JP2025008544A - Adapters and fixtures - Google Patents

Abstract

To provide an adapter capable of suppressing taking-out of the adapter from a wiring duct.SOLUTION: An adapter 2 is attached to a wiring duct 31 of a wiring duct system 3 supplying a power, is connected with a connector 8, and transmits the power to the connector 8 from the wiring duct 31. The adapter 2 comprises: a shaft part 21 that is formed in the wiring duck 31, and is inserted into an open part 32 extending in a long direction of the wiring duck 31; two power reception terminals 22 that project opposite to each other from the shaft part 21, and receive a supply of the power by being connected to a pair of electrodes 34 provided to both ends of a width direction of the wiring duct 31; and a fixing rib 23 that project from the shaft part 21 centered on the shaft part 21. The two power reception terminals 22 are positioned along the long direction in the case where the supply of the power is not received. In the case where the supply of the power is not received, the length L23 between both ends of the fixing rib 23 in the width direction is longer than the width W32 of the open part 32 in view from a depth direction that is orthogonal to both of the length direction and the width direction.SELECTED DRAWING: Figure 1

Description

This disclosure relates generally to adapters and fixtures, and more particularly to adapters and fixtures applied to wiring duct systems.

Patent Document 1 discloses an adapter. This adapter is detachable from a DC duct of a DC duct system that supplies DC power, and a connector is connected to the adapter. The adapter includes an adapter main body and a regulating section.

Here, the adapter body sends DC power to the connector. The restriction unit is stored or held in the adapter body and restricts removal of the adapter body from the DC duct system. The restriction unit further has a lock unit that switches between a locked state and an unlocked state using a specific key, and restricts removal of the adapter body when the lock unit is in the locked state.

JP 2022-086852 A

However, in Patent Document 1, when the electrical connection between the adapter and the DC duct is released in the unlocked state, the adapter can be removed from the DC duct. Thus, in Patent Document 1, there was a problem that the adapter could be removed from the DC duct in the unlocked state.

The objective of this disclosure is to provide an adapter and fixture that can prevent the adapter from being removed from a wiring duct.

The adapter according to one aspect of the present disclosure is attached to a wiring duct of a wiring duct system that supplies electric power, and a connector is connected to send the electric power from the wiring duct to the connector. The adapter includes an axis portion that is inserted into an opening formed in the wiring duct and extending in the longitudinal direction of the wiring duct, two power receiving terminals that protrude in opposite directions from the axis portion and are connected to a pair of electrodes provided at both ends in the width direction of the wiring duct to receive the supply of electric power, and a fixed rib that protrudes from the axis portion with the axis portion as the center. When the power is not being supplied, the two power receiving terminals are located along the longitudinal direction. When the power is not being supplied, the length between both ends of the fixed rib in the width direction is longer than the width of the opening when viewed from a depth direction perpendicular to both the longitudinal direction and the width direction.

A fixture according to one aspect of the present disclosure includes the adapter and the wiring duct system.

This disclosure makes it possible to prevent the adapter from being removed from the wiring duct.

FIG. 1 is a perspective view (including a partial cross section) of a main portion of an adapter and a wiring duct system according to the present embodiment in a power supply state. FIG. 2 is a perspective view (including a partial cross section) of the adapter and the main part of the wiring duct system in a state where no power is supplied. FIG. 3 is a side view (including a partial cross section) of the adapter and the main part of the wiring duct system in a power supply state. FIG. 4 is a side view (including a partial cross section) of the adapter and the main part of the wiring duct system in a state where no power is supplied. FIG. 5 is a rear view of the main part of the adapter in a power supply state. FIG. 6 is a rear view of the main parts of the adapter in a state where no power is being supplied. FIG. 7 is a side view of a main portion of an adapter according to a modified example (the wiring duct system is omitted) in a power supply state. FIG. 8 is a side view of the main part of the adapter (the wiring duct system is omitted) in a state where no power is supplied. FIG. 9 is a rear view of the main part of the adapter in a power supply state. FIG. 10 is a rear view of the main parts of the adapter in a state where no power is being supplied. FIG. 11 is a rear view of the main parts of the adapter according to the reference example in a power supply state. FIG. 12 is a rear view of the main parts of the adapter in a state where no power is being supplied. FIG. 13 is a perspective view showing the fixture according to this embodiment. FIG. 14 is a block diagram showing an example of the configuration of a system that supplies power to an electric device using the adapter and wiring duct system according to this embodiment. FIG. 15 is a perspective view showing a main part of the wiring duct system according to the present embodiment. FIG. 16 is a perspective view showing the wiring duct system with the detachable cover separated therefrom. FIG. 17 is a perspective view showing the wiring duct system with the end cap further separated. FIG. 18 is a front view showing a main part of the wiring duct system. FIG. 19 is an exploded front view showing a main part of the wiring duct system. FIG. 20 is a cross-sectional view showing a main part of the wiring duct system.

1. Overview The adapter 2, wiring duct system 3, and fixture 1 according to the present embodiment will be described below with reference to the drawings. The following embodiments are merely a portion of the various embodiments of the present disclosure. The following embodiments can be modified in various ways depending on the design, etc., as long as the object of the present disclosure can be achieved. The figures referred to in the following embodiments are schematic diagrams, and the size and thickness ratios of the components in the figures do not necessarily reflect the actual dimensional ratios. The following embodiments, modified examples, and reference examples may be realized in appropriate combinations.

In the following figures, the arrows indicating the up-down, left-right, and front-to-back directions are merely there to make the explanation easier to understand, and have no substance. Unless otherwise specified below, the "width direction" corresponds to the up-down direction, the "longitudinal direction" and "one direction" correspond to the left-to-right direction, and the "depth direction" corresponds to the front-to-back direction.

As shown in FIG. 1, the adapter 2 according to this embodiment is attached to a wiring duct 31 of a wiring duct system 3 that supplies power. Furthermore, as shown in FIG. 14, a connector 8 is connected to the adapter 2. Then, the wiring duct system 3 sends power from the wiring duct 31 to the connector 8 via the adapter 2. This allows an electrical device 9 connected to the connector 8 to receive power.

