JP2022108845A - wire harness - Google Patents

Abstract

To enable bending performance of a wire harness to be adjusted in a plurality of sections respectively.SOLUTION: A wire harness 20 comprises: a first connector 22; a second connector 24; a plurality of electric wires 30 through which the first connector 22 is electrically connected to the second connector 24; a first corrugate tube 32 that covers the plurality of electric wires 30, in a first section E1 between the first connector 22 and the second connector 24; and a second corrugate tube 34 that covers the plurality of electric wires 30, in a second section E2 between the first corrugate tube 32 and the second connector 24. A filling factor in the first corrugate tube 32 is different from a filling factor in the second corrugate tube 34.SELECTED DRAWING: Figure 1

Description

The present disclosure relates to wire harnesses.

Patent Literature 1 discloses a technique of separating two corrugated tubes from each other in order to branch a part of a wire bundle that is a main trunk line, and pulling out some wires (branch wires) from the wire bundle at the separated portion. ing.

JP 2010-154665 A

Here, it is required to adjust the bendability of the wire harness by dividing it into a plurality of sections. The bendability is the ease with which a wire harness is bent, and can be evaluated, for example, by the magnitude of the force required to bend the wire harness.

Accordingly, an object of the present disclosure is to enable adjustment of the bendability of a wire harness by dividing it into a plurality of sections.

A wire harness of the present disclosure includes a first connector, a second connector, a plurality of electric wires electrically connecting the first connector and the second connector, and a wire between the first connector and the second connector. A first corrugated tube that covers the plurality of wires in the first section of and a second corrugated tube that covers the plurality of wires in the second section between the first corrugated tube and the second connector The wire harness, wherein the filling rate in the first corrugated tube is different from the filling rate in the second corrugated tube.

According to the present disclosure, the bendability of the wire harness can be adjusted by dividing it into a plurality of sections.

FIG. 1 is a plan view showing a wire harness according to Embodiment 1. FIG. FIG. 2 is a cross-sectional view taken along line II--II of FIG. FIG. 3 is a cross-sectional view taken along line III--III of FIG. FIG. 4 is a plan view showing a wire harness according to a modification. FIG. 5 is a plan view showing a wire harness according to Embodiment 2. FIG. FIG. 6 is a sectional view taken along line VI-VI of FIG. FIG. 7 is a cross-sectional view taken along line VII-VII of FIG. FIG. 8 is an explanatory diagram showing a state in which the wire harness is fixed to the placement target.

[Description of Embodiments of the Present Disclosure]
First, the embodiments of the present disclosure are listed and described.

The wire harness of the present disclosure is as follows.

(1) a first connector, a second connector, a plurality of electric wires electrically connecting the first connector and the second connector, and a first section between the first connector and the second connector a first corrugated tube covering the plurality of electric wires; and a second corrugated tube covering the plurality of electric wires in a second section between the first corrugated tube and the second connector; A wire harness in which the filling rate in one corrugated tube is different from the filling rate in the second corrugated tube.

According to this wire harness, since the first corrugated tube and the second corrugated tube have different filling rates, the first section and the second section have different flexibility. Therefore, the bendability of the wire harness can be adjusted by dividing it into a plurality of sections.

(2) In the wire harness of (1), the filling rate of the second corrugated tube may be higher than the filling rate of the first corrugated tube. This makes it easier to bend the first section than the second section.

(3) In the wire harness according to the aspect (2), the inner diameter of the first corrugated tube may be larger than the inner diameter of the second corrugated tube. Thereby, the filling rate can be easily varied between the first corrugated tube and the second corrugated tube.

(4) In the wire harness according to the aspect (2) or (3), the first tape wound around the first corrugated tube and the winding method of the first tape are different, and a second tape wrapped around the corrugated tube. In this manner, by changing the winding method of the first tape and the second tape between the first corrugated tube and the second corrugated tube, the flexibility can be further adjusted.

(5) In the wire harness according to any one aspect of (2) to (4), in a state where the first section is bent to draw a smaller radius of curvature than the second section, the arrangement target It may be fixed to the body. In this case, the first section is easier to bend than the second section. Therefore, the first section is easily fixed to the placement object while being bent so as to draw a radius of curvature smaller than that of the second section.

