magnetic layer 41 is 200 μm in each of Comparative Examples C14, C15, and C16. Regarding the width dimension of the magnetic layer 41, the 14th Comparative Example C14 is 15.0 mm, the 15th Comparative Example C15 is 10.0 mm, and the 16th Comparative Example C16 is 7.5 mm.

The graph of FIG. 18 shows the shielding performance of the single-shielded conductive path S, the shielding performance of the 14th Comparative Example C14, the shielding performance of the 15th Comparative Example C15, and the shielding performance of the 16th Comparative Example C16. As shown in the graph of FIG. 18, the shielding performance of the 15th Comparative Example C15 in which the width of the magnetic material layer 41 is 10.0 mm and the 16th Comparative Example C16 in which the width of the magnetic material layer 41 is 7.5 mm is single shield conductive. It is generally the same level as the shield performance of the road S. On the other hand, the shielding performance of the 14th Comparative Example C14 in which the width of the magnetic layer 41 is 10.0 mm is superior to the shielding performance of the single shield conductive path S, the 15th Comparative Example C15 and the 16th Comparative Example C16. You can see that there is.

The sheet-shaped conductive path A of the first embodiment has a flexible sheet material 10, a plurality of transmission lines 20 and 30 arranged side by side on the sheet material 10, and a noise shielding member provided on the sheet material 10. 40 and. The plurality of transmission lines 20 and 30 include a first transmission line 20 that requires noise shielding and a second transmission line 30 that does not require noise shielding. The noise shielding member 40 is arranged along only the first transmission line 20 among the plurality of transmission lines 20 and 30. Since the noise shielding member 40 is arranged only along the first transmission line 20 that requires noise countermeasures among the plurality of transmission lines 20 and 30, the noise shielding member 40 is provided along all the transmission lines 20 and 30. The material cost of the noise shielding member 40 can be reduced as compared with the case where the noise shielding member 40 is provided.

The magnetic material layer 41 constituting the noise shielding member 40 is preferably in the form of a sheet containing a magnetic material. The electromagnetic noise generated from the first transmission line 20 is absorbed by the magnetic loss of the magnetic material. Thereby, a high noise shielding effect can be obtained. The pair of noise shielding members 40 are arranged so as to sandwich the first transmission line 20, and face each other in a direction orthogonal to the wiring direction of the first transmission line 20. Compared with the case where the noise countermeasure of the first transmission line 20 is taken only by one noise shielding member 40, the form in which the first transmission line 20 is sandwiched between the pair of noise shielding members 40 can obtain a higher noise shielding effect. can.

The noise shielding member 40 is arranged along only a part of the total length of the first transmission line 20. The magnetic material layer 41 constituting the noise shielding member 40 is elongated along the wiring direction of the first transmission line 20. The length dimension of the magnetic material layer 41 is 500 mm or more. According to this configuration, the material cost of the noise shielding member 40 can be reduced without reducing the noise shielding effect. Further, a higher noise shielding effect can be obtained as compared with the case where the length of the noise shielding member 40 is less than 500 mm.

An electric circuit 46 is connected to the end of the first transmission line 20. The noise shielding member 40 is arranged only in a region near the end of the first transmission line 20. According to this configuration, the electromagnetic noise generated in the electric circuit 46 is reflected toward the electric circuit 46 side at the end of the first transmission line 20. Therefore, as compared with the case where the noise shielding member 40 is arranged at the central portion in the length direction of the first transmission line 20, the influence of the electromagnetic noise generated in the electric circuit 46 is less likely to reach the first transmission line 20.

The magnetic material layer 41 of the noise shielding member 40 has a sheet shape. Since the thickness dimension of the magnetic material layer 41 is 200 μm to 400 μm, a high noise shielding effect can be obtained. The magnetic material layer 41 of the noise shielding member 40 is in the form of a sheet having a constant width. Since the width dimension of the magnetic material layer 41 is 15 mm or more, a high noise shielding effect can be obtained.

[Other Examples]
The present invention is not limited to the examples described in the above description and drawings, but is shown by the scope of claims. The present invention includes the meaning equivalent to the scope of claims and all modifications within the scope of claims, and is intended to include the following embodiments.
In the above embodiment, the first transmission line is a coaxial cable, but the first transmission line may be a twisted pair line.
In the above embodiment, the noise shielding member has a fixed width sheet shape, but the noise shielding member may have a linear shape.
In the above embodiment, the material of the sheath of the first transmission line is PCV (polyvinyl chloride), but the material of the sheath may be other than PVC.
In the above embodiment, the material of the welding layer of the noise shielding member is PCV (polyvinyl chloride), but the material of the welding layer may be other than PVC.

A ... Sheet-shaped conductive path S ... Single-shielded conductive path W ... Double-shielded conductive path 10 ... Sheet material 11 ... Trunk line wiring section 12 ... Branch line wiring section 20 ... First transmission line 21 ... Trunk line section 22 ... Branch line section 24 ... Conductor 25 ... Insulator 26 ... Shield layer 27 ... Sheath 30 ... Second transmission line 31 ... Core wire 32 ... Insulation coating 40 ... Noise shielding member 41 ... Magnetic material layer 42 ... Welding layer 43 ... Protective layer 45 ... Connector 46 ... Electric circuit

Claims (8)

Flexible sheet material and
A plurality of transmission lines arranged side by side on the sheet material and
A noise shielding member provided on the sheet material is provided, and the sheet material is provided with a noise shielding member.
The plurality of transmission lines include a first transmission line that requires noise shielding and a second transmission line that does not require noise shielding.
The noise shielding member is a sheet-shaped conductive path arranged along only the first transmission line among the plurality of transmission lines. The sheet-shaped conductive path according to claim 1, wherein the noise shielding member is in the form of a sheet containing a magnetic material. The sheet-shaped conductive path according to claim 1 or 2, wherein the pair of noise shielding members are arranged so as to face each other with the first transmission path interposed therebetween. The sheet-shaped conductive path according to any one of claims 1 to 3, wherein the noise shielding member is arranged along only a part of the total length of the first transmission line. The sheet-shaped conductive path according to claim 4, wherein the length dimension of the noise shielding member in the wiring direction of the first transmission line is 500 mm or more. An electric circuit is connected to the end of the first transmission line.
The sheet-shaped conductive path according to claim 4 or 5, wherein the noise shielding member is arranged only in a region near the end of the first transmission line. The noise shielding member has a sheet shape and is in the form of a sheet.
The sheet-shaped conductive path according to any one of claims 1 to 6, wherein the noise shielding member has a thickness dimension of 200 μm to 400 μm. The noise shielding member is in the form of a sheet having a constant width.
The sheet-shaped conductive path according to any one of claims 1 to 7, wherein the width dimension of the noise shielding member is 15 mm or more.

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