One of the features of the adapter 2 shown in Figures 1 to 6 is that it is difficult to remove from the wiring duct 31 along the front-to-rear direction. Conversely, therefore, it is also difficult to attach the adapter 2 to the wiring duct 31 along the front-to-rear direction. However, it is possible to remove or attach the adapter 2 from one end of the wiring duct 31 in the left-to-right direction.

Figures 1, 3 and 5 show the power supply state. The power supply state is a state in which power is supplied from the wiring duct 31 to the adapter 2. That is, as shown in Figure 3, the electrode 34 of the wiring duct 31 and the power receiving terminal 22 of the adapter 2 are electrically connected. In this power supply state, the fixing rib 23 of the adapter 2 is fitted into the fitting portion 37 of the wiring duct 31. In other words, as shown in Figure 5, the length L23 between both ends of the fixing rib 23 of the adapter 2 is longer than the width W32 of the opening 32 of the wiring duct 31. Therefore, it is difficult to pull the adapter 2 forward relative to the wiring duct 31.

2, 4, and 6 show the non-power supply state. The non-power supply state is a state in which no power is supplied from the wiring duct 31 to the adapter 2. That is, as shown in FIG. 4, the electrode 34 of the wiring duct 31 and the power receiving terminal 22 of the adapter 2 are not electrically connected. Even in this non-power supply state, the fixing rib 23 of the adapter 2 is engaged with the engagement portion 37 of the wiring duct 31. In other words, as shown in FIG. 6, the length L23 between both ends of the fixing rib 23 of the adapter 2 is longer than the width W32 of the opening 32 of the wiring duct 31. Therefore, it is difficult to pull the adapter 2 forward relative to the wiring duct 31.

As such, in this embodiment, the adapter 2 is difficult to pull forward relative to the wiring duct 31 in both the power supply state and the power non-supply state.

Therefore, according to this embodiment, it is possible to prevent the adapter 2 from being removed from the wiring duct 31.

Note that Figures 11 and 12 show the adapter 2 according to the reference example.

Figure 11 shows the power supply state. In this power supply state, the length L23 between both ends of the fixing rib 23 of the adapter 2 is longer than the width W32 of the opening 32 of the wiring duct 31. Therefore, it is difficult to pull the adapter 2 forward from the wiring duct 31.

On the other hand, FIG. 12 shows the state in which no power is being supplied. In this state in which no power is being supplied, the length L23 between both ends of the fixing rib 23 of the adapter 2 is slightly shorter than the width W32 of the opening 32 of the wiring duct 31. Therefore, it is easy to pull the adapter 2 forward relative to the wiring duct 31.

As such, in the case of the adapter 2 according to the reference example, when power is being supplied, it is difficult to pull the adapter 2 forward relative to the wiring duct 31, but when power is not being supplied, it is easy to pull the adapter 2 forward relative to the wiring duct 31.

Therefore, the adapter 2 in the reference example is more likely to be removed from the wiring duct 31 than the adapter 2 in this embodiment.

2. Details (1) Adapter First, the adapter 2 according to this embodiment will be described with reference to FIGS.

The adapter 2 includes a housing 24, an operating unit 25, an attachment protrusion 26, two power receiving terminals 22, a spring housed in the housing 24, and a lid 27. The adapter 2 further includes a pair of connection connectors (USB sockets) and a circuit board, etc., housed in the housing 24. Here, the housing 24, attachment protrusion 26, two power receiving terminals 22, a pair of connection connectors, a circuit board, the lid 27, etc. of the adapter 2 constitute the adapter main body 20.

The housing 24 is made of resin, for example. The housing 24 is a hollow box with one side (rear side) open. The lid portion 27 is attached to the housing 24 by screwing or the like so that the open side of the housing 24 is covered by the lid portion 27 (see Figures 5 and 6). The outer shape of the housing 24 is a rectangular parallelepiped. The housing 24 has a first socket 241 and a second socket 242. The first socket 241 is a socket for a USB Type-A plug as the connector 8 (see Figure 14). The second socket 242 is a socket for a USB Type-C plug as the connector 8. In other words, the first socket 241 has a different standard from the second socket 242. The first socket 241 is a different size from the second socket 242. In the housing 24, the pair of connection connectors are mounted on a circuit board so as to correspond one-to-one with the first socket 241 and the second socket 242, respectively. The connector 8 inserted into the first socket 241 or the second socket 242 is connected to the corresponding one of the pair of connection connectors and is electrically connected to the power receiving terminal 22 via the circuit board.

The first socket 241 and the second socket 242 are provided on the surface (connector mounting surface 201: the front surface in FIG. 1, etc.) facing away from the wiring duct 31 when the adapter 2 is attached to the wiring duct 31. When the adapter 2 is attached to the wiring duct 31, the first socket 241 and the second socket 242 are lined up one above the other as shown in FIG. 1, etc.

The lid portion 27 is made of, for example, resin. An attachment protrusion 26 is provided on the rear surface of the lid portion 27 (see Figures 3 to 6). The lid portion 27 and the attachment protrusion 26 are formed as a continuous, integrated unit. The attachment protrusion 26 includes a shaft portion 21 and a fixing rib 23.

The shaft portion 21 protrudes from the housing 24 on the side opposite the connector mounting surface 201. The shaft portion 21 is inserted into the opening 32 of the wiring duct 31 (see Figures 3 and 4). The central axis of the shaft portion 21 roughly coincides with the rotation axis B1. The adapter 2 can be rotated a predetermined angle (e.g., 90 degrees) with respect to the wiring duct 31 around the rotation axis B1. Note that the rotation axis B1 is an imaginary axis.

The fixed rib 23 protrudes from the side of the shaft portion 21. Specifically, as shown in Figs. 3 to 6, the fixed rib 23 protrudes from the shaft portion 21 with the shaft portion 21 as the center. In other words, the fixed rib 23 protrudes radially outward from an imaginary circle centered on the rotation axis B1.