(6) In the wire harness according to any one aspect of (1) to (5), when the plurality of wires are a group of first wires, the first wires in the first section a group of a plurality of second wires housed in the first corrugated tube together with a group of; and a third connector electrically connected to the first connector by the group of the second wires; The group of first electric wires and the group of second electric wires are branched at a branch portion between the first section and the second section, and a third section is provided between the branch section and the third connector. WHEREIN: You may further provide the 3rd corrugated tube which covers the group of said 2nd electric wire. In this case, in the wire harness in which the group of the first wires and the group of the second wires branch at the branching portion, the flexibility of the wire harness can be adjusted by dividing it into a plurality of sections.

(7) In the wire harness of (6), the filling rate of the third corrugated tube may be higher than both the filling rate of the first corrugated tube and the filling rate of the second corrugated tube. In this case, flexibility can be adjusted so that the third section is more difficult to bend than the first and second sections.

(8) The wire harness according to any one of (1) to (7) may be provided with a low-voltage electric wire as the electric wire. In this case, since the diameter of each electric wire can be made small compared to the case where high-voltage electric wires are included, it is easy to adjust flexibility.

[Details of the embodiment of the present disclosure]
A specific example of the wire harness of the present disclosure will be described below with reference to the drawings. The present disclosure is not limited to these examples, but is indicated by the scope of the claims, and is intended to include all modifications within the scope and meaning equivalent to the scope of the claims.

[Embodiment 1]
A wire harness according to the first embodiment will be described below. FIG. 1 is a plan view showing the wire harness 20. FIG. FIG. 2 is a cross-sectional view taken along line II--II of FIG. FIG. 3 is a cross-sectional view taken along line III--III of FIG.

The wire harness 20 includes a first connector 22 , a second connector 24 , a plurality of electric wires 30 , a first corrugated tube 32 and a second corrugated tube 34 . Such a wire harness 20 is used as a wiring member for electrically connecting a plurality of electrical components in a vehicle or the like.

The first connector 22 is a connector that maintains electrical connection with electrical components in a vehicle or the like. The first connector 22 may be detachably connected to the electrical component, or may be detachably connected to the electrical component. The electrical components may be electronic control units, sensors, motors, switches, and the like. For example, the first connector 22 may be configured such that a terminal connected to an end portion of the electric wire 30 by crimping or the like is accommodated in a housing made of resin or the like.

The second connector 24, like the first connector 22, is a connector that maintains electrical connection with electrical components in a vehicle or the like. By connecting the first connector 22 and the second connector 24 to separate electrical components, the separate electrical components are electrically connected via the wire harness 20 .

Each of the plurality of electric wires 30 is, for example, an electric wire including a core wire and an insulating coating covering the core wire. The core wire is a linear conductor made of a conductive material such as metal. The core wire is composed of one or more strands. The insulating coating is an insulating portion that covers the periphery of the core wire, and is formed by extruding and coating a resin around the core wire. The electric wire 30 may be an electric wire that constitutes a cable such as a shielded wire or a twisted wire. The thickness of the plurality of electric wires 30 may be the same, or may be different from each other. The number of electric wires 30 is arbitrary. Here, there are six electric wires 30 .

The electric wire 30 may be a signal electric wire or a power electric wire. The electric wire 30 may be a low voltage electric wire. The low-voltage electric wire is a signal electric wire, a ground electric wire, a low-voltage power electric wire, or the like, and may be, for example, an electric wire specified in JASO D611 (JP) 2014 edition. As such a low-voltage electric wire, for example, an electric wire having a diameter of 7 mm or less may be used. The high-voltage electric wire to be compared with the low-voltage electric wire may be, for example, one specified in JASO D624 (JP) 2015 version.

A first connector 22 is connected to one end of the plurality of wires 30 , and a second connector 24 is connected to the other end of the plurality of wires 30 . Thereby, the plurality of electric wires 30 electrically connect the first connector 22 and the second connector 24 . A plurality of electric wires 30 are bundled together between the first connector 22 and the second connector 24 . The plurality of electric wires 30 may be kept in a bundled form by the first corrugated tube 32 and the second corrugated tube 34, or may be kept in a bundled form by another binding member (adhesive tape or the like). The plurality of electric wires 30 may be bundled in a twisted state, or may be bundled without being twisted.

The first corrugated tube 32 is formed in a tube shape in which thin annular portions 32a and thick annular portions 32b are alternately arranged. The narrow annular portion 32a is an annular portion, and the thick annular portion 32b is an annular portion having a larger diameter than the narrow annular portion 32a. An annular stepped portion is formed between the thin annular portion 32a and the thick annular portion 32b to connect the peripheral edge portion of the thick annular portion 32b and the peripheral edge portion of the thin annular portion 32a.

