JP2024082678A - Wiring duct, plug device, and wiring system - Google Patents

Abstract

[Problem] To provide a wiring duct that allows the thickness of the duct portion to be reduced. [Solution] A wiring duct (100) includes a long housing (10) and a plurality of conductors (20) held within the housing (10). The outer surface of the housing (10) includes an installation surface (14) that is parallel to the length direction, and the housing (10) includes two duct portions (12). The two duct portions (12) are aligned at an interval in a direction perpendicular to both the length direction and a direction perpendicular to the installation surface (14). Each of the duct portions (12) includes a holding space (17) and a communication port (18) that opens at a surface facing one of the directions perpendicular to both the length direction of the duct portion (12) and the direction perpendicular to the installation surface (14), and that communicates the holding space with the outside of the duct portion (12). The conductors (20) include a transmission conductor (201) held in the holding space (17) in each of the two duct portions (12). [Selected Figure] FIG.

Description

This disclosure generally relates to wiring ducts, plug devices, and wiring systems, and more particularly to wiring ducts and plug devices that form a supply path for power or electrical signals, and a wiring system that includes a wiring duct and a plug device connected thereto.

Patent Document 1 describes a wiring duct that includes a wiring duct body having an opening on the front along the longitudinal direction, a pair of conductors extending along a pair of inner surfaces of the wiring duct body, and a conductor cover that abuts against the bottom surface of the wiring duct body facing the opening and covers the conductors, and that allows attachment parts to come into contact with the conductors by elastic deformation of the conductor cover pressed from the opening side to the bottom side, and that connects a power outlet plug to the wiring duct.

JP 2006-302665 A

The objective of the present disclosure is to provide a wiring duct and plug device that can reduce the thickness of the duct portion, as well as a wiring system that includes the wiring duct and the plug device that is connected to the wiring duct.

A wiring duct according to one aspect of the present disclosure includes a long housing and a plurality of conductors held within the housing. The outer surface of the housing includes an installation surface parallel to the length direction, and the housing includes two duct sections. Each of the duct sections is long in the length direction of the housing. The two duct sections are arranged at intervals in a direction perpendicular to both the length direction and the direction perpendicular to the installation surface. Each of the duct sections includes a holding space and a communication port that opens on a surface of the duct section facing one of the directions perpendicular to both the length direction and the direction perpendicular to the installation surface, and connects the holding space to the outside of the duct section. The conductors include transmission conductors held in the holding spaces in each of the two duct sections.

A plug device according to one aspect of the present disclosure is connected to a wiring duct. The plug device comprises a main housing having an attachment surface, and two terminal portions positioned opposite the main housing via the attachment surface. Each of the terminal portions comprises a base and a connection terminal protruding from the base. The connection terminals protrude in the same direction parallel to the attachment surface. The positions of the terminal portions relative to the main housing in the direction in which the connection terminals protrude are different from each other.

The wiring system according to one aspect of the present disclosure includes the wiring duct and a plug device connected to the wiring duct.

The present disclosure provides a wiring duct that can reduce the thickness of the duct portion, a plug device, and a wiring system that includes the wiring duct and a plug device connected to the wiring duct.

FIG. 1 is a schematic front view of a wiring duct according to an embodiment. FIG. 2 is a schematic cross-sectional view of the wiring duct as viewed from one direction (right side) in the longitudinal direction. Fig. 3A is a schematic front perspective view of the plug device according to the first embodiment, Fig. 3B is a schematic side view of the plug device, Fig. 3C is a schematic plan view of the plug device, and Fig. 3D is a schematic rear view of the plug device. FIG. 4 is a schematic front view showing a state in which the plug device according to the first embodiment is connected to a wiring duct. FIG. 5 is a schematic cross-sectional view of the above plug device connected to the wiring duct, as viewed from one direction (right side) in the longitudinal direction of the wiring duct. FIG. 6 is a side cross-sectional view of the plug device in a locked state. FIG. 7 is a side cross-sectional view of the plug device in the released state. 8A to 8C are schematic right side cross-sectional views showing a state in which a plug device is connected to a wiring duct in the wiring system. Fig. 8A shows the state before the plug device is placed in the wiring duct. Fig. 8B shows the state in the middle of being placed in the wiring duct and connected. Fig. 8C shows the state after the plug device is connected to the wiring duct. FIG. 9 is a schematic rear view of the plug device according to the second embodiment. 10A and 10B are schematic front views showing a state in which the plug device is connected to a wiring duct in a wiring system, Fig. 10A shows a state before the plug device is placed in the wiring duct, and Fig. 10B shows one state in which the plug device is rotated in the wiring duct. 11A and 11B are schematic front views showing a state in which the plug device is connected to a wiring duct in the wiring system, Fig. 11A shows one state in which the plug device is rotated in the wiring duct, and Fig. 11B shows a state in which the plug device is connected to the wiring duct. FIG. 12 is a schematic side cross-sectional view showing a wiring duct and a plug device in a modified example of the wiring system.

When developing the wiring duct, the inventors focused on whether it would be possible to reduce the thickness of the wiring duct in the direction of the fixed surface relative to the fixed surface in order to secure more space in the direction of the fixed surface relative to the fixed surface when installing the wiring duct on a fixed surface such as a wall or ceiling surface as a fixing member.

Therefore, the present disclosure provides a wiring duct that can reduce the thickness of the duct portion, a plug device, and a wiring system that includes this wiring duct and a plug device connected to it.

The embodiments and modifications of the present disclosure will be described with reference to Figures 1 to 12. Note that the following embodiments and modifications are merely a portion of the various embodiments of the present disclosure. In addition, the following embodiments and modifications can be modified in various ways depending on the design, etc., as long as the object of the present disclosure can be achieved. In addition, the configurations of the modifications can be appropriately combined. All figures referenced below are schematic diagrams, and the dimensional ratios of the components in the figures do not necessarily reflect the actual dimensional ratios.

The wiring duct 100 according to the embodiment includes a long housing 10 and a plurality of conductors 20. The plurality of conductors 20 are held within the housing 10. The outer surface of the housing 10 includes an installation surface 14 parallel to the length direction, and the housing 10 includes two duct sections 12. Each of the duct sections 12 is long in the length direction of the housing 10. The two duct sections 12 are arranged at intervals in a direction perpendicular to both the length direction and the direction perpendicular to the installation surface 14. Each of the duct sections 12 includes a holding space 17 and a communication port 18 that opens on a surface facing one of the directions perpendicular to both the length direction of the duct section 12 and the direction perpendicular to the installation surface 14, and communicates the holding space 17 with the outside of the duct section 12. The conductor 20 includes a transmission conductor 201 held in the holding space 17 in each of the two duct sections 12.

In this way, according to the wiring duct 100 of this embodiment, the two duct sections 12 are arranged at a distance from each other in a direction perpendicular to both the length direction and the direction perpendicular to the installation surface 14, so that the duct sections 12 are not arranged in a direction facing the surface on which the wiring duct 100 is installed, and each of the two duct sections 12 can hold a transmission conductor 201. Therefore, according to the wiring duct 100 of this embodiment, the thickness in the direction facing the surface on which the wiring duct 100 is installed can be reduced.

The wiring system 300, which includes the wiring duct 100 and the plug device 200, is used, for example, to supply power or electrical signals to electrical equipment.

The wiring duct 100 is installed, for example, in a facility such as a building, and constitutes a supply path for power, electrical signals, etc. By connecting the plug device 200 to an appropriate position in the wiring duct 100, power, electrical signals, etc. can be supplied from the wiring duct 100 to the plug device 200, and by connecting appropriate electrical equipment, etc. to the plug device 200, power, electrical signals, etc. can be supplied to the electrical equipment, etc.

The wiring duct 100 can be installed on the surface of a fixing member 50 such as a wall or a ceiling. When the wiring duct 100 is installed on a wall surface, for example, the installation surface 14 of the wiring duct 100 is overlapped on the wall surface, and the two duct parts 12 and the internal space 11 are arranged in the order of one duct part 12, the internal space 11, and the other duct part 12 from the top in the vertical direction. Note that the internal space 11 is a space including a gap between the two duct parts 12. In this case, the communication port 18 in one of the two duct parts 12, which is on the upper side, opens downward into the internal space 11, and the other communication port 18 in the other duct part 12, which is on the lower side of the two duct parts 12, opens into the open space 110 below the duct part 12. A plug device 200 can be connected to this wiring duct 100. When the wiring duct 100 is installed on a wall, each communication opening 18 faces downward. Therefore, even if dust or the like enters the wiring duct 100 through the opening 16, the dust or the like is unlikely to reach the conductor 20 held in the duct portion 12. This prevents problems such as short circuits between the conductors 20 and poor contact with the plug device 200 caused by dust or the like. Below, the configuration of this embodiment will be described mainly for the case where the wiring duct 100 is installed on a wall and the plug device 200 is connected to the wiring duct 100. However, the wiring duct 100 does not necessarily have to be installed on a wall, and can be installed on a ceiling, for example.