In this embodiment, the fixed rib 23 protrudes from the entire circumference of the shaft portion 21. The fixed rib 23 has a thick portion 234 and a thin portion 235 (see Figures 3 to 6). The thickness of the thin portion 235 is thinner than the thickness of the thick portion 234. The thin portion 235 exists on a part of the outer circumference of the fixed rib 23. The thin portion 235 includes a first edge portion 231, a second edge portion 232, and a third edge portion 233. The first edge portion 231 is a portion that extends in one direction with a constant width. The second edge portion 232 is a portion that has the same width as the first edge portion 231 and extends in a direction perpendicular to the first edge portion 231. The third edge portion 233 is a portion that has the same width as the first edge portion 231 and the second edge portion 232 and forms an arc shape that smoothly connects the first edge portion 231 and the second edge portion 232.

Furthermore, in this embodiment, when no power is supplied (i.e., in the case of the power non-supply state shown in Figures 4 and 6), the length L23 between both ends of the fixed rib 23 in the width direction is longer than the width W32 of the opening 32 when viewed from the depth direction (front-to-back direction) perpendicular to both the longitudinal direction and the width direction (see Figure 6).

More specifically, in this embodiment, the length L23 between both ends of the fixed rib 23 in any radial direction centered on the shaft portion 21 is longer than the width W32 of the opening 32. In other words, when viewed along the front-rear direction, the distance between two intersections between any straight line intersecting the rotation axis B1 and the outer periphery of the fixed rib 23 is longer than the width W32 of the opening 32.

The two power receiving terminals 22 protrude in opposite directions from the shaft portion 21. Specifically, in a plane perpendicular to the front-rear direction, the two power receiving terminals 22 protrude in opposite directions (see Figures 5 and 6). The length L23 between both ends of the fixing rib 23 in the direction in which the two power receiving terminals 22 protrude (the up-down direction in Figure 5) is longer than the width W32 of the opening 32. The two power receiving terminals 22 are electrically connected to the circuit board. The adapter 2 receives power from the wiring duct 31 through the two power receiving terminals 22 (see Figure 3).

The adapter 2 has a restricting recess 28 (see Figures 5 and 6). The restricting recess 28 is composed of a recess formed in the rear end face of the housing 24 and in the surface of the cover portion 27. Specifically, the restricting recess 28 includes a first recess 281 and a second recess 282.

The first recess 281 is formed by lowering a portion of the rear end surface of the housing 24 in the direction toward the connector mounting surface 201. In Figures 5 and 6, the area of the first recess 281 is shown by dark dot hatching for ease of understanding.

The second recess 282 is formed by lowering a portion of the surface of the cover 27 in a direction approaching the connector mounting surface 201. In Figs. 5 and 6, for ease of understanding, the area of the second recess 282 is shown by light dot hatching and a portion surrounded by light dot hatching. The bottom surface of the first recess 281 and the bottom surface of the second recess 282 are substantially flush with each other.

The operation unit 25 is configured to be insertable and removable from the opening 32, and configured to restrict the rotation of the adapter 2 by inserting it into the opening 32. The operation unit 25 is held by the housing 24. The operation unit 25 is made of, for example, resin. The operation unit 25 is plate-shaped. The operation unit 25 has a non-slip portion 251 on its surface, and is held by the housing 24 in a manner in which the surface with the non-slip portion 251 is exposed from one side of the housing 24. The operation unit 25 can slide in a predetermined direction (front-back direction in FIG. 1) by applying force to the non-slip portion 251 with a person's fingertip or the like. The operation unit 25 is held by the housing 24 in a state in which the return force of a spring stored in the housing 24 acts in a direction (rearward) away from the connector mounting surface 201. Therefore, when no force is applied to the operation unit 25, the tip portion (claw portion 250) of the operation unit 25 protrudes from the housing 24 to the opposite side to the connector mounting surface 201 side. When a person applies a force forward against the spring force with a fingertip or the like against the anti-slip portion 251, the operation portion 25 slides forward.

The adapter 2 further includes a power converter. A number of electronic components constituting the power converter are mounted on a circuit board inside the housing 24. The power converter converts the power received at the two power receiving terminals 22 into power of a desired voltage. The power converted by the power converter is output from a pair of connection connectors (USB sockets). An electrical device 9 (see FIG. 14) can receive power via a cable including a connector 8 (see FIG. 14) that is inserted into the first socket 241 or the second socket 242 and connected to the connection connector.

(2) Wiring Duct System Next, the wiring duct system 3 according to this embodiment will be described with reference to FIGS.

The wiring duct system 3 is used, for example, as a part of the fixture 1 (described later). The wiring duct system 3 includes a wiring duct 31, an end cap 5, and a removable cover 6. Note that although the base 4 is illustrated in Figures 15 to 20, the base 4 will be described later.

The wiring duct 31 is a member that extends in one direction. Thus, the wiring duct 31 extends in the longitudinal direction (left-right direction in this embodiment). The wiring duct 31 has a duct rail 35 and a pair of electrodes 34. The duct rail 35 includes a first rail 351 and two second rails 352.

The first rail 351 has a rectangular cylindrical shape. The first rail 351 is made of, for example, metal. The first rail 351 extends in the longitudinal direction (left-right direction).

The first rail 351 includes an opening 32. The opening 32 is formed along the longitudinal direction (left-right direction) of the duct rail 35. More specifically, the opening 32 is formed across both ends of the longitudinal direction of the duct rail 35. In this way, the opening 32 is formed in the wiring duct 31 and extends in the longitudinal direction (left-right direction) of the wiring duct 31.

In this embodiment, the opening 32 opens toward the front. The width W32 of the opening 32 is narrower than the width W31 of the wiring duct 31 (see Figures 5 and 6). The width W31 of the wiring duct 31 is equal to the width of the duct rail 35 and the width of the first rail 351.