Similarly to the first corrugated tube 32, the second corrugated tube 34 is also formed in a tube shape in which thin annular portions 34a corresponding to the thin annular portions 32a and thick annular portions 34b corresponding to the thick annular portions 32b are alternately connected. be. The first corrugated tube 32 and the second corrugated tube 34 can be bent and deformed mainly by deforming at annular stepped portions between the thin annular portions 32a, 34a and the thick annular portions 32b, 34b.

The corrugated tubes 32, 34 are made of the same material, for example, resin such as PP (polypropylene). The corrugated tubes 32, 34 may be made of different materials. The diameter and thickness of the corrugated tubes 32 and 34, the repetition pitch between the thin annular portions 32a and 34a and the thick annular portions 32b and 34b, etc. may be the same or different. In this embodiment, an example in which the corrugated tubes 32 and 34 have the same thickness and the same repetition pitch will be described. Also, an example in which the inner diameter of the first corrugated tube 32 is larger than the inner diameter of the second corrugated tube 34 will be described. The corrugated tubes 32 and 34 may have slits for arranging the wires 30 therein. In this case, the slit may be kept closed by tape wrapped around at least a portion of the corrugated tubes 32,34.

The first corrugated tube 32 covers the multiple electric wires 30 in the first section E1 between the first connector 22 and the second connector 24 . The second corrugated tube 34 covers the multiple electric wires 30 in the second section E2 between the first corrugated tube 32 and the second connector 24 . That is, the first corrugated tube 32 covers the first section E1 of the electric wire 30 near the first connector 22 . Also, the second corrugated tube 34 covers the section E2 from the second connector 24 of the electric wire 30 .

Although the first corrugated tube 32 and the second corrugated tube 34 are separated from each other, they may be in contact with each other. The first corrugated tube 32 is separated from the first connector 22 but may be in contact with the first connector 22 . The second corrugated tube 34 is separated from the second connector 24 but may be in contact with the second connector 24 .

The filling rate F1 in the first corrugated tube 32 is different from the filling rate F2 in the second corrugated tube 34 . The filling rate is the ratio of the cross-sectional area of the internal contents to the cross-sectional area of the accommodation space of the corrugated tube. The cross-sectional area of the accommodation space of the corrugated tube is, for example, the cross-sectional area of the accommodation space in the narrow annular portions 32a and 34a. The cross-sectional area of the internal container is the cross-sectional area occupied by the object within the container space. When the internal container contains a plurality of electric wires, the cross-sectional area of the internal container is, for example, the sum of the cross-sectional areas of the multiple electric wires. If the internal contents include a cable in which one or more wires are covered with a shield coating, sheath, etc., the cross-sectional area of the cable may be added as the area surrounded by the outermost surface of the cable. good. The cross-sectional area of each wire or cable is, for example, the cross-sectional area of the cross section perpendicular to the length direction of the wire.

In this example, the first corrugated tube 32 and the second corrugated tube 34 cover the same plurality of electric wires 30 . Therefore, the cross-sectional area of the internal contents (total cross-sectional area of the plurality of electric wires 30) is the same. Also, the first corrugated tube 32 is thicker than the second corrugated tube 34 . Therefore, the cross-sectional area T1 of the accommodation space in the narrow annular portion 32 a of the first corrugated tube 32 is larger than the cross-sectional area T2 of the accommodation space in the narrow annular portion 34 a of the second corrugated tube 34 . Therefore, the filling rate F2 in the second corrugated tube 34 is greater than the filling rate F1 in the first corrugated tube 32. As shown in FIG.

In the first section E1 where the filling rate F1 is small, the plurality of electric wires 30 can freely move within the first corrugated tube 32 (see FIG. 2). Therefore, when the first corrugated tube 32 is bent together with the plurality of electric wires 30 inside, the plurality of electric wires 30 can move freely within the first corrugated tube 32 or pass each other, can be bent easily.

On the other hand, in the second section E2 where the filling rate F2 is large, it is difficult for the plurality of electric wires 30 to move freely within the second corrugated tube 34 (see FIG. 3). Therefore, when the second corrugated tube 34 is bent together with the plurality of electric wires 30 inside, the plurality of electric wires 30 can move freely in the second corrugated tube 34 or pass each other. It becomes more difficult to bend than the first section E1.

According to the wire harness 20 configured in this way, since the first corrugated tube 32 and the second corrugated tube 34 have different filling rates F1 and F2, the flexibility of the first corrugated tube 32 and the second corrugated tube 34 is increased. different. By varying the filling rates F1 and F2 in this way, the flexibility of the wire harness 20 can be adjusted by dividing it into a plurality of sections E1 and E2.