In the following description, when the wiring duct 100 is installed on a wall and the plug device 200 is connected to the wiring duct 100, the direction perpendicular to the horizontal plane is defined as the "up-down direction," the direction perpendicular to the up-down direction and parallel to the wall is defined as the "left-right direction," and the direction perpendicular to both the up-down direction and the left-right direction is defined as the "front-rear direction." The upward direction in the "up-down direction" is defined as the "upward direction," and the downward direction is defined as the "downward direction." The direction of the wiring duct 100 side relative to the wall in the "front-rear direction" is defined as the "forward direction," and the direction opposite to the forward direction is defined as the "rearward direction." When the top and front for the observer are determined by the above-mentioned "upward direction" and "forward direction," the left direction in the "left-right direction" for the observer is defined as the "leftward direction," and the right direction is defined as the "rightward direction." The arrows indicating the "up-down direction," "front-rear direction," and "left-right direction" in the drawings are merely shown for explanatory purposes and do not have any substance. These directional specifications are not intended to limit the installation state of the wiring system 300.

The longitudinal direction of the housing 10 in the wiring duct 100 installed on the wall coincides with the "left-right direction."

The direction perpendicular to the installation surface 14 of the wiring duct 100 installed on the wall and the side to which the mounting surface 31 of the main housing 30 of the plug device 200 connected to this wiring duct 100 faces correspond to "forward", and the direction in which the connecting portion 33 and the base 34 of the terminal portion 32 are aligned corresponds to the "front-to-back direction". The direction in which the installation surface 14 faces in the direction perpendicular to the installation surface 14 corresponds to "rear", and the opposite direction corresponds to "forward". The direction of the base 34 side relative to the connecting portion 33 in the direction in which the connecting portion 33 and the base 34 are aligned corresponds to "rear", and the direction of the connecting portion 33 side relative to the base 34 corresponds to "forward".

In the two duct parts 12 (hereinafter also referred to as the first duct part 12a and the second duct part 12b; details will be described later) of the wiring duct 100 installed on the wall, the direction in which the internal space 11 between the first duct part 12a and the second duct part 12b is aligned and the direction in which the connection terminal 35 of the plug device 200 connected to this wiring duct 100 protrudes correspond to the "up-down direction". The orientation of the two duct parts 12 with respect to the internal space 11 in the direction in which the two duct parts 12 and the internal space 11 are aligned corresponds to the "upward direction", and the orientation of the internal space 11 with respect to the two duct parts 12 corresponds to the "downward direction". The protruding direction of the connection terminal 35 in the protruding direction of the connection terminal 35 corresponds to the "upward direction", and the direction opposite to this direction corresponds to the "downward direction".

An embodiment of the wiring duct 100 will be described with reference to Figures 1 and 2.

The wiring duct 100 of this embodiment includes a housing 10 and a plurality of conductors 20. The plurality of conductors 20 are held within the housing 10. The plurality of conductors 20 include a plurality of transmission conductors 201 and an earth conductor 202.

The transmission conductor 201 is a conductor for transmitting electric power or an electric signal, etc., to be transmitted by the wiring duct 100. For example, when the wiring duct 100 transmits electric power, if the power transmission method is a single-phase two-wire system, the number of transmission conductors 201 is two, if the power transmission method is a single-phase three-wire system or a three-phase three-wire system, the number of transmission conductors 201 is three, and if the power transmission method is a three-phase four-wire system, the number of transmission conductors 201 is four. In this embodiment, the number of transmission conductors 201 is two. Specifically, in this embodiment, the transmission conductors 201 include a first transmission conductor 120 and a second transmission conductor 220.

The housing 10 is long in the left-right direction. The housing 10 has an outer surface with an installation surface 14 that is parallel to the length direction, and a connection surface 15 that is on the opposite side to the installation surface 14 and faces forward. The installation surface 14 is a surface that comes into contact with a wall surface of a fixing member 50 such as a wall. The connection surface 15 is a surface that can come into contact with the mounting surface 31 of the main housing 30 of the plug device 200 when the plug device 200 is attached and connected.

In this embodiment, as described above, the housing 10 has two duct sections 12. Each of the duct sections 12 is long in the length direction of the housing 10. The two duct sections 12 are arranged at a distance from each other in a direction (up-down direction) perpendicular to both the left-right direction and the direction (front-rear direction) perpendicular to the installation surface 14. The two duct sections 12 are located on the opposite side (forward-facing side) to the rearward-facing side toward which the installation surface 14 of the housing 10 faces. In other words, the two duct sections 12 are located on the opposite side of the fixing member 50 on which the installation surface 14 is installed.

In the following, the duct portion 12 located on the upper side in the vertical direction of the two duct portions 12 is also referred to as the "first duct portion 12a", and the duct portion 12 located on the lower side of the first duct portion 12a is also referred to as the "second duct portion 12b". In the space below the first duct portion 12a, there is an internal space 11 in the space between the first duct portion 12a and the second duct portion 12b. In this embodiment, there is an open space 110 below the second duct portion 12b, but this is not limited as long as it is configured to be connectable to the plug device 200. For example, there may be a receiving portion (not shown) parallel to the length direction of the housing 10 below the second duct portion 12b, and the space between this receiving portion and the second duct portion 12b may be formed as an internal space (not shown) in the second duct portion 12b. The open space 110 is a space below the second duct portion 12b, below the communication port 18 of the second duct portion 12b. The open space 110 is not a component of the wiring duct 100. However, as described above, when the second duct portion 12b has a receiving portion below it that is parallel to the length direction of the housing 10, the internal space of the second duct portion 12b can be a component of the wiring duct 100 as a second internal space.

Each of the duct sections 12 holds a transmission conductor 201. In this embodiment, the first duct section 12a holds a first transmission conductor 120, and the second duct section 12b holds a second transmission conductor 220. The first transmission conductor 120 and the second transmission conductor 220 are each long in the left-right direction.

Each of the duct sections 12 has a holding space 17 and a communication port 18 that opens on a surface facing in a direction (front-rear direction) perpendicular to both the length direction (left-right direction) of the duct section 12 and the direction perpendicular to the installation surface 14 (up-down direction), and connects the holding space 17 to the outside of the duct section 12. A transmission conductor 201 is arranged in each of the holding spaces 17 of the duct section 12. Each holding space 17 is a space that is long in the left-right direction, and each communication port 18 is an opening that is long in the left-right direction. In each of the duct sections 12, the holding spaces 17 are lined up in the up-down direction, and therefore the communication ports 18 are also lined up in the up-down direction. Therefore, the transmission conductors 201 held in each of the holding spaces 17 are also lined up in the up-down direction.

The holding space 17 (hereinafter also referred to as the "first holding space 117") and the communication port 18 (hereinafter also referred to as the "first communication port 118") in the first duct portion 12a are connected to the internal space 11.

The holding space 17 (hereinafter also referred to as the "second holding space 217") and the communication port 18 (hereinafter also referred to as the "second communication port 218") in the second duct portion 12b are connected to the open space 110 of the second duct portion 12b.

Each duct section 12 may have a holding section 121 for holding the transmission conductor 201. In this case, the duct section 12 includes the holding section 121, which includes the holding space 17 and the communication opening 18. That is, the holding space 17 and the communication opening 18 included in the duct section 12 described above may be formed in the holding section 121. This allows the holding section 121 to hold the transmission conductor 201 in each duct section 12. In the following description, the holding section 121 in the first duct section 12a of the two duct sections 12 may be referred to as the "first holding section 121a," and the holding section 121 in the second duct section 12b may be referred to as the "second holding section 121b."

As described above, the housing 10 has a connection surface 15, which includes a first connection surface 115 of the first duct portion 12a and a second connection surface 215 of the second duct portion 12b. The housing 10 also has an installation surface 14, which includes a first installation surface 114 of the first duct portion 12a and a second installation surface 214 of the second duct portion 12b. In this embodiment, each of the duct portions 12 includes a retaining portion 121 and an outer shell portion 13.

The holding portion 121 includes a first holding portion 121a in the first duct portion 12a and a second holding portion 121b in the second duct portion 12b. The outer shell portion 13 includes a first outer shell portion 113 in the first duct portion 12a and a second outer shell portion 213 in the second duct portion 12b. The outer shell portion 13 is a long cylindrical shape in the left-right direction. In the outer shell portion 13, the rearward facing surface on the outer surface of the first outer shell portion 113 is the first installation surface 114, and the forward facing surface on the opposite side to the first installation surface 114 is the first connection surface 115. The rearward facing surface on the outer surface of the second outer shell portion 213 is the second installation surface 214, and the forward facing surface on the opposite side to the second installation surface 214 is the second connection surface 215. The space below the first retaining portion 121a inside the first outer shell portion 113 of the first duct portion 12a is the internal space 11. That is, the first retaining portion 121a and the internal space 11 are aligned vertically.

For example, in FIG. 2, the installation surface 14 is configured so that the surface facing the wall surface of the fixing member 50 such as a wall (the rearward facing surface) is flush with the wall, but this is not limited thereto.

In this embodiment, the cross-sectional shape of the outer surface of the outer shell portion 13 of each duct portion 12 (the outer surface of the housing 10) perpendicular to the left-right direction is a rectangle whose vertical dimension is longer than its front-rear dimension. In each duct portion 12, the holding portion 121 is long in the left-right direction and is held at the upper part inside the outer shell portion 13. The first outer shell portion 113 of the first duct portion 12a is located above the second outer shell portion 213 of the second duct portion 12b. The first outer shell portion 113, the internal space 11, and the second outer shell portion 213 are arranged in this order from the top. In this embodiment, the first installation surface 114 on the outer surface of the first outer shell portion 113 and the second installation surface 214 on the outer surface of the second outer shell portion 213 are arranged in the vertical direction. Note that, in FIG. 2 and the like, the first installation surface 114 and the second installation surface 214 are connected and formed as one piece, but this is not limited to this.