The first rail 351 further has a restricting protrusion 39. The restricting protrusion 39 is a protrusion. The restricting protrusion 39 is provided on the lower part of the first rail 351. The restricting protrusion 39 is inserted into the restricting recess 28 of the adapter 2.

The wiring duct 31 has end openings 36 at both ends in the longitudinal direction (left-right direction). One end opening 36 opens to the right, and the other end opening 36 opens to the left. The two end openings 36 are connected to the opening 32.

As shown in Figures 3 and 4, the first rail 351 further includes two fitting portions 37 and two mounting grooves 38.

Each of the two fitting portions 37 is a groove. The two fitting portions 37 are provided on the inner surface of the duct rail 35 (first rail 351). The two fitting portions 37 face each other in the up-down direction. The two fitting portions 37 are formed along the longitudinal direction (left-right direction) of the duct rail 35. More specifically, the two fitting portions 37 are formed across both ends of the longitudinal direction of the duct rail 35.

As shown in Figures 3 and 4, the widths (groove widths) of the two fitting portions 37 are different. The width of one (upper) fitting portion 37 is approximately equal to the thickness of the thick portion 234 of the fixed rib 23. The other (lower) fitting portion 37 has a wide portion 371 and a narrow portion 372. The width of the narrow portion 372 is narrower than the width of the wide portion 371. The narrow portion 372 is connected to the wide portion 371 in the vertical direction. The width of the wide portion 371 is approximately equal to the thickness of the thick portion 234 of the fixed rib 23. The width of the narrow portion 372 is approximately equal to the thickness of the thin portion 235 of the fixed rib 23.

The two fitting portions 37 fit into the fixing ribs 23 of the adapter 2. This allows the adapter 2 to be attached to the wiring duct 31. That is, the duct rail 35 (first rail 351) includes an adapter attachment portion (two fitting portions 37) for attaching the adapter 2. The procedure for attaching the adapter 2 to the wiring duct 31 will be described later.

The two mounting grooves 38 are provided on the inner surface of the duct rail 35 (first rail 351). The two mounting grooves 38 face each other in the vertical direction. Of the two fitting portions 37 and the two mounting grooves 38, the two fitting portions 37 are provided closer to the opening 32. The two mounting grooves 38 are formed along the longitudinal direction (left-right direction) of the duct rail 35. More specifically, the two mounting grooves 38 are formed across both ends of the longitudinal direction of the duct rail 35.

The two mounting grooves 38 correspond one-to-one with the two second rails 352. A corresponding second rail 352 is fitted into each mounting groove 38. In this way, the two second rails 352 are attached to the first rail 351.

Each of the two second rails 352 extends in the longitudinal direction (left-right direction). The two second rails 352 face each other in the up-down direction. The shape of the second rail 352 in a cross section perpendicular to the left-right direction is U-shaped. The second rail 352 is electrically insulating. The second rail 352 is formed of a synthetic resin material such as PVC (polyvinyl chloride). The second rail 352 holds the electrode 34 on its inner side.

The pair of electrodes 34 are provided at both ends of the wiring duct 31 in the width direction (vertical direction in this embodiment). Thus, the pair of electrodes 34 face each other in the vertical direction. Each of the pair of electrodes 34 extends in the longitudinal direction (horizontal direction). Each of the pair of electrodes 34 is provided from the right end to the left end of the duct rail 35. The pair of electrodes 34 are electrically connected to the corresponding wiring W1 (see FIG. 14) via the feed-in 91. One of the pair of electrodes 34 of the wiring duct 31 is electrically connected to the positive side wiring W1, and the other is electrically connected to the negative side wiring W1. As a result, DC power is supplied to the pair of electrodes 34. The two power receiving terminals 22 of the adapter 2 are supplied with power by being connected to the pair of electrodes 34.

The end cap 5 is attached to one end (the right end in this embodiment) of the wiring duct 31. As a result, the end cap 5 closes the end face opening 36 at one end of the wiring duct 31. The end cap 5 includes a closing portion 51, two guide portions 52, an insertion portion 54, and two insertion pieces 55. A feed-in 91 is attached to the other end of the wiring duct 31 (see FIG. 14).

The outer peripheral shape of the blocking portion 51 is approximately the same as the outer peripheral shape of the wiring duct 31 when viewed in the left-right direction. In this embodiment, the blocking portion 51 is a rectangular plate. The width of the blocking portion 51 is equal to the width W5 of the end cap 5. The end cap 5 has the same width as the width W31 of the wiring duct 31.

An inclined surface 57 is formed in front of the blocking portion 51. The inclined surface 57 is inclined so that it extends rearward as it moves to the right.

The two guide portions 52 are formed on one surface of the blocking portion 51 (the surface facing the right in this embodiment). Each of the two guide portions 52 is L-shaped when viewed along the front-rear direction. Each of the two guide portions 52 extends in the front-rear direction. A guide groove 53 is formed between the tip of each of the two guide portions 52 and one surface of the blocking portion 51. The guide groove 53 extends in the front-rear direction. The two guide grooves 53 open on opposite sides to each other. That is, the upper guide groove 53 opens upward, and the lower guide groove 53 opens downward.

The insertion portion 54 is a portion that is inserted into the inside of the wiring duct 31 from the end surface opening 36 of the wiring duct 31. The insertion portion 54 is formed on the other surface of the blocking portion 51 (the surface facing the left in this embodiment).

A fixing hole 56 is formed in the insertion portion 54. The fixing hole 56 is a hole used to fix the end cap 5 to the wiring duct 31. The fixing hole 56 is opened in the front-rear direction. A special screw is screwed into the fixing hole 56 using a special tool. A special screw means a screw of a shape that cannot be turned with a general-purpose tool such as a normal screwdriver (e.g., a Phillips screwdriver, a flathead screwdriver, etc.). An example of a special screw is a hexalobular socket screw. A special tool is a tool that can turn a special screw. In this way, the end cap 5 is attached to the wiring duct 31 using the special tool.

