TW201716264A - Power collecting device and electric power transmission system which are less likely to cause positional deviation of the power collecting device to the power supply path and less likely to result in poor contact of the power collecting device with the power supply path - Google Patents

Abstract

The subject of the present invention is to provide a power collecting device and an electric power transmission system, which are less likely to cause positional deviation of the power collecting device to the power supply path, and less likely to result in poor contact of the power collecting device with the power supply path. The power collecting device (1) of the present invention comprises power collecting arms (61, 62), a movable member (5), and a displacement mechanism (9). One end of the arm portion (65) of the power collecting arms (61, 62) is fixed to the power collector (63), and the end at the opposite side of the power collector (63) is fixed to the movable member (5). The movable member (5) can be connected to a connecting member provided on a movement equipment (30) via the displacement mechanism (9). The displacement mechanism (9) can make the movable member (5) displace relative to the connecting member. The displacement mechanism (9) restricts the direction of displacement of the movable member (5) relative to the connecting member to a direction different from the longitudinal direction of the power supply path (45).

Description

Collector and power transmission system

The present invention relates to a current collecting device and a power transmission system.

Japanese Patent Laid-Open Publication No. 2008-301577 (hereinafter referred to as "Document 1") discloses a power collecting device that transmits electric power from a power supply path to a mobile device such as a crane. This current collecting device includes a current collecting arm and a fixing member. The collector arm has a current collector and an arm. One end of the arm holds the current collector, and the end opposite to the current collector is held by the fixing member. The current collecting device is mounted to the mobile device by fixing the fixing member to the mobile device.

When the current collecting device moves together with the mobile device, the current collector moves in a state of being in contact with the power supply path. Thereby, the power of the power supply path is collected from the power supply path to the current collector, and is supplied to the mobile device via the current collector.

However, due to a construction error or the like, a part of the longitudinal direction of the power supply path may be locally displaced to a direction intersecting the longitudinal direction of the power supply path. In this case, there is a concern that the current collector deviates from the position of the power supply path to cause a poor contact of the current collector to the power supply path (poor contact between the power supply path and the current collector).

Here, in the current collecting device disclosed in Document 1, the arm portion is coupled to be rotatable relative to the fixing member. Therefore, the current collector is moved relative to the fixed member by the rotation of the arm relative to the fixed member.

However, if the arm portion is largely rotated with respect to the fixing member, the direction of the current collector is difficult to stabilize. Therefore, the fixing member of the current collecting device disclosed in Patent Document 1 is provided with a rotation suppressing member for suppressing the rotation of the arm portion. However, if such a rotation suppressing member is provided, the movable range of the current collector is narrowed. Therefore, when a part of the longitudinal direction of the power supply path is largely displaced to a direction intersecting the longitudinal direction of the power supply path, the position of the current collector on the power supply path may be deviated.

The present invention has been made in view of the above circumstances, and an object thereof is to provide a current collecting device and a power transmission system which are less likely to cause a positional deviation of a current collector from a power supply path, and which is less likely to cause a contact failure of a current collector to a power supply path. [Method of solving the problem]

A current collecting device according to an aspect of the present invention includes a current collecting arm, a movable member, and a displacement mechanism. The collector arm has a collector and an arm. The current collector is in contact with the power supply path. The current collector is held at one end of the arm, and the end opposite to the current collector is held by the movable member. The movable member can be coupled to a connecting member provided to the mobile device via the displacement mechanism. The displacement mechanism displaces the movable member relative to the coupling member. The displacement mechanism restricts a displacement direction of the movable member with respect to the coupling member to a direction different from a longitudinal direction of the power supply path.

Moreover, a power transmission system according to an aspect of the present invention includes a power supply path and a power collecting device. The current collecting device includes a current collecting arm, a movable member, and a displacement mechanism. The collector arm has a current collector that is in contact with the power supply path, and an arm portion that holds the current collector at one end, and the end portion opposite to the current collector is held by the movable member. The movable member can be coupled to a connecting member provided to the mobile device via the displacement mechanism. The displacement mechanism displaces the movable member with respect to the coupling member in a direction different from the longitudinal direction of the power supply path, and restricts a displacement direction of the movable member.

In the current collecting device and the power transmission system of the present invention, it is difficult to generate a positional deviation of the current collector from the power supply path, and it is difficult to cause a contact failure of the current collector to the power supply path.

Hereinafter, embodiments will be described based on additional drawings. (First embodiment)

1 and 2 are perspective views of the current collecting device 1 of the embodiment. FIG. 3 is a plan view showing a power transmission system (sliding box type rail system) 2 including the current collecting device 1.

The power transmission system 2 of the present embodiment includes a power collecting device 1, a mobile device 30, and a plurality of power supply paths 45 shown in FIG.

A plurality of power supply paths 45 are used as power sources for the mobile device 30. A plurality of power supply paths 45 are disposed along the moving path of the mobile device 30.

The plurality of power supply paths 45 of the present embodiment extend in the horizontal direction and are arranged in the vertical direction. That is, the direction D1 in which the plurality of power supply paths 45 of the present embodiment are arranged is the vertical direction. The plurality of power supply paths 45 may also be arranged in a horizontal direction. Further, the power transmission system 2 may have only one power supply path 45.

The current collecting device 1 is provided with a plurality of current collectors 63. A plurality of current collectors 63 are arranged in parallel with the plurality of power supply paths 45 and are opposed to the plurality of power supply paths 45. In the following description, the relative direction D2 of the power supply path 45 and the current collector 63 (the direction parallel to the direction in which the current collector 63 faces the power supply path 45) is set to the front-rear direction, and the long-side direction of the power supply path 45 is set to Left and right direction. In the following, the direction from the position where the power feeding path 45 is seen from the current collector 63 is set to the front, and the left side when the power collecting device 1 is viewed from the front is left, and the current collecting device 1 will be described. Moreover, the direction in which the current collecting device 1 is used is not limited.

The mobile device 30 of the present embodiment is installed in an electric trolley of an automatic warehouse. Mobile device 30 is used to carry items in an automated warehouse.

The mobile device 30 is walkable by supplying electric power from the plurality of power supply paths 45 via the power collecting device 1. The mobile device 30 walks along, for example, a track provided on the building floor. In this case, the direction of movement of the mobile device 30 is defined by the track.

The mobile device 30 of the present embodiment is an electric vehicle, but the mobile device 30 may be a transport machine other than an electric car such as a crane or a passenger vehicle. Moreover, the mobile device 30 can also be disposed along structural materials such as walls, ceilings, beams, and the like of the building. Further, the mobile device 30 may be installed in a factory, a ride, or the like.