The first duct portion 12a and the second duct portion 12b may be separate members, or may be a single member that cannot be separated without destruction, and the outer shell portion 13 and the retaining portion 121 may be separate members, or may be a single member that cannot be separated without destruction.

Each of the transmission conductors 201 held in the holding space 17 of the duct section 12 has two leaf springs 19 that face each other in a direction perpendicular to the installation surface 14. The upper ends of the two leaf springs 19 in the vertical direction are connected to each other. The two leaf springs 19 in each of the transmission conductors 201 may be made of a single plate material, that is, each of the portions on one end side and the other end side of the bent plate material may be the leaf spring 19. As described later, by sandwiching the connection terminal 35 of the plug device 200 between the two leaf springs 19, a stable electrical connection can be realized between each of the transmission conductors 201 and each of the connection terminals 35.

The first transmission conductor 120 is held in the first holding space 117 in the first duct portion 12a. Since the first duct portion 12a has the first holding space 117 in the first holding portion 121a, it can also be said that the first transmission conductor 120 is in the first holding portion 121a in the first duct portion 12a.

The second transmission conductor 220 is held in the second holding space 217 in the second duct portion 12b. Since the second duct portion 12b has the second holding space 217 in the second holding portion 121b, it can also be said that the second transmission conductor 220 is in the second holding portion 121b in the second duct portion 12b.

The housing 10 is made of an electrically insulating material, such as, but not limited to, plastic. For example, a portion of the housing 10 may be made of an electrically conductive material, such as a metal, provided that short circuits between the conductors 20 are prevented.

The housing 10 has an opening 16 that is open between the first connection surface 115 of the first duct portion 12a and the second connection surface 215 of the second duct portion 12b, communicates with the internal space 11, and is long along the left-right direction. The opening 16 opens forward between the first connection surface 115 of the first duct portion 12a and the second connection surface 215 of the second duct portion 12b, i.e., communicates the outside of the wiring duct 100 with the internal space 11 in the front-rear direction. The opening 16 opens at a position lower in the vertical direction than the connection surface 15 of the first duct portion 12a (hereinafter also referred to as the "first connection surface 115") and higher in the vertical direction than the connection surface 15 of the second duct portion 12b (hereinafter also referred to as the "second connection surface 215").

The housing 10 holds the earth conductor 202 so that it is exposed at the connection surface 15. In this embodiment, the second outer shell portion 213 of the second duct portion 12b holds the earth conductor 202, and the earth conductor 202 is exposed at the second connection surface 215. The second connection surface 215 is formed with unevenness. For example, the second connection surface 215 of the second outer shell portion 213 has a recess (first recess 213b) that opens forward, and the earth conductor 202 is disposed in this first recess 213b. In addition, the second connection surface 215 of the second outer shell portion 213 has a recess (second recess 213d) that opens forward below the earth conductor 202. Specifically, for example, in FIG. 2 and the like, the second outer shell portion 213 has a first convex portion 213a, a first concave portion 213b, a second convex portion 213c, a second concave portion 213d, and a third convex portion 213e formed continuously in order from the upper end side in the vertical direction of the second duct portion 12b. The first convex portion 213a, the first concave portion 213b, the second convex portion 213c, the second concave portion 213d, and the third convex portion 213e are all formed long in the left-right direction. In this case, in the second duct portion 12b, the ground conductor 202 having a strip-like shape long in the left-right direction can be arranged in the first concave portion 213b. Furthermore, when the ground conductor 202 is arranged in the first concave portion 213b, the wiring system 300 can be configured by connecting the ground terminal 335 in the plug device 200 described later to the ground conductor 202. Note that the position at which the ground conductor 202 is arranged is not limited to this. For example, the position where the earth conductor 202 is arranged may be the outer surface of the first duct portion 12a depending on the embodiment of the plug device 200. The connection method will be described in detail in the explanation of the wiring system 300.

The outer shell 13 of the housing 10 has a mounting hole 41. The mounting hole 41 opens between the first duct portion 12a and the second duct portion 12b, i.e., at a position on the inner surface of the internal space 11 opposite the opening 16, and connects the internal space 11 to the outside of the wiring duct 100. On the outside side of the wiring duct 100, the mounting hole 41 opens at the installation surface 14. By inserting a fastener 51 such as a screw into this mounting hole 41, the wiring duct 100 can be installed on the surface of a structural material such as a wall. In addition, when driving the fastener 51 into a structural material such as a wall, it is easy to insert a tool into the wiring duct 100 through the opening 16 to perform the work.

In this embodiment, the wiring duct 100 has the above-mentioned configuration, and each of the duct parts 12 has a communication port 18 that connects the transmission conductor 201, which is the conductor 120 held by the duct part 12, to the internal space 11 or the open space 110, and each communication port 18 opens toward the internal space 11 or the open space 110 in a direction perpendicular to both the length direction of the housing 10 and the direction perpendicular to the installation surface 14. Therefore, especially when the wiring duct 100 is installed on a wall surface as described above, each communication port 18 faces downward. Therefore, even if dust or the like enters the wiring duct 100 from the opening 16, the dust or the like is unlikely to reach the conductor 20 held in the duct part 12. This suppresses the occurrence of defects such as short circuits between the conductors 20 and poor contact with the plug device 200 caused by dust or the like. Furthermore, in this embodiment, when the wiring duct 100 is installed in a structural material such as a fixing member 50 on a wall or the like, even if it is embedded in the structural material, the opening 16 can be exposed from the structural material.

We will now explain the embodiments of the plug device 200 and the wiring system 300. These embodiments include the following first and second embodiments.

The plug device 200 of this embodiment is connected to the above-mentioned wiring duct 100. For example, the plug device 200 is used to connect to the wiring duct 100.

The plug device 200 comprises a main housing 30 and two terminal portions 32. The main housing 30 has an attachment surface 31. The attachment surface 31 is the surface opposite to the side (forward-facing side) to which the main housing 30 faces. The two terminal portions 32 are positioned opposite the main housing 30 via the attachment surface 31. Each of the terminal portions 32 comprises a base 34 and a connection terminal 35 protruding from the base 34. The connection terminals 35 protrude in the same direction parallel to the attachment surface 31. The positions of the two connection terminals 35 in the direction in which they protrude relative to the main housing 30 are different from each other.

The plug device 200 also includes a connecting portion 33 that connects each terminal portion 32 to the main body housing 30 on the mounting surface 31. The connecting portion 33 is included in the terminal portion 32. That is, each terminal portion 32 includes a connecting portion 33, a base portion 34, and a connection terminal 35. In the embodiment, the base portion 34 of each terminal portion 32 is connected to the main body housing 30 via the connecting portion 33. In this disclosure, of the two terminal portions 32, the terminal portion 32 closer to the upper side in the vertical direction is also referred to as the "first terminal portion 132", and the terminal portion 32 closer to the lower side is also referred to as the "second terminal portion 232". In addition, the base portion 34 of the first terminal portion 132 is also referred to as the "first base portion 134", the connection terminal 35 is also referred to as the "first connection terminal 135", the base portion 34 of the second terminal portion 232 is also referred to as the "second base portion 234", and the connection terminal 35 is also referred to as the "second connection terminal 235". In addition, the connecting portion 33 that connects to the main body housing 30 at the first terminal portion 132 is also referred to as the "first connecting portion 133," and the connecting portion 33 that connects to the main body housing 30 at the second terminal portion 232 is also referred to as the "second connecting portion 233." The first terminal portion 132 has the first connecting portion 133, a first base portion 134, and a first connection terminal 135, and is connected to the main body housing 30 via the first connecting portion 133. The second terminal portion 232 has the second connecting portion 233, a second base portion 234, and a second connection terminal 235, and is connected to the main body housing 30 via the second connecting portion 233.

The plug device 200 has a connector 36 and a socket 136 on the surface opposite (facing forward) from the mounting surface 31 on which the terminal portion 32 is provided. The connector 36 is fixed to the main housing 30, and the socket 136 of the connector 36 opens on the surface of the main housing 30 facing forward in the front-to-rear direction. The connector 36 can output power or electrical signals transmitted by the wiring system 300 to the outside of the wiring system 300 through an external plug (not shown) connected to the connector 36. The connector 36 in the embodiment is configured to be connected to an external plug for power supply, but the connector 36 may be a port for transmitting electrical signals, such as a USB port.

The main body housing 30 of the plug device 200 is disposed outside the wiring duct 100 in a state in which the plug device 200 is connected to the wiring duct 100 (hereinafter referred to as the "connected state"). This can constitute a wiring system 300. That is, the wiring system 300 includes the wiring duct 100 and the plug device 200. In this embodiment, in the connected state, the first base 134 of the first terminal portion 132 of the plug device 200 is disposed in the internal space 11 between the first duct portion 12a and the second duct portion 12b of the wiring duct 100. The second base 234 of the second terminal portion 232 is disposed below the lower end of the second connection surface 215 of the second duct portion in the vertical direction.