The two insertion pieces 55 are formed on the upper and lower sides of the insertion portion 54, respectively. The two insertion pieces 55 extend in the left-right direction. The two insertion pieces 55 correspond one-to-one with the two mating portions 37 of the first rail 351. The upper insertion piece 55 fits into the upper mating portion 37, and the lower insertion piece 55 fits into the lower mating portion 37.

The removable cover 6 is a cover that can be detached from the end cap 5. The removable cover 6 is attached to the end cap 5 in one direction (left-right direction). In this embodiment, the removable cover 6 is attached adjacent to the right side of the end cap 5. The removable cover 6 has a rectangular box shape. The removable cover 6 includes a main body 60 and two guide pieces 61 (see Figure 19).

The main body 60 is a rectangular box-like shape, with openings at the rear and the side facing left. The width of the main body 60 is equal to the width W6 of the detachable cover 6. The detachable cover 6 has the same width W31 as the width W31 of the wiring duct 31. In other words, the width W31 of the wiring duct 31, the width W5 of the end cap 5, and the width W6 of the detachable cover 6 are equal.

An inclined surface 62 is formed on the front left side of the main body 60. The inclined surface 62 is inclined so as to extend rearward as it approaches the right side. The inclined surface 62 faces the inclined surface 57 of the end cap 5. In this manner, the inclined surface 62 of the removable cover 6 faces the inclined surface 57 of the end cap 5, and a removal hole 63 is formed between them. A general-purpose tool such as a flathead screwdriver is inserted into the removal hole 63, and the removable cover 6 is pulled forward by the principle of leverage. In this manner, the removable cover 6 is slidable in one direction and in a direction perpendicular to the width direction of the wiring duct 31 (in the front-to-rear direction in this embodiment).

The two guide pieces 61 correspond one-to-one to the two guide grooves 53 of the end cap 5. Each guide piece 61 extends in the front-to-rear direction. The two guide pieces 61 face each other in the up-down direction. That is, the upper guide piece 61 protrudes downward, and the lower guide piece 61 protrudes upward. The thickness of the guide pieces 61 is approximately equal to the thickness of the guide groove 53. Each guide piece 61 is inserted into the corresponding guide groove 53. This allows the removable cover 6 to slide in the front-to-rear direction relative to the end cap 5 while being coupled to the end cap 5.

In one direction (left-right direction), the length L6 of the removable cover 6 is longer than the length L5 of the end cap 5. In one direction (left-right direction), the length L6 of the removable cover 6 is longer than the length of a portion of the adapter 2 inserted into the wiring duct 31. Here, the portion of the adapter 2 is a portion that exists behind the rear surface of the cover portion 27. Specifically, it is the mounting protrusion 26. Preferably, when viewed along the front-rear direction, the length L6 of the removable cover 6 is longer than the distance between two intersections between any straight line intersecting the rotation axis B1 and the outer periphery of the fixed rib 23.

(3) Fixture Next, the fixture 1 according to this embodiment will be described with reference to FIG. 13 and FIG. 14.

The fixture 1 includes an adapter 2 and a wiring duct system 3. Note that FIG. 13 illustrates the fixture 1 with the adapter 2 removed from the wiring duct system 3.

Here, fixtures 1 is a general term for furniture, fixtures, and other equipment used in residential or non-residential buildings. Examples of fixtures 1 are desks, tables, workbenches, and the like used as platforms for placing items. Other examples of fixtures 1 are shelves, boxes, dressers, beds, whiteboards, screens, partitions, benches, and the like.

In the following, we will explain the case where the fixture 1 is a desk 10, but it is not intended to limit the fixture 1 to a desk 10.

The fixture 1 further includes a desk 10, a duct fixture 11, and a partition 12.

The desk 10 has a top plate 13 that is rectangular in plan view, two legs 14, and two support bases 15. One of the two legs 14 protrudes downward from near the right end of the top plate 13, and the other protrudes downward from near the left end of the top plate 13. The two support bases 15 correspond one-to-one to the two legs 14. Each support base 15 is connected to the lower end of the corresponding leg 14 and supports the leg 14.

The duct fixing device 11 is a member for fixing the wiring duct system 3 to the desk 10. The duct fixing device 11 has a first fixing part 111 and a second fixing part 112.

The first fixing part 111 is a member for holding the wiring duct system 3. The first fixing part 111 extends in the left-right direction and is positioned so as to separate the front and rear of the desk 10.

The second fixing part 112 is a member for fixing the first fixing part 111 to the desk 10. The second fixing part 112 is connected to both the left and right ends of the first fixing part 111. The second fixing part 112 includes a clamping mechanism, and is fixed to the desk 10 by clamping the desk 10 in the vertical direction with this clamping mechanism.

The partition 12 has a rectangular plate shape and is held by the duct fixing device 11. The partition 12 separates the front and rear of the desk 10. In this embodiment, the partition 12 is translucent. The material of the partition 12 is, for example, acrylic resin.

Next, an example of a power supply system for fixture 1 will be described with reference to FIG. 14. The power supply system is a system that supplies power to electrical equipment 9 using an adapter 2 and a wiring duct system 3.

The type of electrical equipment 9 is not particularly limited. Examples of electrical equipment 9 include computer terminals (personal computers, smartphones, tablet terminals, etc.), computer terminal accessories (monitors, speakers, microphones, etc.), lighting equipment (desk lamps, etc.), network cameras, sensors (temperature sensors, humidity sensors, illuminance sensors, etc.), game consoles, and air conditioning equipment (desk fans, etc.).

As shown in FIG. 14, a switching hub 93 and a splitter 94 are provided in the facility where the electrical device 9 is used. The switching hub 93 is electrically connected to a power source 92. The power source 92 supplies AC power to the switching hub 93. The power source 92 is, for example, a commercial power source or a distributed power source.

The switching hub 93 is a PoE switching hub that supports PoE (Power over Ethernet). The switching hub 93 is electrically connected to the splitter 94 via a LAN (Local Area Network) cable. The switching hub 93 can also be electrically connected to devices that support PoE. Examples of devices that support PoE include computer terminals, network cameras, IP (Internet Protocol) telephones, and wireless access points. The switching hub 93 can transmit and receive PoE signals that include data and power (DC power) between devices that are electrically connected to the switching hub 93.