As shown in FIG. 3, the power transmission system 2 of the present embodiment includes a plurality of power supply rails 41, 42 arranged in the moving direction of the mobile device 30 (direction indicated by D3 in FIG. 3), and the plurality of power supply rails 41. 42 has a plurality of power supply paths 45 (refer to FIG. 4).

The power transmission system 2 of the present embodiment includes two power supply rails 41 and 42, but the power transmission system 2 may have three or more power supply rails. Further, the power transmission system 2 may have only one power supply track.

Each of the power supply rails 41 and 42 of the present embodiment is installed in a beam and column as a structural material of the automatic warehouse. Each of the power supply rails 41, 42 may also be disposed of a structural material other than the beam and column of the structure. This structural material is exemplified by walls, ceilings, floors, and the like.

As shown in FIG. 4, each of the power supply rails 41, 42 is provided with a sheath 44 having electrical insulation, and a plurality of electric wires 451 (refer to FIG. 3) and 452 covered by a sheath 44.

The sheath 44 of each of the power supply rails 41 and 42 is formed in a plate shape in which the thickness direction is parallel to the front-rear direction and extends in the moving direction of the mobile device 30. Each of the sheaths 44 is formed with a plurality of storage grooves 46 arranged in the width direction (up and down direction) of the plate-shaped sheath 44.

Each of the accommodation grooves 46 is formed over the entire length of the sheath 44 in the longitudinal direction. Each of the accommodation grooves 46 is opened on one side (rearward) in the thickness direction (front-rear direction) of the plate-shaped sheath 44.

In the plurality of storage grooves 46 of the sheath 44 of the power supply rail 41, a plurality of electric wires 451 (see FIG. 3) are accommodated in correspondence with each other in a one-to-one correspondence. The plurality of storage grooves 46 of the sheath 44 of the power supply rail 42 accommodate a plurality of electric wires 452 in a one-to-one correspondence. That is, a plurality of electric wires 451 and 452 arranged in the width direction of the sheath 44 are provided in the respective sheaths 44.

In each of the sheaths 44 of the present embodiment, four electric wires 451 and 452 are arranged in the vertical direction. Two, three, or five or more wires may be provided for each of the sheaths 44. Further, in each of the sheaths 44, only one electric wire may be provided.

Each of the electric wires 451 and 452 extends over the entire length of the corresponding sheath 44 in the longitudinal direction. The longitudinal direction of the plurality of electric wires 451 and 452 in each of the power supply rails 41 and 42 is parallel. Each of the electric wires 451 and 452 is formed in a plate shape in which the thickness direction is parallel to the thickness direction (front-rear direction) of the sheath 44. The cross-sectional shape perpendicular to the longitudinal direction of each of the electric wires 451 and 452 is a rectangle. One surface (back surface) in the thickness direction of each of the electric wires 451 and 452 is a contact surface 47 that is exposed through the groove opening of the accommodation groove 46. The contact surface 47 is the surface that the current collector 63 contacts.

The cross-sectional shape perpendicular to the longitudinal direction of each of the electric wires 451 and 452 is not limited to a rectangular shape. For example, a groove V-shaped or a U-shaped groove having a cross section may be formed in the contact surface 47 of each of the electric wires 451 and 452.

In each of the power feeding rails 41 and 42 of the present embodiment, the direction in which the plurality of electric wires 451 and 452 are arranged is parallel to the vertical direction, and the contact faces 47 of the electric wires 451 and 452 are disposed to face the current collecting device 1 and the mobile device 30. The direction (rear). The plurality of power supply rails 41, 42 may be arranged to set the direction in which the plurality of electric wires 451, 452 are arranged horizontally.

The plurality of power supply rails 41, 42 of the present embodiment shown in FIG. 3 are provided as a plurality of electric wires 451 of the power supply rail 41 of one of the adjacent power supply rails 41, 42 and a plurality of power supply rails 42 The wires 452 correspond to one to one, respectively.

The plurality of power supply paths 45 are composed of a plurality of electric wires 451, 452 provided on the plurality of power supply rails 41, 42. Each of the power supply paths 45 is composed of a plurality of segmented electric wires 451 and 452.

The power transmission system 2 of the present embodiment includes the first power supply rail 41 and the second power supply rail 42 as a plurality of power supply rails 41 and 42. The first power supply rail 41 and the second power supply rail 42 are adjacent to each other in the moving direction of the mobile device 30.

Each of the power feeding paths 45 of the present embodiment includes an electric wire 451 (hereinafter referred to as a "first electric wire 451") provided in the first electric power feeding rail 41, and a second electric power feeding rail 42 corresponding to the first electric wire 451. The second wire 452 of the position. The first electric wire 451 and the second electric wire 452 are adjacent to each other in the moving direction of the mobile device 30 as viewed from the vertical direction.

The second electric wire 452 is located away from the first electric wire 451 in the moving direction of the mobile device 30 (longitudinal direction of the first electric wire 451). The first power supply rail 41 and the second power supply rail 42 are provided such that the end portion of the second electric wire 452 on the side of the first electric wire 451 is located on an extension line in which the first electric wire 451 is extended toward the second electric wire 452 side. In the first feeding rail 41 and the second feeding rail 42 of the present embodiment, the longitudinal direction of the first electric wire 451 is parallel to the longitudinal direction of the second electric wire 452.

The power collecting device 1 is mounted to the mobile device 30. As shown in FIG. 4, the current collecting device 1 is disposed between the plurality of power supply paths 45 and the mobile device 30 in the front-rear direction indicated by an arrow D2. The power collecting device 1 transmits power obtained from the power supply path 45 to the mobile device 30 by collecting power from the plurality of power supply paths 45. As shown in FIG. 1, the current collecting device 1 includes a movable member 5, a plurality of collecting arms 61 and 62, and a displacement mechanism 9.

The movable member 5 is coupled to a connection member (a fixing member 10 to be described later) provided in the mobile device 30 via the displacement mechanism 9. The movable member 5 of the present embodiment includes a frame 50, casters 58, and a retaining body 56. As shown in FIG. 2 , the frame 50 includes a frame portion 59 and a rectangular frame shape extending in the left-right direction, and the attachment portions 53 and 54 are respectively provided at both end portions of the frame portion 59 in the left-right direction.

Mounting portions 53 and 54 are provided at intermediate portions in the vertical direction of the left and right ends of the frame portion 59, respectively. Each of the mounting portions 53 and 54 is formed integrally with the frame portion 59. The two mounting portions 53, 54 protrude from the frame portion 59 in the left-right direction toward each other. The mounting portion 53 of one of the two mounting portions 53, 54 is located at the left end of the movable member 5; and the other mounting portion 54 is located at the right end of the movable member 5.