The connection terminals 35 in each terminal portion 32 are electrically connected to the corresponding transmission conductors 201 in the wiring duct 100 in a connected state. In this embodiment, the upper end of each connection terminal 35 in the vertical direction is configured not to protrude beyond the upper end of the main body housing 30. The vertical dimension of the first connection terminal 135 is smaller than, for example, the distance between the first duct portion 12a and the second duct portion 12b. Each connection terminal 35 is a single conductive plate having a thickness in the front-rear direction.

The connection terminals 35 and the transmission conductors 201 correspond one-to-one, and in the connected state, each connection terminal 35 is inserted into the corresponding holding space 17 from the corresponding communication port 18 and is electrically connected to the corresponding transmission conductor 201. The connection terminal 35 is sandwiched between the two leaf springs 19 in the transmission conductor 201, so that it is stably connected to the transmission conductor 20 (see FIG. 5).

5 and other figures, in this embodiment, the vertical dimension of the main housing 30 is equal to or smaller than the vertical dimension of the housing 10. Here, the vertical dimension of the housing 10 refers to the length from the upward end (upper end) of the first connection surface 115 of the housing 10 to the downward end (lower end) of the second connection surface 215. In the connected state, the upward end of the main housing 30 is not positioned at a position above the upward end of the housing 10, and the downward end of the main housing 30 is not positioned at a position below the downward end of the housing 10. Therefore, in the connected state, the plug device 200 is positioned to fit comfortably in the wiring duct 100.

Details of the first embodiment are described with reference to Figures 3A to 3D.

The plug device 200 according to the first embodiment is shown in Figs. 3A to 3D. In the first embodiment, the main body housing 30 is rectangular, and the six faces of the main body housing 30 face up, down, left, right, front and back in the connected state.

Each connection terminal 35 protrudes upward from the base 24. In this embodiment, each connection terminal 35 in the terminal portion 32 protrudes in the same direction parallel to the mounting surface 31. More specifically, in this embodiment, each connection terminal 35 protrudes in a direction facing the communication port 18 of the wiring duct 100. The two terminal portions 32 are also parallel to the mounting surface 31 and are aligned along a direction that is not perpendicular to the direction in which the connection terminals 35 protrude. In this embodiment, each connection terminal 35 is aligned on the same axis as the direction in which the connection terminals 35 protrude.

The plug device 200 also includes a mating protrusion 37, a biasing mechanism 371, an operating portion 38, and a conversion mechanism 381.

The mating protrusion 37 protrudes rearward in the front-rear direction from the surface facing the rearward side of the main housing 30. In the connected state, the mating protrusion 37 is located between the first terminal portion 132 and the second terminal portion 232 in the up-down direction. In the connected state, when the mating protrusion 37 is viewed from the rearward side of the plug device 200 looking forward, the mating protrusion 37 is rectangular, and the up-down dimension of the mating protrusion 37 is equal to or smaller than the up-down dimension of the opening 16. The mating protrusion 37 is configured to be movable along the front-rear direction relative to the main housing 30. Therefore, the mating protrusion 37 is configured to fit into the opening 16 of the wiring duct 100 by moving it along the front-rear direction.

As shown in Figures 6 and 7, the plug device 200 has a mating portion 137, and the rearward end of this mating portion 137 is the mating protrusion 37. The mating portion 137 is held in the main body housing 30.

The main housing 30 has a recess 311 that opens on the surface facing the rearward side. The fitting portion 137 is inserted into this recess 311, and the fitting protrusion 37 protrudes from the opening of the recess 311. The fitting portion 137 can move in the front-rear direction while inserted into the recess 311, and therefore the fitting protrusion 37 can also move in the front-rear direction. A rib 312 that protrudes inward from the edge of the opening of the recess 311 is formed on the inner peripheral surface of the recess 311. A rib 372 that faces outward is formed on the outer peripheral surface of the fitting portion 137 at a position on the forward side of the fitting protrusion 37. The rib 372 of the fitting portion 137 abuts on the rib 312 of the recess 311 from its forward side, which defines the movement limit position of the fitting portion 137 and the fitting protrusion 37 to the rearward side relative to the main housing 30. When the mating protrusion 37 is at the limit of movement, the mating protrusion 37 protrudes rearward from the main housing 30.

The biasing mechanism 371 applies a rearward force to the mating protrusion 37. In the first embodiment, the biasing mechanism 371 is composed of a coil spring 316. The coil spring 316 is held between a retaining recess 313 formed in the bottom surface of the recess 311 and a retaining recess 374 formed in the front-facing end surface of the mating portion 137 so as to extend in the front-rear direction. This causes the coil spring 316 to apply a rearward force to the mating portion 137 and the mating protrusion 37.

The operating unit 38 and the conversion mechanism 381 are configured so that the force pushing the operating unit 38 is converted by the conversion mechanism 381 into a force that moves the mating protrusion 37 toward the forward side. In the first embodiment, the operating unit 38 is held by the main body housing 30 and is exposed to the outside from the outer surface of the main body housing 30. The operating unit 38 is movable in a direction perpendicular to the front-rear direction relative to the main body housing 30 and is pushed toward the main body housing 30. In the first embodiment, the operating unit 38 is exposed at an opening 39 formed on the surface facing the upward side of the main body housing 30 and is movable in the vertical direction relative to the main body housing 30. That is, the moving direction of the operating unit 38 coincides with the "vertical direction", and the direction in which the operating unit 38 is pushed coincides with the "downward direction". A rib 315 protruding toward the inside of the opening 39 is formed on the inner peripheral surface of the opening 39, and a rib 318 protruding toward the outside of the operating unit 38 is formed on the outer peripheral surface of the operating unit 38. The rib 318 of the operating part 38 abuts against the rib 315 of the opening 39 from its upward side, determining the limit of the upward movement of the operating part 38 relative to the main body housing 30.

The operating unit 38 is arranged so that its upward end face abuts against the outer peripheral surface of the fitting portion 137 inside the main housing 30 in the direction in which the operating unit 38 moves. The surface of the operating unit 38 that abuts against the fitting portion 137 (hereinafter referred to as the abutment surface 382) and the surface of the fitting portion 137 that abuts against the abutment surface 382 of the operating unit 38 (hereinafter referred to as the abutment surface 373) are both inclined relative to an imaginary plane perpendicular to the direction in which the operating unit 38 moves so that the position on the side where the fitting protrusion 37 protrudes is located on the opposite side to the operating unit 38.

When the operating portion 38 is pressed from the outside of the plug device 200 toward the inside of the main housing 30, as shown in FIG. 7, the operating portion 38 moves downward in the vertical direction, and the abutment surface 382 of the operating portion 38 presses the abutment surface 373 of the fitting portion 137. Since the abutment surface 373 and the abutment surface 382 are inclined as described above, and the direction in which the fitting portion 137 and the fitting protrusion 37 can move is restricted by the recess 311, a force is applied to the fitting portion 137 and the fitting protrusion 37 in the direction of movement opposite to the direction in which the fitting protrusion 37 protrudes. Therefore, the fitting portion 137 and the fitting protrusion 37 move in the opposite direction to the direction in which the fitting protrusion 37 protrudes against the force applied by the biasing mechanism 371. As a result, the fitting protrusion 37 is pushed into the main housing 30. Furthermore, even if the operating portion 38 is not pressed, if a force is applied from outside the plug device 200 to the mating protrusion 37 in a direction opposite to the direction in which the mating protrusion 37 protrudes, the mating portion 137 and the mating protrusion 37 move in the direction opposite to the direction in which the mating protrusion 37 protrudes against the force applied by the biasing mechanism 371, and the mating protrusion 37 is pushed into the main housing 30.

In the first embodiment, the plug device 200 further includes an earth terminal 335 on the mounting surface 31 in addition to the two terminal portions 32. The position of the earth terminal 335 can be set as appropriate, but it is preferable that the earth terminal 335 be disposed at a position corresponding to the earth conductor 202 in the connected state. For example, when the earth conductor 202 is located in front of the connection surface 215 of the second duct portion 12b in the wiring duct 100, the earth terminal 335 may be disposed in a position facing the second connection surface 215 of the second duct portion 12b in the front-rear direction.

In the first embodiment, the earth terminal 335 is disposed on the front-facing surface of the mounting surface 31 of the main housing 30. In the connected state, the earth terminal 335 abuts against and contacts the earth conductor 202 of the wiring duct 100. As a result, the earth terminal 335 is electrically connected to the earth conductor 202 in the connected state. The vertical position of the earth terminal 335 is not particularly limited, but is, for example, parallel to the direction in which the two terminal portions 32 are arranged and is located closer to the second terminal portion 232 in the vertical direction. In this case, it is easy to electrically connect the earth conductor 202 provided on the connection surface 215 of the second duct portion 12b of the wiring duct 100 described above.

The method for connecting the plug device 200 to the wiring duct 100 to achieve a connected state in the first embodiment, and the method for removing the plug device 200 from the wiring duct 100 in the connected state will be described with reference to Figures 8A to 8C.

When connecting the plug device 200 to the wiring duct 100, the first terminal portion 132 is inserted into the internal space 11 of the first duct portion 12a of the housing 10 through the opening 16, the first connecting portion 133 is placed in the opening 16, and the second terminal portion 232 is positioned in the open space 110 below the lower end of the second connecting surface 215 of the second duct portion 12b of the housing 10. Then, the plug device 200 is moved upward to achieve the connected state.