The splitter 94 is a PoE splitter that supports PoE. The splitter 94 separates the PoE signal received from the switching hub 93 into data and power (DC power). The splitter 94 supplies the power separated from the PoE signal to a device that does not support PoE. As an example, the splitter 94 supplies the power separated from the PoE signal to one or more electrical devices 9 that do not support PoE via the wiring duct system 3.

The splitter 94 transmits a data signal containing data separated from the PoE signal to a device that does not support PoE.

The DC power output terminal of the splitter 94 is electrically connected to the first end of each of the two wirings W1. The two wirings W1 are positive and negative wirings. The two wirings W1 correspond one-to-one with the two electrodes 34 of the wiring duct 31. The second end of each of the two wirings W1 is electrically connected to the corresponding electrode 34 via the feed-in 91. The adapter 2 can be connected to the wiring duct 31, and an electrical device 9 can be electrically connected to each electrode 34 via the adapter 2.

As a result, the electrical device 9 can receive power supplied from the wiring W1 via the electrode 34 and the adapter 2. The user can use the electrical device 9 on or around the desk 10 (see FIG. 13).

(4) Attaching and Removing the Adapter to the Wiring Duct Next, the attachment and removal of the adapter 2 to the wiring duct 31 will be described with reference to Figures 15 to 20. The base 4 shown in Figures 15 to 20 corresponds to the first fixing portion 111 of the fixture 1 shown in Figure 13. For convenience of explanation, the base 4 is illustrated as a rectangular parallelepiped, but is not limited to this shape.

A storage groove 41 and a working space 42 are formed on the surface of the base 4 (the front surface in this embodiment). The storage groove 41 and the working space 42 are recessed toward the rear.

The storage groove 41 is a groove in which the wiring duct 31 is stored. The wiring duct 31 stored in the storage groove 41 is exposed from the base 4. Specifically, the front surface of the wiring duct 31 (the surface on which the opening 32 is formed) is exposed from the base 4. The end cap 5 (front portion) attached to the wiring duct 31 is also exposed from the base 4.

The storage groove 41 extends in the left-right direction. The width of the storage groove 41 is approximately equal to the width W31 of the wiring duct 31. The depth of the storage groove 41 is approximately equal to the length of the wiring duct 31 in the front-to-rear direction. In this way, the wiring duct 31 does not protrude from the base 4 except for the restricting protrusion 39. The wiring duct 31 is fixed to the storage groove 41 by screws or the like. The end cap 5 attached to the wiring duct 31 also does not protrude from the base 4.

The working space 42 is a space used when attaching or detaching the adapter 2 (see Figures 16 and 17). Before and after the attachment or detachment of the adapter 2, the working space 42 is closed by the removable cover 6. In this way, the removable cover 6 is exposed from the base 4. Specifically, the front surface of the removable cover 6 is exposed from the base 4.

The working space 42 is formed continuously with one end of the storage groove 41 (the right end in this embodiment). The width of the working space 42 is approximately equal to the width of the storage groove 41. The depth of the working space 42 is approximately equal to the depth of the storage groove 41. The length L42 of the working space 42 is approximately equal to the length L6 of the detachable cover 6 and is longer than the length L5 of the end cap 5 (see FIG. 19). The depth of the working space 42 is approximately equal to the height (distance in the front-to-rear direction) of the detachable cover 6 (see FIG. 20). Therefore, the surface (front) of the base 4 and the surface (front) of the detachable cover 6 are approximately flush with each other. In this way, the detachable cover 6 does not protrude from the base 4.

The procedure for attaching the adapter 2 to the wiring duct 31 is described below.

As shown in FIG. 15, when the installation work of the adapter 2 begins, the wiring duct 31, the end cap 5, and the removable cover 6 are embedded in the base 4.

First, insert a general-purpose tool such as a flathead screwdriver into the removal hole 63 and pull the removable cover 6 forward using the principle of leverage (see Figure 16). This will reveal the work space 42.

Next, slide the end cap 5 to the right until it reaches the working space 42. Then, pull the end cap 5 forward from the working space 42 (see FIG. 17). Because the length L42 of the working space 42 is longer than the length L5 of the end cap 5 (see FIG. 19), the end cap 5 can be easily pulled out from the working space 42.

Next, a part of the adapter 2 is inserted from one end of the wiring duct 31 (the end opening 36 facing the working space 42). As described above, the part of the adapter 2 is the part (the mounting protrusion 26) that exists behind the rear surface of the cover 27. Here, the fitting portion 37 of the wiring duct 31 opens at the end opening 36. Therefore, the fixing rib 23 of the adapter 2 can be inserted and fitted into the fitting portion 37 of the wiring duct 31 along the left-right direction. Then, the adapter 2 is moved left-right to a predetermined position of the wiring duct 31 (a position desired by the user). At this time, in order to avoid wear of the two power receiving terminals 22, it is preferable to move the adapter 2 with the two power receiving terminals 22 positioned along the longitudinal direction (left-right direction). That is, since this state is a non-power supply state (see FIG. 4), the two power receiving terminals 22 are not in contact with the electrodes 34 and do not receive power supply.

When a portion of the adapter 2 is inserted through the end opening 36 of the wiring duct 31, the thick portion 234 of the fixing rib 23 is inserted into the wide portion 371 of the fitting portion 37, and the thin portion 235 of the fixing rib 23 is inserted into the narrow portion 372 of the fitting portion 37 (see FIG. 4). If the orientation of the adapter 2 is incorrect, the thick portion 234 of the fixing rib 23 will interfere with the narrow portion 372 of the fitting portion 37, and the adapter 2 cannot be inserted through the end opening 36 of the wiring duct 31.