Moreover, since the filling rate F2 of the second corrugated tube 34 is set higher than the filling rate F1 of the first corrugated tube 32, the first section E1 can be bent more easily than the second section E2. For this reason, for example, when assembling the wire harness 20 to a vehicle or the like, the second section E2 is arranged along a straight or less curved wiring route, and the first section E1 is arranged along a largely curved wiring route. Therefore, the wire harness 20 can be easily installed.

In addition, since the inner diameter of the first corrugated tube 32 is larger than the inner diameter of the second corrugated tube 34, the filling rates F1 and F2 can be easily made different between the first corrugated tube 32 and the second corrugated tube. It should be noted that different filling rates can also be achieved by other configurations, for example, by changing the number of wires in the corrugated tube.

Moreover, if the electric wire 30 is a low voltage electric wire, the diameter of each electric wire 30 can be made small. If the diameter of each electric wire 30 is small, the flexibility inherent in each electric wire 30 has little effect on the overall flexibility of the wire harness 20 . Rather, the degree of freedom of movement of the plurality of electric wires 30 within the corrugated tubes 32 and 34 has a greater effect on the bendability of the wire harness 20 . Therefore, when the electric wires 30 are low-voltage electric wires, the diameter of each electric wire 30 can be made small, so that the flexibility can be easily adjusted by setting the filling rate.

FIG. 4 is a plan view showing a wire harness 20B according to a modification. A wire harness 20B according to this modification includes a first tape 42 wound around a first corrugated tube 32 and a second tape 44 wound around a second corrugated tube 34 . The first tape 42 and the second tape 44 may be continuous tapes or separate tapes. The method of winding the first tape 42 around the first corrugated tube 32 and the method of winding the second tape 44 around the second corrugated tube 34 are different. The different ways of winding the tapes 42, 44 around the corrugated tubes 32, 34 mean, for example, the areas where the tapes 42, 44 are wound around the corrugated tubes 32, 34 (for example, only the ends or the entire area including the intermediate area). , the winding pitch of the tapes 42 and 44 (whether it is lap winding in which the tapes are wound in a spiral shape with the tapes stacked on top of each other, or rough winding in which the tape is spirally wound with a gap provided for each turn, etc.), the corrugated tube 32, The number of layers of the tapes 42 and 44 on the tape 34 (whether only one layer is wound, or whether multiple layers are wound, etc.) is different. The larger the wrap area of the tapes 42, 44 on the corrugated tubes 32, 34, the less likely the corrugated tubes 32, 34 will bend. The smaller the winding pitch of the tapes 42, 44, the more difficult it is for the corrugated tubes 32, 34 to bend. Further, the corrugated tubes 32, 34 are less likely to bend as the number of layers of the tapes 42, 44 on the corrugated tubes 32, 34 increases.

In the example shown in FIG. 4 , the first tape 42 is lap-wound around the end of the first corrugated tube 32 , and the first tape 42 is loosely wound around the middle of the first corrugated tube 32 . A second tape 44 is lap-wound around the entire second corrugated tube 34 . Therefore, the method of winding the second tape 44 is a method of winding that makes the corrugated tube more difficult to bend than the method of winding the first tape 42 . The second tape 44 is also adjusted so that the second corrugated tube 34 is difficult to bend. The first tape 42 and the second tape 44 may have a role of making it difficult for the corrugated tubes 32 and 34 to open at the slits. The first tape 42 and the second tape 44 are also wound around the bundle of electric wires 30 and may have a role of positioning the corrugated tubes 32 and 34 with respect to the electric wires 30 at fixed positions.

[Embodiment 2]
A wire harness 120 according to the second embodiment will be described. FIG. 5 is a plan view showing a wire harness 120 according to Embodiment 2. FIG. 6 is a sectional view taken along line VI-VI of FIG. 5, and FIG. 7 is a sectional view taken along line VII-VII of FIG. It should be noted that the same components as those described in the first embodiment are denoted by the same reference numerals, and the description thereof will be omitted.

In the second embodiment, an example in which a plurality of electric wires 30 are branched will be described. That is, the wire harness 120 includes a group of first wires 130A, a group of second wires 130B, a first connector 22, a second connector 24, a third connector 126, a first corrugated tube 32, and a second corrugated tube. A tube 34 and a third corrugated tube 136 are provided.