Specifically, first, as shown in FIG. 8A, the plug device 200 is positioned in a forward-facing position relative to the wiring duct 100 such that the overall posture of the plug device 200 relative to the wiring duct 100 is such that the two connection terminals 35 of the plug device 200 face upward in the vertical direction, the lower end of the first terminal portion 32 of the plug device 200 is above the upper end of the second duct portion 12b, and the upper end of the first terminal portion 132 of the plug device 200 (i.e., the upper end of the first connection terminal 135) is below the lower end of the first connection surface 115 in the first duct portion 12a.

Next, the first terminal portion 132 of the plug device 200 is inserted into the internal space 11 through the opening 16, and the lower end of the first terminal portion 132 is placed in the opening 16. The vertical dimension of the first terminal portion 132 in the connected state is smaller than the vertical dimension of the opening 16, and the vertical dimension of the second terminal portion 232 is larger than the vertical dimension of the second duct portion 12b, which is the lower of the two duct portions. Therefore, if the plug device 200 is pushed backward, the first terminal portion 132 can pass through the opening 16 and enter the rear side of the internal space 11. At this time, with the plug device 200 in the internal space 11, the ground terminal 335 is accommodated in the second recess 213d of the second duct portion 12b (see FIG. 8B). In this state, the mating protrusion 37 is pushed forward by the second duct portion 12b and enters the inside of the main housing 30.

8B and 8C, the entire plug device 200 is moved upward in the vertical direction until the connecting portion 133 of the first terminal portion 132 hits the lower end of the first connection surface 115 of the first duct portion 12a, and the connecting portion 233 of the second terminal portion 232 hits the lower end of the second connection surface 215 of the second duct portion 12b. At this time, when the mating protrusion 37 reaches a position where the opening 16 is located, the mating protrusion 37 can protrude to the outside of the main housing 30. In this way, the first connection terminal 135 is inserted from the internal space 11 of the first duct portion 12a through the first communication port 118 into the first holding space 117, and the second connection terminal 235 is inserted from the open space 110 below the second duct portion 12b through the second communication port 218 into the second holding space 217. As a result, the first connection terminal 135 is sandwiched between the two leaf springs 119 of the corresponding first transmission conductor 120, and the first connection terminal 135 is electrically connected to the first transmission conductor 120, and the second connection terminal 235 is sandwiched between the two leaf springs 219 of the corresponding second transmission conductor 220, and the second connection terminal 235 is electrically connected to the second transmission conductor 220 (see FIG. 8C).

The engaging protrusion 37 may be retracted inward or protruded outward by operating the operating portion 38. For example, by operating the operating portion 38 to push the operating portion 38 into the inside of the main housing 30, as described above, the engaging protrusion 37 enters the inside of the main housing 30, making it easier to move the plug device 200 upward in the vertical direction. Next, by moving the plug device 200 upward and electrically connecting each of the connection terminals 35 to the corresponding transmission conductors 201, and then releasing the pushing of the operating portion 38, the engaging protrusion 37, which has a dimension smaller than the vertical dimension of the opening 16, protrudes again in the rearward direction relative to the main housing 30. As a result, the engaging protrusion 37 fits into the opening 16 between the first duct portion 12a and the second duct portion 12b, and the engaging protrusion 37 can be fitted in the opening 16. That is, the force resisting the biasing mechanism 371 is no longer applied to the mating protrusion 37, and therefore the plug device 200 is prohibited from moving in the vertical direction. The plug device 200 is locked in a state where it is connected to the wiring duct 100. This allows the electrical connection state of each of the connection terminals 35 to be stably maintained, and also makes it difficult for the plug device 200 to accidentally fall off the wiring duct 100.

When removing the plug device 200 from the wiring duct 100, a person first presses the operating portion 38 of the plug device 200 to move the mating protrusion 37 forward, thereby releasing the mating between the mating protrusion 37 and the opening 16. While maintaining this state, the entire plug device 200 is moved downward relative to the wiring duct 100. This causes each of the terminal portions 32 to separate from the corresponding transmission conductors 201, and the first terminal portion 132 can move into the internal space 11 and the second terminal portion 232 can move into the open space 110 through each of the communication openings 18 of the duct portion 12. Next, in this state, when the plug device 200 is moved forward relative to the wiring duct 100, each terminal portion 32 moves to the outside of the wiring duct 100. This allows the plug device 200 to be removed.

In FIG. 3D, the two terminals 32 for the main housing 30 are arranged side by side along the vertical direction passing through the center in the left-right direction of the mounting surface 31, but the two terminals 32 may be arranged side by side along the vertical direction passing through a point other than the center. For example, the two terminals 32 for the main housing 30 may be arranged side by side along the vertical direction passing to the left of the center in the left-right direction, or side by side along the vertical direction passing to the left of the center in the left-right direction, so that the two terminals 32 for the main housing 30 are arranged at different positions from each other in the vertical direction and are arranged side by side on the same axis as the direction in which the connection terminals 35 protrude in the vertical direction passing through a point other than the center in the left-right direction.

In the first embodiment, in a connected state in which the plug device 200 is connected to the wiring duct 100, the dimension of the terminal portion 32 (first terminal portion 132) of the plug device 200 that connects to the duct portion 12 (i.e., the first duct portion 12a) of the two duct portions 12 (12a, 12b) that is opposite to the direction in which the communication port 18 opens, in the direction in which the two duct portions 12 (12a, 12b) are aligned, is less than or equal to the dimension of the gap between the two duct portions 12 (12a, 12b) in a direction perpendicular to both the length direction (left-right direction) of the housing 10 and the direction perpendicular to the installation surface 14. Furthermore, the distance between the two terminal portions 32 (132, 232) in a direction perpendicular to both the length direction (left-right direction) of the housing 10 and the direction perpendicular to the installation surface 14 is equal to or greater than the dimension of the duct portion 12 (i.e., the second duct portion 12b) located on the lower side of the two duct portions 12 (12a, 12b) in a direction perpendicular to both the length direction (left-right direction) of the housing 10 and the direction perpendicular to the installation surface 14. In other words, with reference to FIG. 5 etc., the vertical dimension of the first terminal portion 132 connected to the first duct portion 12a located on the upper side in the vertical direction of the two duct portions 12 (12a, 12b) is equal to or less than the vertical dimension of the gap between the two duct portions 12, and the vertical distance between the two terminal portions 32 (132, 232) is equal to or greater than the vertical dimension of the second duct portion 12b. Therefore, when placing and connecting the plug device 200 in the wiring duct 100, it is easy to place the first terminal portion 32 in the internal space 11 of the first duct portion 12a.

The second embodiment will be described with reference to Figures 9 to 11B.

9 and 10A to 11B show a plug device 200 and a wiring system 300 according to the second embodiment. In the second embodiment, the positional relationship of the two terminals 32 on the mounting surface 31 is different from that of the first embodiment. That is, in the first embodiment, the two terminals 32 (132, 232) are parallel to the mounting surface 31 and are aligned along a direction that is not perpendicular to the direction in which the connection terminals 35 (135, 235) protrude (vertical direction), whereas in the second embodiment, the positions of the two terminals 32 (132, 232) are different in a direction perpendicular to both the direction perpendicular to the mounting surface 31 and the direction in which the connection terminals 35 (135, 235) protrude. Therefore, the same reference numerals are used for the same configurations as in the first embodiment, and detailed descriptions are omitted as appropriate.

The plug device 200 of the second embodiment includes a main housing 30 and two terminal portions 32. The main housing 30 has an attachment surface 31. The attachment surface 31 is the surface opposite to the side (forward-facing side) to which the main housing 30 faces. The two terminal portions 32 (first terminal portion 132, second terminal portion 232) are located opposite the main housing 30 via the attachment surface 31. Each of the two terminal portions 32 (first terminal portion 132, second terminal portion 232) includes a base portion 34 (first base portion 134, second base portion 234) and a connection terminal 35 (first connection terminal 135, second connection terminal 235) protruding from the base portion 34.

Each of the connection terminals 35 protrudes in the same direction parallel to the mounting surface 31. Specifically, each of the connection terminals 35 protrudes upward from the base 24 (134, 234).

The positions of the two connection terminals 35 in the direction in which they protrude (upward) relative to the main housing 30 are different from each other. Furthermore, in the second embodiment, the two terminal portions 32 (132, 232) are arranged so that their positions are different in the direction perpendicular to both the direction perpendicular to the mounting surface 31 and the direction in which the connection terminals 35 protrude. Therefore, the two terminal portions 32 are different in both the up-down position and the left-right position relative to the main housing 30.

In addition, in the second embodiment, in a connected state in which the plug device 200 is connected to the wiring duct 100, the following configuration is provided.

Each of the terminals 32 (132, 232) differs from the others in both the position in the direction perpendicular to both the length direction and the direction perpendicular to the installation surface 14, and in the position in the direction parallel to the length direction of the housing 10.

The dimension of the upper terminal portion 32 (first terminal portion 132) of the duct portions 12 (12a, 12b) in at least one inclination direction that is perpendicular to the installation surface 14 and inclined in a direction different from the direction in which the duct portions 12 are arranged is equal to or less than the dimension in the direction perpendicular to both the length direction of the gap between the two duct portions 12 and the direction perpendicular to the installation surface 14. Specifically, the vertical dimension of the first terminal portion 132 is equal to or less than the vertical dimension of the gap between the first duct portion 12a and the second duct portion 12b. The vertical dimension of the first terminal portion 132 here is the distance from the lower end of the first base portion 134 to the upper end of the first connection terminal 135 when the first connection terminal 135 is arranged facing upward in the vertical direction. The vertical dimension of the gap between the first duct portion 12a and the second duct portion 12b is the distance in the vertical direction from the lower end of the first connection surface 115 of the first duct portion 12a to the upper end of the second connection surface 215 of the second duct portion 12b.