Each of the attachment portions 53 and 54 is formed in a tubular shape that is parallel to the left-right direction in the axial direction. The cross-sectional shape of each of the mounting portions 53 and 54 perpendicular to the left-right direction is a rectangular frame shape.

Casters 58 are attached to both sides of the mounting portions 53 and 54 in the vertical direction. In other words, a pair of upper and lower casters 58 are provided at both end portions of the movable member 5 in the left-right direction.

Each of the casters 58 constitutes a guided portion guided by guide members 21 and 22 (see FIGS. 3 and 5) which will be described later. The guided portion is not limited to the caster 58 and may be, for example, a spherical body that is easy to slide with respect to the guiding members 21 and 22, or a member having a triangular cross section. Further, the guided portion may be, for example, a part of the frame.

Each of the casters 58 has a wheel (caster body) 55 rotatable around the front and rear axle directions. Here, "rotating in the direction of the front-rear axis" means that it is rotatable about a rotation axis parallel to the front-rear direction.

The holder 56 is located inside the frame portion 59. The center portion of the holding body 56 and the frame portion 59 in the left-right direction is disposed at the same position in the left-right direction. The holder 56 is fixed to the frame portion 59 by a fixing tool (for example, a screw).

As shown in FIG. 2, the holding body 56 is formed in a U-shaped plate shape which is open to the rear from the left-right direction. The holding body 56 has a holding portion 57 and a pair of upper and lower connected portions 51 and 52. The holding portion 57 is formed in a rectangular plate shape in which the thickness direction is parallel to the front-rear direction. The holding portion 57 is located inside the frame portion 59.

The connected portion 51 of one of the pair of connected portions 51 and 52 protrudes rearward from the upper end portion of the holding portion 57, and the other connected portion 52 projects rearward from the lower end portion of the holding portion 57. The pair of connected portions 51 and 52 face each other in the vertical direction. Each of the connected portions 51 and 52 is formed in a rectangular plate shape in which the thickness direction is parallel to the vertical direction.

In the following, the connected portion 51 provided at the upper end portion of the holding portion 57 is referred to as the "first connected portion 51", and is provided in the pair of connected portions 51 and 52 provided in the holding member 56. The connected portion 52 at the lower end portion of the holding portion 57 is referred to as a "second connected portion 52".

As shown in FIG. 1, the holding portion 57 holds a plurality of collector arms 61, 62. Each of the collector arms 61 and 62 is located in front of the holding portion 57. Each of the collector arms 61 and 62 has a current collector 63 at one end, and an end portion opposite to the current collector 63 is held by the holding portion 57.

The current collecting device 1 of the present embodiment includes a plurality of first collecting arms 61 and a plurality of second collecting arms 62 as a plurality of collecting arms 61 and 62.

A plurality of first collector arms 61 are attached to the left end portion of the holding portion 57. A plurality of first collecting arms 61 are arranged in the vertical direction.

The current collecting device 1 includes a first collecting arm 61 and a same number of second collecting arms 62. A plurality of second collector arms 62 are attached to the right end portion of the holding portion 57. A plurality of second collector arms 62 are arranged in the vertical direction. That is, the current collecting device 1 is provided with a group of collector arms 61 and 62 that are paired in pairs.

The current collecting device 1 of the present embodiment includes four sets of collecting arms 61 and 62 which are paired in pairs. The power collecting device 1 may also include only one set of the right and left pairs of collector arms 61 and 62, or may have only one collector arm.

Each of the collector arms 61 and 62 has a current collector 63 and an arm portion 65. The shape of the arm portion 65 is a shape that extends in one direction. The current collector 63 is held at one end portion of the arm portion 65 in the longitudinal direction. The end portion on the opposite side to the current collector 63 of the arm portion 65 is held by the holding portion 57.

The arm portion 65 of each of the first collector arms 61 protrudes further to the left than the holding portion 57. The arm portion 65 of each of the second collector arms 62 protrudes to the right from the holding portion 57.

The current collectors 63 of the collector arms 61, 62 have electrical conductivity. As shown in FIG. 4, the current collectors 63 of the respective collector arms 61, 62 are moved along the power supply path 45 in a state of being in contact with the corresponding power supply path 45. The current collector 63 is electrically connected to the mobile device 30 via a cable.

As shown in FIG. 1, the arm portion 65 of the present embodiment includes a collector holder 66, a first rotating member 71, a second rotating member 72, an arm portion 67, and a third rotating member 73.

The current collector holder 66 holds the current collector 63 in a state in which the current collector 63 is housed. The current collector 63 has a plate-shaped contact piece portion 68 that protrudes forward from the current collector holder 66. Each of the collector arms 61 and 62 is attached to the holding portion 57 such that the thickness direction of the contact piece portion 68 is substantially parallel to the vertical direction. The front end surface of the contact piece portion 68 is a contacted surface 64 that is in contact with the power supply path 45.

The current collector holder 66 is coupled to be rotatable about the vertical axis with respect to the first rotating member 71. Here, "rotating in the direction of the vertical axis" means that it is rotatable about a rotation axis parallel to the vertical direction.

The first rotating member 71 is coupled to be rotatable about the front-rear axis direction with respect to the second rotating member 72.

The arm main body 67 of the present embodiment is a parallel coupling mechanism, and is configured by a pair of connecting members 74 arranged in a direction perpendicular to the vertical direction. The arm main body 67 may be a parallel connecting mechanism composed of three or more connecting members, or may be constituted by one connecting member.

The second rotating member 72 is connected to the third rotating member 73 via the arm body 67 . The pair of coupling members 74 are coupled to each other so as to be rotatable in the vertical axis direction with respect to the second rotation member 72. The pair of coupling members 74 are coupled to each other so as to be rotatable in the vertical axis direction with respect to the third rotation member 73.

The third rotating member 73 is coupled to be rotatable about the front and rear axis directions with respect to the holding portion 57. In other words, the arm portion 65 is coupled to be rotatable about a rotation axis parallel to the front-rear direction (a direction intersecting the displacement direction described later) with respect to the movable member 5.