The group of first electric wires 130A electrically connects the first connector 22 and the second connector 24, like the electric wires 30 described above.

Each of the group of second electric wires 130B is a member similar to the electric wire 30 described above. A group of second wires 130B electrically connect the first connector 22 and the third connector 126 . It should be noted that the third connector 126 is a portion that maintains electrical connection with electrical components, like the first connector 22 or the second connector 24 .

The first corrugated tube 32 accommodates the group of the first electric wires 130A and the group of the second electric wires 130B in the first section E1.

The second corrugated tube 34 accommodates a group of first electric wires 130A in the second section between the first corrugated tube 32 and the second connector 24, as in the first embodiment.

The third corrugated tube 136, like the first corrugated tube 32, is a tube in which narrow annular portions 136a and thick annular portions 136b are alternately connected. The third corrugated tube 136 covers the group of second wires 130B in the third section between the first corrugated tube 32 and the third connector 126. As shown in FIG.

That is, the group of first electric wires 130A and the group of second electric wires 130B are bundled together in the first section E1 near the first connector 22 . In this first section E1, the group of first electric wires 130A and the group of second electric wires 130B are housed in the same first corrugated tube 32 (see FIG. 2). The group of the first electric wires 130A and the group of the second electric wires 130B are connected to the branch portion 131 on the side opposite to the first connector 22 with respect to the first section E1, that is, between the first section E1 and the second section E2. is branched at a branching portion 131 of . A group of branched first electric wires 130A is accommodated in the second corrugated tube 34 (see FIG. 6). The group of the other branched second electric wires 130B is accommodated in the third corrugated tube 136 (see FIG. 7). The number of first electric wires 130A and the number of second electric wires 130B are arbitrary. In this example, there are two first electric wires 130A and four second electric wires 130B.

As in the first embodiment, the filling rate F1 of the first corrugated tube 32 is different from the filling rate F2 of the second corrugated tube 34 . For example, since the group of first electric wires 130A and the group of second electric wires 130B are branched at the branching portion 131, the number of electric wires in the second corrugated tube 34 is greater than the number of electric wires in the first corrugated tube 32. less. The inner diameter of the first corrugated tube 32 and the inner diameter of the second corrugated tube 34 are set in consideration of the number and thickness of the electric wires inside, and the filling rate F1 in the first corrugated tube 32 is It is set to be smaller than the filling rate F2. The second corrugated tube 34 is thinner than the first corrugated tube 32 here.

Also, the filling rate F3 of the third corrugated tube 136 may be set to be higher than both the filling rate F1 of the first corrugated tube 32 and the filling rate F2 of the second corrugated tube 34 . That is, considering the number, thickness, etc. of the electric wires inside, the inner diameters of the respective corrugated tubes 32, 34, 136 are adjusted so that the filling rate F3 in the third corrugated tube 136 is greater than the other filling rates F1, F2. is set. Here, the third corrugated tube 136 is thinner than the first corrugated tube 32 . Also, here, although the third corrugated tube 136 has the same thickness as the second corrugated tube 34, the number of the second electric wires 130B in the third corrugated tube 136 is equal to the number of the first electric wires 130A in the second corrugated tube 34. greater than Therefore, the filling rate F3 in the third corrugated tube 136 is greater than the filling rate F2 in the second corrugated tube 34.

According to this Embodiment 2, the same effect as Embodiment 1 can be obtained. In addition, even in the wire harness 120 in which a plurality of electric wires 130A and 130B branch, the flexibility of the wire harness 120 can be adjusted by dividing it into a plurality of sections E1, E2 and E3. For example, the wire harness 120 is divided into a trunk portion in which a group of the first electric wires 130A and a group of the second electric wires 130B are bundled, and a group of the first electric wires 130A and a group of the second electric wires 130B branching from the trunk portion. to adjust flexibility.

In addition, the filling rate F3 of the third corrugated tube 136 is set to be higher than both the filling rate F1 of the first corrugated tube 32 and the filling rate F2 of the second corrugated tube 34, so that the third section Flexibility can be adjusted so that E3 is more difficult to bend than the first section E1 and the second section E2.

FIG. 8 is an explanatory diagram showing a state in which the wire harness 120 according to the second embodiment is fixed to an arrangement target object 200 such as a vehicle. Electrical components 212 , 214 , 216 are directly or indirectly supported with respect to the arrangement target object 200 . In the example shown in FIG. 8, electrical component 212 is provided below and electrical components 214 and 216 are provided above. The electrical components 214, 216 are horizontally spaced apart. The electrical component 212 is provided at a position offset to one side from the center of the electrical components 214 and 216 .