For the same purpose as above, when inserting a part of the adapter 2 from the end surface opening 36 of the wiring duct 31, the restricting protrusion 39 of the wiring duct 31 is inserted into the restricting recess 28 (see FIG. 4). If the orientation of the adapter 2 is incorrect, the restricting protrusion 39 will interfere with an area on the rear surface of the adapter 2 that protrudes one step further than the restricting recess 28, and the adapter 2 cannot be inserted from the end surface opening 36 of the wiring duct 31. In other words, the restricting recess 28 and the restricting protrusion 39 restrict the orientation of the adapter 2.

Next, as shown in FIG. 2 (base 4 is not shown), the adapter 2 is moved to a predetermined position in the wiring duct 31, and then rotated 90 degrees around the rotation axis B1 (see FIG. 1). This transitions from the power-off state shown in FIG. 4 to the power-supply state shown in FIG. 3. That is, the two power-receiving terminals 22 come into contact with the electrodes 34 and receive a supply of power. Furthermore, as shown in FIGS. 1 and 3, the claws 250 of the operating unit 25 are inserted into the opening 32 of the wiring duct 31, thereby restricting the rotation of the adapter 2 (housing 24).

Next, the end cap 5 is moved in the direction opposite to the arrow in FIG. 17. That is, after the end cap 5 is placed in the working space 42, the insertion piece 55 of the end cap 5 is inserted into the fitting portion 37 of the wiring duct 31 and then slid to the left. This causes the end cap 5 to close the end face opening 36 of the wiring duct 31.

Next, the removable cover 6 is moved in the direction opposite to the arrow in FIG. 16. That is, the guide piece 61 of the removable cover 6 is inserted into the guide groove 53 of the end cap 5, and the removable cover 6 is then slid backward into the working space 42. This allows the working space 42 to be closed off with the removable cover 6 (see FIG. 15).

By following the above steps, the adapter 2 can be attached to the wiring duct 31. Note that the adapter 2 can be removed from the wiring duct 31 by following the above steps in reverse.

3. Modifications (1) Modifications of the Adapter Modifications of the adapter 2 will be described with reference to Figures 7 to 10. In this modification, components similar to those in the above embodiment are denoted by the same reference numerals as in the above embodiment, and detailed description thereof may be omitted.

The adapter 2 according to the modified example differs from the adapter 2 according to the above embodiment in the shape of the fixed rib 23. Specifically, the fixed rib 23 of the adapter 2 according to the modified example forms a circle centered on the rotation axis B1 when viewed along the front-to-rear direction. The outer periphery of the thick-walled portion 234 and the outer periphery of the thin-walled portion 235 are concentric circles. An outer peripheral edge portion 236 that forms a ring shape exists between the outer periphery of the thick-walled portion 234 and the outer periphery of the thin-walled portion 235.

(2) Reference Example of Adapter A reference example of the adapter 2 will be described with reference to Fig. 11 and Fig. 12. In this reference example, components similar to those in the above embodiment are denoted by the same reference numerals as in the above embodiment, and detailed description thereof may be omitted.

The adapter 2 according to the reference example differs from the adapter 2 according to the above embodiment in the shape of the fixed rib 23. Specifically, the length L23 between both ends of the fixed rib 23 in the direction in which the two power receiving terminals 22 protrude (the vertical direction in FIG. 11) is longer than the width W32 of the opening 32. However, the length L23 between both ends of the fixed rib 23 in the direction perpendicular to the direction in which the two power receiving terminals 22 protrude (the vertical direction in FIG. 12) is less than the width W32 of the opening 32.

(3) Others In the present embodiment, the wiring duct system 3 has been described as a DC duct system that supplies DC (direct current) power. However, the wiring duct system 3 may be an AC duct system that supplies AC (alternating current) power.

In this embodiment, a case has been described in which a switching hub 93 and a splitter 94 are provided in the facility where the electrical device 9 is used (see FIG. 14), but this is not limited to the case. For example, an AC adapter may be provided instead of the switching hub 93 and the splitter 94. The AC adapter converts AC power supplied from the power source 92 into DC power. For example, the AC adapter may be configured to convert 100V AC power into 24V DC power.

In this embodiment, the end cap 5 and the removable cover 6 are attached to the right end of the wiring duct 31, but they may also be attached to the left end of the wiring duct 31.

4. Advantages Advantages of the adapter 2, the wiring duct system 3, and the fixture 1 according to this embodiment will be described below.

The adapter 2 according to this embodiment is less likely to be removed from the wiring duct 31 than the adapter 2 according to the reference example.

In the adapter 2 according to the reference example, particularly in the non-powered state, the length L23 between both ends of the fixing rib 23 is shorter than the width W32 of the opening 32 of the wiring duct 31 (see FIG. 12). Therefore, in the adapter 2 according to the reference example, if the adapter 2 is rotated around the rotation axis B1 to change from a powered state to a non-powered state, essentially anyone can take the adapter 2 out of the wiring duct 31.

In contrast, in the adapter 2 according to this embodiment, the length L23 between both ends of the fixing rib 23 is longer than the width W32 of the opening 32 of the wiring duct 31, particularly in the power-off state (see FIG. 6). Therefore, even if you try to pull the adapter 2 forward in the power-off state, the fixing rib 23 interferes with the edge of the opening 32, making it difficult to pull the adapter 2 out of the wiring duct 31. This makes it possible to prevent the adapter 2 from being taken out of the wiring duct 31. However, in the power-off state, it is only difficult for the adapter 2 to move in the front-rear direction, but it can move in the left-right direction. In other words, the adapter 2 according to this embodiment can be freely moved along the longitudinal direction (left-right direction) of the wiring duct 31 without being separated from the wiring duct 31.

In the adapter 2 according to this embodiment, even in the power supply state, the length L23 between both ends of the fixing rib 23 is longer than the width W32 of the opening 32 of the wiring duct 31 (see FIG. 5). Therefore, even in the power supply state, it is possible to prevent the adapter 2 from being removed from the front of the wiring duct 31 (the surface where the opening 32 is formed). This also applies to the adapter 2 according to the modified example.