The direction of the contacted surface 64 of the current collector 63 is changed by the current collector holder 66 being rotated relative to the first rotating member 71. By the rotation of the first rotating member 71 with respect to the second rotating member 72, the direction of the plate surface of the contact piece portion 68 is changed. When the second rotating member 72 rotates with respect to the arm main body 67, and the arm main body 67 rotates with respect to the third rotating member 73, the second rotating member 72 moves in the front-rear direction, and the current collector 63 moves in the front-rear direction. In other words, the second rotating member 72 is rotated relative to the third rotating member 73 via the arm main body 67, so that the position of the current collector 63 in the front-rear direction is changed. By rotating the third rotating member 73 with respect to the holding portion 57, the position of the current collector 63 in the vertical direction is changed.

When the current collectors 63 are displaced to any position with respect to the holding portion 57, the current collecting arms 61 and 62 are also located between the left pair of casters 58 and the right pair of casters 58 in the left-right direction.

Each of the collector arms 61 and 62 of the present embodiment further has a biasing member 69. The biasing member 69 of this embodiment is a tension spring. The biasing member 69 biases the arm body 67 so that the arm body 67 rotates forward around the third rotating member 73. In other words, the biasing member 69 rotates the arm body 67 forwardly around the third rotating member 73.

As shown in Fig. 1, each of the collector arms 61, 62 of the present embodiment further has a rotation suppressing member 75 for maintaining the current collector 63 horizontal. The rotation suppressing member 75 is fixed to the holding portion 57.

The rotation suppressing member 75 is formed of a material having elasticity such as metal. The rotation suppressing member 75 has a fixing piece portion 80, a first spring piece portion 81, and a second spring piece portion 82.

The fixing piece portion 80 is along the front surface of the holding portion 57. The fixing piece portion 80 is sandwiched by the third rotating member 73 attached to the holding portion 57 and the holding portion 57. Thereby, the rotation suppressing member 75 is fixed to the holding portion 57. The first spring piece portion 81 protrudes forward from the upper end portion of the fixing piece portion 80. The second spring piece portion 82 protrudes forward from the lower end portion of the fixing piece portion 80.

A corresponding arm portion 67 is slidably accommodated in the horizontal direction between the first spring piece portion 81 and the second spring piece portion 82 of each of the rotation suppressing members 75. In each of the rotation suppressing members 75, the first spring piece portion 81 is in contact with the top surface of the corresponding arm portion main body 67, and the second spring piece portion 82 is in contact with the bottom surface of the corresponding arm portion main body 67. Thereby, each arm unit main body 67 suppresses the amount of rotation of the third rotating member 73 by the corresponding rotation suppressing member 75, and limits the amount of displacement of the current collector 63 of each of the current collecting arms 61 and 62 in the vertical direction.

The current collecting device 1 of the present embodiment further includes a fixing member 10 that can be fixed to the mobile device 30 as a connecting member provided in the mobile device 30. The power collecting device 1 may not include the fixing member 10. In this case, the mobile device 30 includes a connection member, and the movable member 5 is coupled to the connection member via the displacement mechanism 9.

As shown in FIG. 2, the fixing member 10 is formed in a U-shaped plate shape which is open to the front from the left-right direction. Further, in Fig. 2, in order to clearly show the displacement mechanism 9, the fixing member 10 is indicated by a two-dot chain line.

The fixing member 10 has a fixing portion 13 and a pair of upper and lower connecting portions 11 and 12. The fixing portion 13 is formed in a rectangular plate shape in which the thickness direction is parallel to the front-rear direction. As shown in FIG. 2, the fixing portion 13 is located behind the holding portion 57.

The pair of coupling portions 11 and 12 of the fixing member 10 are respectively protruded forward from both end portions of the fixing portion 13 in the vertical direction. Each of the connecting portions 11 and 12 is formed in a rectangular plate shape in which the thickness direction is parallel to the vertical direction.

In the pair of connecting portions 11 and 12, the connecting portion 11 provided at the upper end portion of the fixing portion 13 is referred to as a "first connecting portion 11", and the connecting portion 12 provided at the lower end portion of the fixing portion 13 is provided. It is called "the second connection part 12".

The first to-be-connected portion 51 and the second to-be-joined portion 52 of the movable member 5 respectively have projections 510 and 520 that protrude rearward from the frame portion 59. The protruding portion 510 of the first connected portion 51 and the protruding portion 520 of the second connected portion 52 are located between the pair of connecting portions 11 and 12 of the fixing member 10. The protruding portion 510 and the protruding portion 520 are coupled to the pair of connecting portions 11 and 12 of the fixing member 10 via the displacement mechanism 9 .

The displacement mechanism 9 holds the movable member 5 so as to be displaceable relative to the fixed member 10. Moreover, the displacement mechanism 9 restricts the displacement direction of the movable member 5 with respect to the fixed member 10 to the up-down direction. The displacement mechanism 9 only needs to displace the movable member 5 in a direction different from the left-right direction with respect to the fixed member 10, and the displacement direction of the movable member 5 with respect to the fixed member 10 is not limited to the up-and-down direction.

The displacement mechanism 9 has a plurality of bearings 91, 92 and a plurality of shafts 941, 942. A plurality of bearings 91 and 92 are arranged in the left-right direction. Each of the bearings 91 and 92 has a pair of upper and lower bearing bodies 93. Among the pair of bearing bodies 93 of the respective bearings 91, one of the bearing bodies 93 is attached to the protruding portion 510 of the first connected portion 51, and the other bearing body 93 is attached to the protruding portion 520 of the second connected portion 52.

The displacement mechanism 9 of the present embodiment has a first bearing 91 and a second bearing 92 as a plurality of bearings 91 and 92. The displacement mechanism 9 can also have more than three bearings or only one bearing. Further, each of the bearings may have three or more bearing bodies, or may have only one bearing body.

In each of the projections 510 and 520 of the holding body 56, shaft through holes 141 and 142 which are formed in the vertical direction are formed at a position corresponding to the plurality of bearings 91 and 92. Hereinafter, the pair of upper and lower shaft through holes 141 formed in the holding body 56 at the position corresponding to the first bearing 91 are referred to as "first shaft through holes 141". Further, the pair of upper and lower shaft through holes 142 formed in the holding body 56 at the position corresponding to the second bearing 92 are referred to as "second shaft through holes 142".

A plurality of axes 941, 942 are arranged in the left and right direction. The axial direction of each of the shafts 941 and 942 is parallel to the vertical direction.

The displacement mechanism 9 of the present embodiment has a first shaft 941 and a second shaft 942 as a plurality of shafts 941 and 942. The first shaft 941 penetrates the pair of upper and lower bearing bodies 93 of the first bearing 91 and the pair of upper and lower first shaft through holes 141 . The second shaft 942 penetrates the pair of upper and lower bearing bodies 93 of the second bearing 92 and the pair of upper and lower second shaft through holes 142 . Thereby, the plurality of shafts 941 and 942 are supported by a plurality of bearings 91 and 92 so as to be reciprocally movable in the vertical direction.