The distance between the terminals 32 (132, 232) in the inclined direction is equal to or greater than the vertical dimension of the duct portion 12 (second duct portion 12b) that is located on the lower side of the duct portions 12 (12a, 12b). Specifically, the distance between the first terminal portion 132 and the second terminal portion 232 when the first terminal portion 132 and the second terminal portion 232 are arranged so as to be positioned at an angle is equal to or greater than the vertical length of the second connection surface 215 of the second duct portion 12b. The distance between the first terminal portion 132 and the second terminal portion 232 here refers to the distance from the lower end of the first terminal portion 132 in the vertical direction to the upper end of the second terminal portion 232 in the vertical direction when the first connection terminal 135 and the second connection terminal 235 are arranged in one direction in the left-right direction.

As a result, in the second embodiment of the plug device 200, when connecting the plug device 200 to the wiring duct 100, the connection state can be achieved by rotating the plug device 200 within the wiring duct 100.

In this embodiment, the dimension of the terminal portion 32 (first terminal portion 132) connected to the duct portion 12 (12a, 12b) on the opposite side to the direction in which the communication port 18 opens (i.e., the first duct portion 12a) is larger than the dimension of the gap between the two duct portions 12 in the direction perpendicular to both the length direction of the housing 10 and the direction perpendicular to the installation surface 14. Specifically, the dimension of the first terminal portion 132 connected to the first duct portion 12a in the front-rear direction is larger than the dimension of the gap between the first duct portion 12a and the second duct portion 12b in the front-rear direction. The dimension of the first terminal portion 132 in the front-rear direction here is the distance from the mounting surface 31 to the rear end of the first base portion 134. Additionally, the front-to-rear dimension of the gap between the first duct portion 12a and the second duct portion 12b is the distance from the opening 16 to the rear end of the internal space 11.

The following provides a more detailed explanation of the method for connecting the plug device 200 to the wiring duct 100 to achieve a connected state, and the method for removing the plug device 200 from the wiring duct 100 in the connected state, in the second embodiment.

In the second embodiment, the two terminal portions 32 (132, 232) are arranged so that their positions are different in the direction perpendicular to both the mounting surface 31 and the direction in which the connection terminal 35 protrudes. Therefore, the plug device 200 can be connected to the wiring duct 100 in a manner different from that of the first embodiment to achieve a connected state. That is, in the second embodiment, the first connection terminal 135 can be electrically connected to the first transmission conductor 120 and the second connection terminal 235 can be electrically connected to the second transmission conductor 220 by rotating the entire plug device 200.

Specifically, for example, a plug device 200 is prepared in which a first connection terminal 135 and a second connection terminal 235 having the same dimensions in the vertical direction of the main body housing 30 are arranged to face each other with respect to the center point of the mounting surface 31.

10A, the plug device 200 is placed in a forward position relative to the wiring duct 100, with the two connection terminals 35 (135, 235) of the plug device 200 parallel to the length of the wiring duct 100, the first connection terminal 135 of the plug device 200 being located on the upper side in the vertical direction, and the second connection terminal 235 being located on the lower side of the first connection terminal 135 in the vertical direction, and the lower end of the first terminal portion 132 being located on the upper side of the upper end of the second duct portion 12b, and the upper end of the second terminal portion 232 being located on the lower side of the lower end of the second connection surface 215 in the second duct portion 12b. In this way, the first terminal portion 132 of the plug device 200 can be placed in the internal space 11 through the opening 16 of the first duct portion 12a of the wiring duct 100. The orientation of the first connection terminal 135 of the first terminal portion 132 and the second connection terminal 235 of the second terminal portion 232 may be in either the left-right direction as long as they face the same direction in the left-right direction. Specifically, the orientation may be such that the first connection terminal 135 is located on the upper side in the vertical direction and on the lower side in the vertical direction of the second connection terminal 235 so that the first connection terminal 135 can be placed in the internal space 11 through the opening 16 between the first duct portion 12a and the second duct portion 12b.

Next, with the first terminal portion 132 placed in the internal space 11, the plug device 200 is rotated so that the vertical position of the upper end of the first terminal portion 132 does not change in this state. In other words, with the first terminal portion 132 in the internal space 11, the plug device 200 is rotated with the upper end of the first terminal portion 132 positioned below the first communication opening 118 of the first duct portion 12a (FIG. 10B). In this case, the upper and lower ends of the second terminal portion 232 are below the second communication opening 218 of the second duct portion 12b, so that even if the plug device 200 is rotated, the second terminal portion 232 does not interfere with the rotation of the plug device 200 by the second outer shell portion 213 of the second duct portion 12b.

As a result, the first connection terminal 135 and the second connection terminal 235 of the plug device 200 are changed from facing either left or right to facing upward. The first connection terminal 135 can then be positioned to face the first communication port 118 of the first duct portion 12a in the vertical direction, and the second connection terminal 235 can be positioned to face the second communication port 218 of the second duct portion 12b in the vertical direction. In this case, as described above, the vertical dimension of the first terminal portion 132 is equal to or less than the vertical dimension of the gap between the first duct portion 12a and the second duct portion 12b, and the distance between the first terminal portion 132 and the second terminal portion 232 when the first terminal portion 132 and the second terminal portion 232 are arranged at an angle is equal to or greater than the vertical length of the second connection surface 215 of the second duct portion 12b. Therefore, even if the plug device 200 is rotated with the first terminal portion 132 in the internal space 11 of the wiring duct 100, the first terminal portion 132 is unlikely to be interfered with by the first outer shell portion 113 of the first duct portion 12a and the second outer shell portion 213 of the second duct portion 12b.

At this time, when the plug device 200 is rotated, each of the connection terminals 35 of each terminal portion 32 is inserted into the holding space 17 through the communication opening 18 (118, 218) of the corresponding holding space 17 (117, 217), and can further enter between the leaf springs 19 (119, 119) (219, 219) of the corresponding transmission conductors 201 (120, 220). As a result, the connection terminals 35 are sandwiched between the leaf springs 19 of the transmission conductors 201, and each of the connection terminals 35 is electrically connected to each of the transmission conductors 201 (FIG. 11A). In this way, by rotating the plug device 200 to connect it to the wiring duct 100, it is possible to easily apply a load when fitting the plug device 200.

When rotating the plug device 200, if the plug device 200 has an engaging protrusion 37, the plug device 200 may be rotated with the operating portion 38 pressed into the inside of the plug device 200. In this case, the plug device 200 can be easily rotated without the engaging protrusion 37 being interfered with by the first duct portion 12a and the second duct portion 12b. At this time, when the engaging protrusion 37 reaches a position where the opening 16 is located, the engaging protrusion 37 can protrude to the outside of the main housing 30.

In this embodiment, as in the first embodiment, the mating protrusion 37 may be retracted inward or protruded outward by operating the operating portion 38. For example, by operating the operating portion 38 to push the operating portion 38 into the inside of the main housing 30, as described above, the mating protrusion 37 enters the inside of the main housing 30, making it easier to move the plug device 200 upward in the vertical direction. Next, by moving the plug device 200 upward and electrically connecting each of the connection terminals 35 to the corresponding transmission conductors 201, and then releasing the pushing of the operating portion 38, the mating protrusion 37, which has a dimension smaller than the vertical dimension of the opening 16, protrudes again in the rearward direction relative to the main housing 30. As a result, the mating protrusion 37 fits into the opening 16 between the first duct portion 12a and the second duct portion 12b, and the mating protrusion 37 can be fitted in the opening 16. Therefore, the vertical movement of the plug device 200 is prohibited. That is, the plug device 200 is locked in a connected state to the wiring duct 100. This allows the electrical connection state of each of the connection terminals 35 to be stably maintained, and also makes it difficult for the plug device 200 to accidentally fall off the wiring duct 100.

9 and 10A to 11B, the first terminal portion 132 is disposed on the left side of the mounting surface 31, and the second terminal portion 232 is disposed on the right side of the mounting surface 31, but this is not limited to the above. For example, the first terminal portion 132 and the second terminal portion 232 may be disposed so that they are positioned in at least one inclined direction that is perpendicular to the installation surface 14 and inclined in a direction different from the direction in which the duct portions 12 (12a, 12b) are arranged. Also, although the terminal portion 132 is rotated in the clockwise direction indicated by the arrow in FIGS. 10A to 11A, the direction of rotation can be changed depending on the direction in which the terminal portion 32 faces.

A modified example of the present disclosure will be described. In the modified example, the same components as those in the above embodiment are denoted by the same reference numerals in the figures. Also, the description of the same components as those in the above embodiment will be omitted as appropriate.

The position of the earth conductor 202 in the wiring duct 100 and the position of the earth terminal 335 in the plug device 200 are not limited to the above description.