First connector 22 of wire harness 120 is connected to electrical component 212 , second connector 24 is connected to electrical component 214 , and third connector 126 is connected to electrical component 216 . The group of first electric wires 130A and the group of second electric wires 130B in the first section E1 bend upward from the first connector 22 along a path P1 having a radius of curvature R1. The group of first electric wires 130A in the second section E2 heads toward the electrical component 214 while gently curving along a route P2 having a radius of curvature R2. The curvature radius R1 is smaller than the curvature radius R2. The group of second wires 130B in the third section E3 go to the electrical component 216 along a path P3 that is straight or has a radius of curvature.

In this way, the wire harness 120 is fixed to the arrangement target object 200 in a state in which the first section E1 of the wire harness 120 is bent to draw a curvature radius R1 smaller than that of the second section E2. The wire harness 120 is fixed to the placement target 200 by connecting the connectors 22 , 24 , 126 to the electrical components 212 , 214 , 216 . In addition, the corrugated tubes 32, 34, 136, the group of the first electric wires 130A, the group of the second electric wires 130B, and the like may be fixed to the arrangement target object 200 via brackets or the like. The route of the wire harness 120 is set according to the positional relationship of the electrical components 212, 214, 216 so as to avoid interference with peripheral components.

When the first section E1 is more bendable than the second section E2, when fixing the wire harness 120 to the arrangement target 200, the easily bendable first section E1 can be easily bent to have a radius of curvature smaller than that of the second section E2. It is easy to arrange along the path P1 that draws R1. In addition, the second section E2, which is difficult to bend, can be easily arranged along the route P2 without being bent greatly. In addition, it is easy to maintain the second section E2 along a stable route after assembly.

In particular, the third section E3, which has the highest filling rate F3 and is the hardest to bend, is configured along the path P3 that draws a straight line or the largest radius of curvature. can be reduced, and the assembly work of the wire harness 120 is facilitated. In addition, it is easy to maintain the route of the wire harness 120 in a stable route after assembly in this section E3.

In addition, each configuration described in each of the above-described embodiments and modifications can be appropriately combined as long as they do not contradict each other.

20, 20B, 120 wire harness 22 first connector 24 second connector 30, 130A, 130B electric wire 32 first corrugated tubes 32a, 34a, 136a narrow annular portions 32b, 34b, 136b thick annular portion 33 second corrugated tube 42 first Tape 44 Second tape 126 Third connector 131 Branch portion 136 Third corrugated tube 200 Arrangement object 212, 214, 216 Electric component E1 First section E2 Second section E3 Third section

Claims (8)

a first connector;
a second connector;
a plurality of electric wires electrically connecting the first connector and the second connector;
a first corrugated tube covering the plurality of electric wires in a first section between the first connector and the second connector;
a second corrugated tube covering the plurality of electric wires in a second section between the first corrugated tube and the second connector;
with
The wire harness, wherein the filling rate in the first corrugated tube is different from the filling rate in the second corrugated tube. The wire harness according to claim 1,
The wire harness, wherein the filling rate of the second corrugated tube is higher than the filling rate of the first corrugated tube. The wire harness according to claim 2,
A wire harness, wherein the inner diameter of the first corrugated tube is larger than the inner diameter of the second corrugated tube. The wire harness according to claim 2 or 3,
a first tape wound around the first corrugated tube;
A second tape wound around the second corrugated tube in a manner different from the winding method of the first tape;
a wire harness. The wire harness according to any one of claims 2 to 4,
The wire harness fixed to the placement target in a state in which the first section is bent to draw a smaller radius of curvature than the second section. The wire harness according to any one of claims 1 to 5,
When the plurality of electric wires are used as a group of first electric wires,
Further, a group of a plurality of second electric wires accommodated in the first corrugated tube together with the group of the first electric wires in the first section;
a third connector electrically connected to the first connector by the group of second wires;
with
The group of first wires and the group of second wires are branched at a branching portion between the first section and the second section,
The wire harness further comprising a third corrugated tube that covers the group of the second electric wires in a third section between the branch portion and the third connector. The wire harness according to claim 6,
The wire harness, wherein the filling rate of the third corrugated tube is higher than both the filling rate of the first corrugated tube and the filling rate of the second corrugated tube. The wire harness according to any one of claims 1 to 7, comprising a low-voltage electric wire as the electric wire.

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