Furthermore, in the adapter 2 according to this embodiment, the length L23 between both ends of the fixed rib 23 in any radial direction centered on the shaft portion 21 (particularly the rotation axis B1) is longer than the width W32 of the opening 32. Therefore, even if the adapter 2 is rotated at any angle around the rotation axis B1, it is difficult to pull the adapter 2 out of the wiring duct 31. Therefore, it is possible to further suppress removal of the adapter 2 from the front of the wiring duct 31. The same applies to the adapter 2 according to the modified example.

The wiring duct system 3 according to this embodiment also includes a wiring duct 31, an end cap 5, and a removable cover 6. In particular, the wiring duct system 3 includes the removable cover 6, which makes it easier to ensure the work space 42 required for attaching and detaching the adapter 2. Therefore, even if the wiring duct 31 is embedded in the base 4, the adapter 2 can be easily attached and detached from the wiring duct 31. Furthermore, the work space 42 is closed by the removable cover 6 before and after attaching and detaching the adapter 2, so the aesthetic appearance is not impaired.

The length L6 of the detachable cover 6 is longer than the length L5 of the end cap 5 and the length of a portion of the adapter 2 (the mounting protrusion 26 in this embodiment). Therefore, the space required for attaching and detaching the adapter 2 can be secured as the working space 42.

The removable cover 6 can slide forward and backward even though its movement in the up-down and left-right directions is restricted. Therefore, even if the removable cover 6 is embedded in the base 4, the removable cover 6 can be easily attached and detached.

The end cap 5 is attached to the wiring duct 31 using a special tool. Therefore, even if the removable cover 6 is removed, the adapter 2 is prevented from being removed from the wiring duct 31.

The fixture 1 according to this embodiment is equipped with the adapter 2 according to this embodiment and the wiring duct system 3 according to this embodiment, and therefore is able to prevent the adapter 2 from being taken out of the wiring duct 31. Moreover, even if the wiring duct 31 is embedded in the base 4, the adapter 2 can be easily attached and detached from the wiring duct 31. Although the adapter 2 according to the reference example is more likely to be taken out than the adapter 2 according to this embodiment and the modified example, the fixture 1 may be equipped with the adapter 2 according to the reference example.

In addition, in the fixture 1 according to this embodiment, the wiring duct 31, end cap 5, and removable cover 6 are embedded in the base 4. By removing the removable cover 6, the work space 42 appears. The end cap 5 can also be removed using the work space 42. Therefore, the adapter 2 can be easily attached and detached to the wiring duct 31 without removing the wiring duct 31 from the base 4.

5. Aspects As is apparent from the above-described embodiment and modified examples, 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 first aspect is an adapter (2) that is attached to a wiring duct (31) of a wiring duct system (3) that supplies electric power, and a connector (8) is connected to send the electric power from the wiring duct (31) to the connector (8). The adapter (2) includes an axis portion (21) that is inserted into an opening (32) formed in the wiring duct (31) and extending in the longitudinal direction of the wiring duct (31), two power receiving terminals (22) that protrude in opposite directions from the axis portion (21) and are connected to a pair of electrodes (34) provided at both ends in the width direction of the wiring duct (31) to receive the supply of electric power, and a fixed rib (23) that protrudes from the axis portion (21) with the axis portion (21) as the center. When the power supply is not received, the two power receiving terminals (22) are located along the longitudinal direction. When the power supply is not received, the length (L23) between both ends of the fixed rib (23) in the width direction is longer than the width (W32) of the opening (32) when viewed from the depth direction perpendicular to both the longitudinal direction and the width direction.

This embodiment makes it possible to prevent the adapter (2) from being removed from the wiring duct (31).

The second aspect is an adapter (2) based on the first aspect. In the second aspect, the fixing rib (23) protrudes from the entire circumference of the shaft portion (21). The length (L23) between both ends of the fixing rib (23) in the direction in which the two power receiving terminals (22) protrude is longer than the width (W32) of the opening (32).

This embodiment makes it possible to prevent the adapter (2) from being removed from the front of the wiring duct (31) (the surface on which the opening (32) is formed).

The third aspect is an adapter (2) based on the second aspect. In the third aspect, the length (L23) between both ends of the fixing rib (23) in any radial direction centered on the shaft portion (21) is longer than the width (W32) of the opening (32).

This aspect further prevents the adapter (2) from being removed from the front of the wiring duct (31).

The fourth aspect is a fixture (1) that includes an adapter (2) based on any one of the first to third aspects and the wiring duct system (3).

This embodiment makes it possible to prevent the adapter (2) from being removed from the wiring duct (31).

REFERENCE SIGNS LIST 1 fixture 2 adapter 21 shaft portion 22 power receiving terminal 23 fixing rib 3 wiring duct system 31 wiring duct 32 opening 34 electrode 8 connector

Claims (4)

An adapter that is attached to a wiring duct of a wiring duct system that supplies electric power, has a connector connected thereto, and transmits the electric power from the wiring duct to the connector,
a shaft portion that is inserted into an opening formed in the wiring duct and extending in a longitudinal direction of the wiring duct;
two power receiving terminals that project in opposite directions from the shaft portion and are connected to a pair of electrodes provided at both ends of the wiring duct in a width direction to receive the power;
A fixing rib protruding from the shaft portion around the shaft portion,
the two power receiving terminals are located along the longitudinal direction when the power receiving terminal is not supplied with the power,
When the power is not supplied, the length between both ends of the fixing rib in the width direction is longer than the width of the opening when viewed from a depth direction perpendicular to both the longitudinal direction and the width direction.
adapter. The fixing rib protrudes from the entire circumference of the shaft portion,
The length between both ends of the fixing rib in the direction in which the two power receiving terminals protrude is longer than the width of the opening.
2. The adapter of claim 1. The length between both ends of the fixing rib in any radial direction around the shaft portion is longer than the width of the opening.
3. The adapter of claim 2. A fixture comprising the adapter according to any one of claims 1 to 3 and the wiring duct system.

Images