In the present embodiment, the shafts 941 and 942 are provided in the fixing member 10, and the bearings 91 and 92 are provided in the movable member 5. However, the shafts 941 and 942 may be provided to the movable member 5, and the bearings 91 and 92 may be provided to The fixing member 10. Further, the displacement mechanism 9 may be constituted not by the shafts 941 and 942 and the bearings 91 and 92, but by, for example, a track provided on one of the fixed member 10 and the movable member 5 and disposed along the track. The moving mobile body is composed of.

The current collecting device 1 further includes an elastic member 15. The elastic member 15 has a plurality of elastic bodies 151 and 152 arranged in the left-right direction.

The current collecting device 1 of the present embodiment includes the first elastic body 151 and the second elastic body 152 as a plurality of elastic bodies 151 and 152.

The first elastic body 151 has a pair of upper and lower springs 161. The second elastic body 152 has a pair of upper and lower springs 162. Hereinafter, the pair of springs 161 included in the first elastic body 151 are referred to as "first springs 161", and the pair of springs 162 included in the second elastic body 152 are referred to as "seconds". Spring 162". The elastic bodies 151 and 152 of the present embodiment are composed of a pair of springs 161 and 162. However, they may be composed of three or more springs, or may be constituted by one spring. Further, the elastic member 15 may be composed of a member having elasticity other than a spring such as rubber.

Each of the springs 161, 162 is a coil spring. Among the pair of upper and lower first springs 161, one of the first springs 161 is located between the first connecting portion 11 and the first connected portion 51, and the other one of the springs 161 is located between the second connecting portion 12 and the second connected portion. Between 52. Among the pair of upper and lower second springs 162, one of the second springs 162 is located between the first connecting portion 11 and the first connected portion 51, and the other second spring 162 is located between the second connecting portion 12 and the second connected portion. Between the sections 52.

The first shaft 941 penetrates inside the pair of first springs 161. The second shaft 942 penetrates inside the pair of second springs 162.

Both end portions of the first shaft 941 in the axial direction are fixed to the corresponding connecting portions 11 and 12 of the fixing member 10, respectively. Thereby, the first shaft 941 is spanned between the pair of coupling portions 11 and 12 of the fixing member 10. Both end portions of the first shaft 941 are fixed to the joint portions 11 and 12 by using a fixing tool such as a nut.

Both ends of the second shaft 942 in the axial direction are fixed to the corresponding connecting portions 11 and 12 of the fixing member 10, respectively. Thereby, the second shaft 942 spans between the pair of coupling portions 11 and 12 of the fixing member 10. Both ends of the second shaft 942 are fixed to the connecting portions 11 and 12 by using a fixing tool such as a nut.

The plurality of bearings 91 and 92 slide in the vertical direction with respect to the plurality of shafts 941 and 942, and the holding body 56 is displaced in the vertical direction between the pair of coupling portions 11 and 12 of the fixing member 10. Thereby, the movable member 5 can reciprocate linearly in the up and down direction. Further, by the plurality of shafts 941 and 942 contacting the corresponding bearings 91 and 92, respectively, the displacement of the movable member 5 in the direction other than the vertical direction is restricted.

The pair of connected portions 51 and 52 of the holding body 56 are sandwiched between the pair of first springs 161 via the first bearing 91 . The pair of connected portions 51 and 52 of the holding body 56 are sandwiched between the pair of second springs 162 via the second bearing 92. Thereby, the holding body 56 is held by the fixing member 10 via the elastic member 15 .

When the holder 56 is displaced in the upward direction, the first spring 161 and the second spring 162 located between the first connecting portion 11 and the first connected portion 51 are sandwiched by the first connecting portion 11 and the first connected portion 51. Live and compress. When the holding body 56 is displaced by a predetermined size or more in the downward direction, the first connecting portion 12 and the second connected portion 52 are located between the second connecting portion 12 and the second connected portion 52, and the first spring 161 and the second portion 2 The spring 162 is clamped and compressed. Thereby, the displacement range of the holding body 56 by the displacement mechanism 9 (the displacement range of the movable member 5) can be restricted to a certain range by the pair of coupling portions 11 and 12.

As shown in FIG. 2, in a state where an external force is not applied to the current collecting device 1, the holding body 56 of the present embodiment is located at a central portion in the vertical direction between the pair of connected portions 51 and 52. This position is the center position of the displacement range of the retaining body 56, and this position is hereinafter referred to as "reference position". The reference position does not have to be at the center of the displacement range of the retaining body 56. For example, the reference position may be located at a position offset from the center of the displacement range of the retaining body 56, and the retaining body 56 may be displaced from the position in the upper and lower directions.

When an external force is applied to the movable member 5 and the holding body 56 is displaced upward from the reference position with respect to the fixing member 10, the first spring 161 and the second spring 162 located above the holding body 56 are connected by the first one. The portion 51 and the first connecting portion 11 are compressed in the vertical direction. At this time, the first spring 161 and the second spring 162 located above are biased toward the lower side, that is, the direction in which the retaining body 56 is displaced toward the reference position. Therefore, when the upward external force is released, the retaining body 56 returns to the reference position.

On the other hand, when a downward external force is applied to the movable member 5 and the holding body 56 is displaced downward from the reference position with respect to the fixing member 10, the first spring 161 and the second spring 162 located below the holding body 56 are second. The connected portion 52 and the second connecting portion 12 are compressed in the vertical direction. At this time, the first spring 161 and the second spring 162 give an elastic force to the upper side in which the holding body 56 is displaced toward the reference position. Therefore, when the downward external force is released, the holding body 56 returns to the reference position. Further, when the first spring 161 and the second spring 162 suppress the displacement of the movable member 5, the movable member 5 strongly moves and comes into contact with the fixing member 10. The current collecting device 1 of the present embodiment includes the elastic member 15, but the elastic member 15 may not be provided.

As shown in FIG. 4, the current collecting device 1 is attached to the mobile device 30 by being fixed to the mobile device 30 by the fixing portion 13 of the fixing member 10. The fixing portion 13 is fixed to the mobile device 30 using a fixing tool such as a bolt.