For example, in the wiring duct 100, each of the transmission conductors 201 may be composed of one conductor plate. In the plug device 200, each of the terminal parts 32 may have two leaf springs 419 that face each other in the front-rear direction. Specifically, as shown in FIG. 12, each of the conductors 20 (transmission conductors 201) held in the two duct parts 12 in the wiring duct 100 may be one conductor plate 435 having a thickness in the front-rear direction. On the other hand, each of the terminal parts 132 in the plug device 200 that are electrically connected to the conductors 20 held in the duct parts 12 may have two leaf springs 419 that face each other in the front-rear direction as connection terminals. In this case, in the connected state, the conductor 120 of the wiring duct 100 is sandwiched between the two leaf springs 419, thereby realizing a stable electrical connection between the conductor 120 and the connection terminal of the terminal part 32. In FIG. 11, each of the first duct portion 12a and the second duct portion 12b has a conductive plate 435 having a thickness in the front-rear direction, and each of the first terminal portion 132 and the second terminal portion 232 has two leaf springs 419, but this is not limited to the above. For example, either the first duct portion 12 or the second duct portion 12b may have a conductive plate 435 having a thickness in the front-rear direction, or one of the corresponding first terminal portion 132 and the second terminal portion 232 may have two leaf springs 419 facing each other in the front-rear direction as a connection terminal.

The positions of the connector 36 and the socket 136 in the plug device 200 are not limited to those described above.

The wiring duct 100 may include a third duct portion that holds the earth conductor 202, for example, in the direction in which the two duct portions 12 (12a, 12b) are aligned (the vertical direction). In this case, for example, the third duct portion may have a configuration in which the transmission conductor 201 in the first duct portion 12a and the second duct portion 12b is changed to the earth conductor 202. When the wiring duct 100 includes a third duct portion that holds the earth conductor 202, the positional relationship in the vertical direction between the first duct portion 12a, the second duct portion 12b, and the third duct portion may be adjusted as appropriate.

Each of the connection terminals 35 may have a chamfered inclined surface on each edge on both sides of the thickness direction of the connection terminal 251 at each end in a direction perpendicular to both the thickness direction of the connection terminal 35 and the direction in which the connection terminal 35 protrudes. In this case, the inclined surface may be, for example, a flat surface or a curved surface. When each of the connection terminals 35 has the above-mentioned inclined surface, for example, in the second embodiment of the wiring system 300, when the connection state is realized by rotating the entire plug device 200 relative to the duct 100, the connection terminals 35 can smoothly enter between the leaf springs 19.

Also, for example, in the second embodiment, the dimensions of the terminal portion 32 of the plug device 200 and the gap between the first duct portion 12a and the duct portion 12b of the wiring duct 100 may be adjusted to connect the plug device 200 to the wiring duct 100 in the same manner as in the first embodiment to achieve a connected state. That is, when connecting the plug device 200 to the wiring duct 100, the first terminal portion 132 is inserted into the internal space 11 of the first duct portion 12a of the housing 10 through the opening 16, the first connecting portion 133 is disposed in the opening 16, and the second terminal portion 232 is located in the open space 110 below the lower end of the second connecting surface 215 of the second duct portion 12b of the housing 10, and the plug device 200 is moved upward to achieve a connected state. As described above, in the second embodiment, the positional relationship of the two terminals 32 is different from that in the first embodiment, but the cross section when viewed from the side (one side in the left-right direction) can be the same as that shown in Figures 8A to 8C. Therefore, it is possible to connect the plug device 200 to the wiring duct 100 in the same manner as described in the first embodiment.

In addition, in the second embodiment, by adjusting the dimensions of the terminal portion 32 of the plug device 200 and the gap between the first duct portion 12a and the duct portion 12b of the wiring duct 100, the plug device 200 may be connected to the wiring duct 100 by rotating the plug device 200 and then moving it upward in the vertical direction in a manner different from that described above. For example, first, the plug device 200 is disposed in a position facing forward with respect to the wiring duct 100, with the overall posture of the plug device 200 with respect to the wiring duct 100 such that the two connection terminals 35 (135, 235) of the plug device 200 are parallel to the length direction of the wiring duct 100, the first connection terminal 135 of the plug device 200 is positioned on the upper side in the vertical direction, and the second connection terminal 235 is positioned on the lower side of the first connection terminal 135 in the vertical direction, and the lower end of the first terminal portion 132 is positioned on the upper side of the upper end of the second duct portion 12b, and the upper end of the second terminal portion 232 is positioned on the lower side of the lower end of the second connection surface 215 of the second duct portion 12b. In this manner, the first terminal portion 132 of the plug device 200 can be disposed in the internal space 11 through the opening 16 of the first duct portion 12a of the wiring duct 100. The orientation of the first connection terminal 135 of the first terminal portion 132 and the second connection terminal 235 of the second terminal portion 232 may be in either direction along the length (left-right direction). For example, the orientation may be such that the first connection terminal 135 is located on the top side in the vertical direction and the second connection terminal 235 is located on the bottom side in the vertical direction so that the first connection terminal 135 can be placed in the internal space 11 through the opening 16 between the first duct portion 12a and the second duct portion 12b.

Next, the plug device 200 is pushed backward until the mounting surface 31 of the plug device 200 comes into contact with the connection surface 15 (first connection surface 115 and second connection surface 215) of the wiring duct 100. In this case, the first terminal portion 132 of the plug device 200 enters the internal space 11 from the opening 16, and the lower end of the first terminal portion 132 can be positioned in the opening 16.

Next, the entire plug device 200 is rotated with the first terminal portion 132 in the internal space 11. This changes the state in which the first connection terminal 135 and the second connection terminal 235 of the plug device 200 face either left or right to a state in which they face upward in the vertical direction. By rotating in this manner, the first connection terminal 135 can be positioned in a position facing the first communication port 118 of the first duct portion 12a in the vertical direction, and the second connection terminal 235 can be positioned in a position facing the second communication port 218 of the second duct portion 12b in the vertical direction. At this time, when the mating protrusion 37 reaches a position where the opening 16 is located, the mating protrusion 37 can protrude to the outside of the main housing 30. The direction in which the plug device 200 is rotated is not limited to the above, and may be changed as appropriate depending on the position of the first terminal portion 132 and the direction in which the first connection terminal 135 faces.

At this time, when rotating the plug device 200, if the plug device 200 has a mating protrusion 37, the plug device 200 may be rotated with the operating portion 38 pressed into the inside of the plug device 200. In this case, the plug device 200 can be easily rotated without the mating protrusion 37 interfering with the first duct portion 12a and the second duct portion 12b.

Next, with the first connection terminal 135 and the second connection terminal 235 facing upward, the entire plug device 200 is moved upward in the vertical direction until the first coupling portion 133 (133) of the first terminal portion 132 abuts against the lower end of the first connection surface 115 in the first duct portion 12a, and the second coupling portion 33 (233) of the second terminal portion 232 abuts against the lower end of the second connection surface 215 in the second duct portion 12b. At this time, when the mating protrusion 37 reaches a position where the opening 16 is located, the mating protrusion 37 can protrude outside the main housing 30. If the mating protrusion 37 is present, the pressing of the operating portion 38 is released. In this way, the first connection terminal 135 is inserted into the first holding space 117 from the internal space 11 in the first duct portion 12a through the first communication port 118, and the second connection terminal 235 is inserted into the second holding space 217 from the open space 110 below the second duct portion 12b through the second communication port 218.

As a result, the first connection terminal 135 is sandwiched between the two leaf springs 119 of the corresponding first transmission conductor 120, and the first connection terminal 135 is electrically connected to the first transmission conductor 120, and the second connection terminal 235 is sandwiched between the two leaf springs 219 of the corresponding second transmission conductor 220, and the second connection terminal 235 is electrically connected to the second transmission conductor 220.

In addition, in this modified example, as in the first embodiment, the fitting protrusion 37 may be retracted inward or protruded outward by operating the operating portion 38. In this case, too, the electrical connection state of each of the connection terminals 35 can be stably maintained, and the plug device 200 is less likely to accidentally fall off the wiring duct 100.

In addition to the above, the number, type, and position of the duct portion 12 and conductors 20 of the wiring duct 100 can be set as appropriate. Accordingly, the number, type, and position of the terminal portions 32 of the plug device 200 can also be set as appropriate. Furthermore, the shape of the conductors 20 of the wiring duct 100 and the shape of the terminal portions 32 of the plug device 200 are not limited to the above description.

(summary)
As is apparent from the above-described embodiment, the present disclosure includes the following aspects. In the following, reference symbols are given in parentheses only to clarify the correspondence with the embodiment.

The wiring duct (100) of the first aspect comprises a long housing (10) and a plurality of conductors (20) held within the housing (10). The outer surface of the housing (10) includes an installation surface (14) parallel to the length direction, and the housing (10) comprises two duct sections (12). Each of the duct sections (12) is long in the length direction of the housing (10). The two duct sections (12) are arranged at intervals in a direction perpendicular to both the length direction and the direction perpendicular to the installation surface (14). Each of the duct sections (12) comprises a holding space (17) and a communication port (18) that opens on a surface facing one of the directions perpendicular to both the length direction of the duct section (12) and the direction perpendicular to the installation surface (14) and communicates the holding space (17) with the outside of the duct section (12). The conductor (20) includes a transmission conductor (201 (120, 220)) held in the holding space (17) in each of the two duct sections (12).