The current collecting device 1 is disposed at a position where the contact surface 64 of each of the current collectors 63 contacts the contact surface 47 of the corresponding power supply path 45. The contacted surface 64 of each current collector 63 is in contact with the contact surface 47 of the corresponding power supply path 45. In this contact state, the opposing direction of each of the current collectors 63 and the corresponding power supply path 45 is the front-rear direction. In other words, the displacement direction of the movable member 5 displaced by the displacement mechanism 9 of the present embodiment is a direction intersecting the longitudinal direction of the power supply path 45 and intersecting the opposing direction of the current collector 63 and the power supply path 45.

In a state where the contact surface 64 of each current collector 63 is in contact with the contact surface 47 of the corresponding power supply path 45, the arm body 67 of each of the collector arms 61, 62 is biased by a biasing member 69 (refer to FIG. 1). The third rotating member 73 is biased in the direction of forward rotation. Therefore, the contacted faces 64 of the respective current collectors 63 are in contact with each other in a state of being pressed against the contact faces 47 of the corresponding power supply paths 45.

The mobile device 30 moves in a state where each of the current collectors 63 contacts the corresponding power supply path 45. At this time, each of the current collectors 63 moves in the longitudinal direction of the power supply path 45 while contacting the corresponding power supply path 45. Thereby, electric power is supplied to the mobile device 30 from the plurality of power supply paths 45 via the plurality of current collectors 63.

As shown in FIG. 3, the power transmission system 2 of the present embodiment further includes a plurality of guide members 21 and 22.

Each of the guiding members 21 and 22 is in contact with the caster 58 of the current collecting device 1 that moves as shown in FIGS. 5A to 5D, and by guiding the caster 58, the movable member 5 is displaced in the up and down direction, and the current collectors 63 are caused to be driven. Contact with the corresponding wire 451 (refer to FIG. 3), 452.

As shown in FIG. 3, the power transmission system 2 of the present embodiment includes a first guiding member 21 and a second guiding member 22 as a plurality of guiding members 21 and 22.

The first guiding member 21 and the second guiding member 22 are arranged in the moving direction of the mobile device 30 between the first feeding rail 41 and the second feeding rail 42. The first guiding member 21 is located between the first feeding rail 41 and the second guiding member 22 . The second guiding member 22 is located between the second feeding rail 42 and the first guiding member 21 .

Each of the guide members 21 and 22 of the present embodiment is provided in a beam and column as a structural material of an automatic warehouse. Each of the guiding members 21, 22 may be provided on a structural material such as a wall or a ceiling of a building.

The first guiding member 21 and the first feeding rail 41 are arranged in parallel with the moving direction (left-right direction) of the mobile device 30, and are connected to the first feeding rail 41. The second guiding member 22 and the second feeding rail 42 are arranged in parallel with the moving direction (left-right direction) of the mobile device 30, and are connected to the second feeding rail 42.

As shown in FIG. 5A, each of the guiding members 21, 22 includes: a pair of upper and lower movable member guides 24, 25; and a collector guide 26.

One of the pair of movable member guiding members 24, 25 is connected to the upper end portion of the current collector guiding member 26; the other movable member guiding member 25 is connected to the current collector guiding member 26. Lower end.

Each of the movable member guides 24, 25 is formed in a plate shape, and protrudes from the current collector guide 26 in the direction (back) in which the current collecting device 1 and the mobile device 30 are located.

Each of the movable member guides 24, 25 has a parallel portion 27 and an inclined portion 28. The parallel portion 27 is formed in a horizontal plate shape. The pair of parallel portions 27 of the respective guiding members 21, 22 are opposed to each other and are parallel to the moving direction of the mobile device 30. The interval between the pair of parallel portions 27 of the respective guide members 21, 22 is fixed in the moving direction of the mobile device 30.

The pair of inclined portions 28 of the first guiding member 21 (refer to FIG. 3 ) are respectively from the end portion of the corresponding parallel portion 27 of the first guiding member 21 opposite to the first feeding rail 41, and 1 The power supply rail 41 is convex on the opposite side. The pair of inclined portions 28 of the second guiding member 22 are respectively from the end portion of the corresponding parallel portion 27 of the second guiding member 22 opposite to the second feeding rail 42 to the second feeding rail 42 The opposite side is convex.

The pair of inclined portions 28 of the respective guide members 21 and 22 are arranged to be spaced apart from each other in the vertical direction. The pair of inclined portions 28 of the respective guide members 21, 22 are inclined such that the distance between the pair of inclined portions 28 is larger and wider from the parallel portion 27 in the moving direction of the mobile device 30.

The pair of movable member guides 24 and 25 of the respective guide members 21 and 22 function when the vertical position of the first feeding rail 41 and the vertical position of the second feeding rail 42 are deviated by, for example, a construction error. .

The first guiding member 21 (refer to FIG. 3 ) moves (travels) from the second feeding rail 42 side to the first feeding rail 41 side along the plurality of feeding rails 41 and 42 as the movable member 5 moves along with the moving device 30 . At this time, the movable member 5 is guided. Thereby, the movable member 5 is displaced in the vertical direction, and the electric wires 451 corresponding to the respective current collectors 63 and the first electric power supply rail 41 are disposed at the same position in the vertical direction.

When the movable member 5 moves (travels) from the first feeding rail 41 side to the second feeding rail 42 side along the plurality of feeding rails 41 and 42 in accordance with the movement of the moving device 30, the second guiding member 22 is guided to move. Member 5. Thereby, the movable member 5 is displaced in the vertical direction, and the electric wires 452 corresponding to the respective current collectors 63 and the second electric power feeding rail 42 are disposed at the same position in the vertical direction.

Specifically, a case where the movable member 5 moves from the first power supply rail 41 to the second power supply rail 42 along the plurality of power supply rails 41 and 42 in accordance with the movement of the mobile device 30 will be described. In this case, as shown in FIG. 5A, first, one of the pair of upper and lower casters 58 provided at the front end portion of the movable member 5 in the traveling direction contacts the inclined portion 28 corresponding to the second guiding member 22.

When the movable member 5 moves further toward the second power supply rail 42 side, the wheel 55 contacting the caster 58 of the inclined portion 28 rotates along the corresponding inclined portion 28. As a result, as shown in FIG. 5B, the movable member 5 is displaced in the vertical direction with respect to the fixed member 10, so that the current collectors 63 are brought closer to the corresponding second electric wire 452 in the vertical direction.

As shown in FIG. 5C, the movable member 5 moves further toward the second feeding rail 42 side and enters between the pair of parallel portions 27 of the second guiding member 22. After that, each of the current collectors 63 of the movable member 5 is disposed at the same position as the corresponding second electric wire 452 in the vertical direction.

Then, the movable member 5 moves to the second feeding rail 42 side while being restricted in the vertical direction by the pair of parallel portions 27. After that, the contact piece portion 68 (see FIG. 1) of each of the current collectors 63 enters the corresponding accommodation groove 46 of the second power supply rail 42 and comes into contact with the corresponding second electric wire 452. That is, when the current collecting device 1 moves from one side of the adjacent power supply rails 41, 42 to the other side, the current collectors 63 of the current collecting device 1 are guided by the guiding members 21, 22 at the movable member 5. After being displaced in the up and down direction, it contacts the corresponding wires 451, 452. Thus, when the current collecting device 1 moves from one side of the adjacent power supply rails 41, 42 to the other side, the current collectors 63 do not contact the movable member guides 24, 25 of the guiding members 21, 22.

The movable member 5 moves to the second power supply rail 42 side after the contact piece portion 68 of each current collector 63 comes into contact with the corresponding second electric wire 452 as described above. After that, as shown in FIG. 5D, the movable member 5 is passed out from between the pair of movable member guides 24, 25 to the second power supply rail 42 side, and is no longer used by the pair of movable member guides 24, 25. guide.

Similarly to the second guiding member 22, the first guiding member 21 of Fig. 3 also guides the movable member 5. That is, the first guiding member 21 guides the movable member 5 when the movable member 5 moves from the second feeding rail 42 to the first feeding rail 41 along the plurality of feeding rails 41, 42 as the moving device 30 moves. . Thereby, the movable member 5 is displaced, and the current collector 63 and the corresponding first electric wire 451 are disposed at the same position in the vertical direction.

As shown in FIG. 5A, a plurality of guide grooves 29 arranged in the vertical direction are formed on the current collector guides 26 of the respective guide members 21, 22 (refer to FIG. 5A). Each of the guide grooves 29 extends in the moving direction of the mobile device 30. Each of the guide grooves 29 opens toward the direction (back) in which the power collecting device 1 and the mobile device 30 are located.

The plurality of guide grooves 29 of the second guiding member 22 are connected to the plurality of storage grooves 46 of the second feeding rail 42 in a one-to-one manner. The groove of each of the guide grooves 29 of the second guiding member 22 becomes narrower in the portion of each of the guiding grooves 29 which is closer to the second feeding rail 42.

Similarly, the plurality of guide grooves 29 of the first guiding member 21 (refer to FIG. 3) are connected to the plurality of storage grooves 46 of the first feeding rail 41 in a one-to-one manner. The groove of each of the guide grooves 29 of the first guiding member 21 becomes narrower in the portion of each of the guiding grooves 29 which is closer to the first feeding rail 41.

The plurality of guiding grooves 29 of the guiding members 21, 22 are in a state where the movable member 5 enters between the pair of parallel portions 27 of the guiding members 21, 22, and the power supply rails to which the guiding members 21, 22 are connected When the 41 and 42 sides move, they play a role.

For example, as shown in FIG. 5C, when the movable member 5 enters between the pair of parallel portions 27 of the second guiding member 22 and moves toward the second feeding rail 42 side, the respective collectors 63 enter the corresponding guides. Ditch 29. When the movable member 5 moves to the second power supply rail 42 side, the current collectors 63 are guided by the corresponding guide grooves 29, and the second electric wires 452 are disposed at the same position in the vertical direction. Displacement. The displacement of the current collector 63 is realized by the rotation of the third rotating member 73 (refer to FIG. 1) of the corresponding arm portion 65 with respect to the holding portion 57. (Second embodiment)

Next, a second embodiment will be described. In the following description of the second embodiment, the same components as those of the first embodiment are denoted by the same reference numerals, and the description of the same portions as those of the first embodiment will be omitted.

As shown in FIG. 3, the longitudinal direction of the first feeding rail 41 and the longitudinal direction of the second feeding rail 42 in the first embodiment are parallel as viewed from the vertical direction. On the other hand, as shown in FIG. 6 , the longitudinal direction of the second feeding rail 42 of the present embodiment is perpendicular to the longitudinal direction of the first feeding rail 41 as viewed in the vertical direction.

As shown in FIG. 7, the guide member 23 is provided in the 2nd power supply rail 42. The guide member 23 is provided at a position corresponding to the first power supply rail 41 in the second power supply rail 42. In Fig. 7, an arrow D4 indicates a moving direction in which the current collecting device 1 moves with the movement of the mobile device 30.

The guide member 23 is provided with a pair of upper and lower movable member guides 24 and 25. The guide member 23 of the present embodiment does not include the current collector guide 26.

One of the pair of movable member guides 24, 25 is located above the second power supply rail 42, and the other movable member guide 25 is located below the second power supply rail 42. Each of the movable member guides 24, 25 is formed in a plate shape. Each of the movable member guides 24 and 25 protrudes toward the first power supply rail 41 side from the second power supply rail 42.

Each of the movable member guides 24, 25 has a parallel portion 27 and an inclined portion 28. The parallel portion 27 is formed in a horizontal plate shape. The parallel portion 27 of the movable member guide 24 protrudes from the upper side of the second power supply rail 42 toward the first power supply rail 41 side.

The parallel portion 27 of the movable member guide 25 protrudes from the lower side of the second power supply rail 42 toward the first power supply rail 41 side.

The pair of parallel portions 27 of the guide member 23 are partitioned in the up and down direction. The pair of parallel portions 27 of the guiding member 23 are opposed to each other. The interval between the pair of parallel portions 27 of the guiding member 23 is fixed in the moving direction of the mobile device 30.

Each of the inclined portions 28 of the movable member guides 24 and 25 projects from the end portion of the parallel portion 27 on the first power supply rail 41 side toward the first power supply rail 41 side. The pair of inclined portions 28 of the guiding member 23 are partitioned in the vertical direction. The pair of inclined portions 28 of the guide member 23 are inclined such that the portion of the pair of inclined portions 28 that is closer to the first power supply rail 41 becomes wider as the interval between the pair of inclined portions 28.

The guide member 23 of the present embodiment is used to guide the movable member 5 in the same manner as the guide members 21 and 22 of the first embodiment. In other words, the guiding member 23 guides the movable member 5 when the movable member 5 moves from the first feeding rail 41 to the second feeding rail 42 in association with the movement of the moving device 30. Thereby, the movable member 5 is displaced, and the current collector 63 and the corresponding second electric wire 452 are disposed at the same position in the vertical direction.