According to this aspect, the thickness of the duct portion (12) in the wiring duct (100) can be reduced.

In the second aspect of the wiring duct (100), in the first aspect, each of the transmission conductors (201) held in the holding space (17) of the duct portion (12) is provided with two leaf springs (19) that face each other in a direction perpendicular to the installation surface (14).

In the third aspect of the wiring duct (100), in the first aspect, each of the transmission conductors (201 (120, 220)) is composed of a single conductor plate.

This aspect can contribute to reducing the thickness of the duct portion (12) in the wiring duct (100).

The plug device (200) according to the fourth aspect is connected to a wiring duct (100). The plug device (200) comprises a main housing (30) and two terminal portions (32 (132, 232)). The main housing (30) has an attachment surface (31). The two terminal portions (32 (132, 232)) are positioned opposite the main housing (30) via the attachment surface (31). Each of the terminal portions (32) comprises a base (34) and a connection terminal (35) protruding from the base (34). The connection terminal (35) protrudes in the same direction in one direction parallel to the attachment surface (31). The positions of the two connection terminals (35 (135, 235)) in the direction in which they protrude relative to the main housing (30) are different from each other.

According to this aspect, the thickness of the plug device (200) can be reduced. This makes it possible to provide a wiring system (300) in which the thickness of the duct portion (12) of the wiring duct (100) is reduced.

In the plug device (200) according to the fifth aspect, in the fourth aspect, the two terminal portions (32 (132, 232)) are parallel to the mounting surface (31) and are aligned along a direction that is not perpendicular to the direction in which the connection terminal (35 (135, 235)) protrudes.

According to this embodiment, when connecting the plug device (200) to the wiring duct (100), the connection state can be achieved only by moving the plug device (200) in the direction in which the connection terminal (35) of the plug device (200) faces.

In the plug device (200) according to the sixth aspect, in the fourth or fifth aspect, the two terminal portions (32 (132, 232)) are different in position in a direction perpendicular to both the direction perpendicular to the mounting surface (31) and the direction in which the connection terminal (35) protrudes.

According to this aspect, when connecting the plug device (200) to the wiring duct (100), the connected state can be achieved by rotating the plug device (200).

The seventh aspect of the plug device (200) is any one of the fourth to sixth aspects, in which each of the terminal portions (32 (132, 232)) is composed of a single conductive plate.

According to this aspect, the thickness of the plug device (200) can be reduced, and therefore it can be applied to a wiring duct (100) in which the thickness of the duct portion (12) in the wiring duct (100) is reduced.

The plug device (200) of the eighth aspect is any one of the fourth to seventh aspects, in which each of the terminal portions (32 (132, 232)) has two leaf springs (19) that face each other in a direction perpendicular to the mounting surface (31).

The wiring system (300) according to the ninth aspect comprises the wiring duct (100) according to the first aspect and a plug device (200) according to any one of the fourth to eighth aspects.

According to this aspect, a wiring system (300) can be provided that can reduce the thickness of the wiring duct (100).

In the wiring system (300) of the tenth aspect, in the ninth aspect, the plug device (200) is arranged so that the main body housing (30) is disposed outside the wiring duct (100) in a connected state in which the plug device (200) is connected to the wiring duct (100). The connection terminals (35) are each electrically connected to the transmission conductors (201).

According to this embodiment, when connecting the plug device (200) to the wiring duct (100), the connection state can be achieved only by moving the plug device (200) in the direction in which the connection terminal (35) of the plug device (200) faces.

In the wiring system (300) of the eleventh aspect, in the ninth or tenth aspect, in the connected state, the plug device (200) has a terminal portion (32) that connects to the duct portion (12) that is opposite to the direction in which the communication port (18) opens, and the dimension in the direction in which the duct portions (12) are lined up is less than or equal to the dimension of the gap between the two duct portions (12 (12a, 12b)) in a direction perpendicular to both the length direction and the direction perpendicular to the installation surface (14). Furthermore, the distance between the terminal portions (32 (132, 232)) in a direction perpendicular to both the length direction and the direction perpendicular to the installation surface (14) is equal to or greater than the dimension of the duct portion (12) on the same side as the opening of the communication port (18) in a direction perpendicular to both the length direction and the direction perpendicular to the installation surface (14).

According to this embodiment, when connecting the plug device (200) to the wiring duct (100), the connection state can be achieved only by moving the plug device (200) in the direction in which the connection terminal (35) of the plug device (200) faces.

In the wiring system (300) of the twelfth aspect, in any one of the ninth to eleventh aspects, in the connected state, each of the terminal parts (32 (132, 232)) differs in position in a direction perpendicular to both the length direction and the direction perpendicular to the installation surface (14) and in a direction parallel to the length direction. The dimension of the upper terminal part (32) in at least one inclination direction perpendicular to the installation surface (14) and inclined in a direction different from the direction in which the duct parts (12) are arranged is equal to or smaller than the dimension of the gap between the two duct parts (12 (12a, 12b)) in a direction perpendicular to both the length direction and the direction perpendicular to the installation surface (14). The distance between the terminal parts (32 (132, 232)) in the inclination direction is equal to or larger than the dimension of the duct part (12) located on the lower side of the duct parts (12 (12a, 12b)) in the up-down direction.

According to this embodiment, when connecting the plug device (200) to the wiring duct (100), the connected state can be achieved only by rotating the plug device (200).

The configurations according to the second and third aspects are not essential for the wiring duct (100) and may be omitted as appropriate. The configurations according to the fifth to eighth aspects are not essential for the plug device (200) and may be omitted as appropriate. The ninth to twelfth aspects are aspects that may be implemented alone, and may be applied to the wiring system (300) of any of the ninth to twelfth aspects.

REFERENCE SIGNS LIST 100 Wiring duct 10 Housing 11 Internal space 12 Duct portion 14 Installation surface 17 Retaining space 18 Communication port 19 Leaf spring 20 Conductor 201 Transmission conductor 200 Plug device 30 Main body housing 31 Mounting surface 32 Terminal portion 34 Base portion 35 Connection terminal 300 Wiring system

Claims (12)

The device includes an elongated housing and a plurality of conductors held within the housing,
The outer surface of the housing includes an installation surface parallel to a longitudinal direction, and the housing includes two duct portions;
Each of the duct portions is elongated in a longitudinal direction of the housing,
The two duct portions are arranged at an interval in a direction perpendicular to both the length direction and a direction perpendicular to the installation surface,
Each of the duct sections includes a holding space and a communication port that opens on a surface facing one of a direction perpendicular to both the length direction of the duct section and a direction perpendicular to the installation surface, and communicates the holding space with the outside of the duct section,
the conductor includes a transmission conductor held in the holding space in each of the two duct portions;
Wiring duct. Each of the transmission conductors held in the holding space of the duct portion includes two leaf springs facing each other in a direction perpendicular to the installation surface.
The wiring duct according to claim 1 . Each of the transmission conductors is composed of one conductor plate.
The wiring duct according to claim 1 . A plug device that is connected to a wiring duct,
The plug device includes a main housing having a mounting surface and two terminal portions located opposite the main housing with the mounting surface interposed therebetween,
Each of the terminal portions includes a base portion and a connection terminal protruding from the base portion,
The connection terminals protrude in the same direction parallel to the mounting surface,
The positions of the terminal portions relative to the main body housing in a direction in which the connection terminals protrude are different from each other.
Plug device. The two terminal portions are parallel to the mounting surface and aligned along a direction not perpendicular to a direction in which the connection terminal protrudes.
5. The plug device of claim 4. The two terminal portions are located at different positions in a direction perpendicular to both the mounting surface and the direction in which the connection terminal protrudes.
5. The plug device of claim 4. Each of the terminal portions is formed of a single conductive plate.
5. The plug device of claim 4. Each of the terminal portions includes two leaf springs facing each other in a direction perpendicular to the mounting surface.
5. The plug device of claim 4. The wiring duct according to claim 1 and the plug device according to claim 4,
Wiring system. the main body housing is disposed outside the wiring duct in a connected state in which the plug device is connected to the wiring duct;
In the connected state, the connection terminals are electrically connected to the transmission conductors, respectively.
The wiring system according to claim 9. In the connected state,
The plug device comprises:
a dimension of the terminal portion connected to one of the duct portions facing opposite to the direction in which the communication port is opened, in a direction in which the duct portions are arranged, is equal to or smaller than a dimension of a gap between the two duct portions in a direction perpendicular to both the length direction and the direction perpendicular to the installation surface;
and a distance between the terminal portions in a direction perpendicular to both the length direction and the direction perpendicular to the installation surface is equal to or greater than a dimension of a duct portion on the same side as the opening of the communication port in a direction perpendicular to both the length direction and the direction perpendicular to the installation surface.
The wiring system according to claim 9. In the connected state,
the terminal portions are different from one another in positions in a direction perpendicular to both the length direction and a direction perpendicular to the installation surface, and in positions in a direction parallel to the length direction;
a dimension of the upper terminal portion in at least one inclined direction that is perpendicular to the installation surface and inclined in a direction different from the direction in which the duct portions are arranged is equal to or smaller than a dimension of a gap between the two duct portions in a direction perpendicular to both the length direction and the direction perpendicular to the installation surface;
a distance between the terminal portions in the inclination direction is equal to or greater than a dimension of a lower one of the duct portions in the up-down direction;
The wiring system according to claim 9.

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