The current collecting device 1 according to the first embodiment and the second embodiment described above has the following features. The current collecting device 1 includes collector arms 61 and 62, a movable member 5, and a displacement mechanism 9. The collector arms 61, 62 have a current collector 63 and an arm portion 65. The current collector 63 is in contact with the power supply path 45. One end portion (first end portion) of the arm portion 65 holds the current collector 63. An end portion (second end portion) of the arm portion 65 opposite to the current collector 63 is held by the movable member 5. The movable member 5 is connectable to a coupling member (fixing member 10) provided in the mobile device 30 via the displacement mechanism 9. The displacement mechanism 9 displaces the movable member 5 with respect to the joint member. The displacement mechanism 9 restricts the displacement direction of the movable member 5 with respect to the connection member to a direction different from the longitudinal direction of the power supply path 45. Hereinafter, this current collecting device 1 will be referred to as "the first aspect of the current collecting device 1".

The current collecting device 1 of the first aspect is effective when a part of the longitudinal direction of the power feeding path 45 is partially displaced in a direction intersecting the longitudinal direction of the power feeding path 45. In this case, by the displacement of the movable member 5 with respect to the joint member, the current collector 63 is easily brought into proper contact with the power supply path 45. Further, compared with the design in which the movable member 5 is fixed to the connecting member, the displacement amount of the current collector 63 with respect to the movable member 5 can be suppressed, and the current collector 63 is fixed to the movable member 5, and the direction of the current collector 63 can be easily stabilized. Therefore, the contact failure between the current collector 63 and the power supply path 45 can be suppressed.

Further, in the current collecting device 1 of the first embodiment and the second embodiment, the current collecting device of the first aspect has the following additional features. The displacement direction of the movable member 5 by the displacement mechanism 9 is a direction intersecting the longitudinal direction of the power supply path 45 and intersecting the opposing direction of the current collector 63 and the power supply path 45. Hereinafter, this current collecting device 1 will be referred to as "the second embodiment of the current collecting device 1".

The current collecting device 1 of the second aspect described above partially intersects the longitudinal direction of the power feeding path 45 with respect to the other portion in the longitudinal direction of the power feeding path 45, and is opposed to the opposing direction of the current collector 63 and the power feeding path 45. It is effective when the direction of the intersection deviates. In this case, the current collector 63 is easily contacted with the electric wire 45 by displacement of the movable member 5 with respect to the joint member.

Further, the current collecting device 1 of the first embodiment and the second embodiment has the following additional features in the power collecting device 1 of the first or second aspect. The current collecting device 1 further includes an elastic member 15. When the elastic member 15 is displaced in the displacement direction from the reference position within the displacement range restricted by the displacement mechanism 9, the elastic member 15 imparts an elastic force to the direction in which the movable member 5 is displaced toward the reference position. Hereinafter, this current collecting device 1 will be referred to as "the third embodiment of the current collecting device 1".

In the current collecting device 1 of the third aspect described above, when the movable member 5 is displaced from the reference position, the elastic force of the movable member 5 is restored to the reference position by the elastic member 15.

In the power collecting device 1 of the first embodiment and the second embodiment, the current collecting device 1 of the third aspect has the following additional features. The elastic member 15 has springs 161, 162. The movable member 5 is held by the coupling member via the springs 161 and 162. Hereinafter, this current collecting device 1 will be referred to as "the fourth embodiment of the current collecting device 1".

In the current collecting device 1 of the fourth aspect described above, when the movable member 5 is displaced, the displacement speed of the movable member 5 is reduced by the springs 161 and 162. Therefore, it is possible to suppress the movable member 5 from strongly contacting the fixing member 10.

Further, in the current collecting device 1 of the first embodiment and the second embodiment, the current collecting device 1 of any of the first to fourth aspects has the following additional features. The displacement mechanism 9 includes bearings 91 and 92 provided in one of the movable member 5 and the connecting member, and shafts 941 and 942 provided in the other of the movable member 5 and the connecting member. The shafts 941, 942 are movably supported by the bearings 91, 92 in the axial direction of the shafts 941, 942, whereby the movable member 5 is displaceable relative to the joint member. Hereinafter, this current collecting device 1 will be referred to as "the fifth aspect of the current collecting device 1".

The current collecting device 1 of the fifth aspect described above is a simple mechanism in which the displacement mechanism 9 uses the shafts 941 and 942 and the bearings 91 and 92.

In the power collecting device 1 of the first embodiment and the second embodiment, the power collecting device 1 of the fifth aspect has the following additional features. The shafts 941 and 942 are provided in the joint member. Bearings 91 and 92 are provided to the movable member 5. Hereinafter, this current collecting device 1 will be referred to as "the sixth embodiment of the current collecting device 1".

The current collecting device 1 of the sixth aspect described above is a simple mechanism in which the displacement mechanism 9 uses the shafts 941 and 942 provided in the connecting member and the bearings 91 and 92 provided in the movable member 5.

Further, in the current collecting device 1 of the first embodiment and the second embodiment, the current collecting device 1 of any of the first to sixth aspects has the following additional features. The movable member 5 has a guided portion (caster 58). The guided portion is guided by the guiding members 21, 22 (or 23) provided on the power supply path 45, whereby the movable member 5 is displaced in the displacement direction of the movable member 5 to dispose the current collector 63 and the power supply path 45. In the same location. Hereinafter, this current collecting device 1 will be referred to as "the seventh embodiment of the current collecting device 1".

In the current collecting device 1 of the seventh aspect, the guide portion is guided by the guiding members 21, 22 (or 23), and the current collector 63 and the power supply path 45 are disposed in the displacement direction of the movable member 5 The same location. Therefore, the contact failure between the current collector 63 and the power supply path 45 can be suppressed.

In the power collecting device 1 of the first embodiment and the second embodiment, the power collecting device 1 of the seventh aspect has the following additional features. The guided portion is provided at an end portion on the front side in the traveling direction of the movable member 5 that moves along the power supply path 45. Hereinafter, this current collecting device 1 will be referred to as "the eighth embodiment of the current collecting device 1".

In the current collecting device 1 of the eighth aspect, when the movable member 5 moves along the power feeding path 45, the guided portion is likely to first contact the guiding members 21, 22 (or 23) in the movable member 5.

Further, in the current collecting device 1 of the first embodiment and the second embodiment, the power collecting device 1 of the eighth aspect has the following additional features. The guided portion is a caster 58. Hereinafter, this current collecting device 1 will be referred to as "the ninth aspect of the current collecting device 1".

The current collecting device 1 of the ninth aspect described above is rotated by the caster 58 with respect to the guiding members 21, 22 (or 23), so that the movable member 5 can be smoothly guided by the guiding members 21, 22 (or 23).

Further, in the current collecting device 1 of the first embodiment and the second embodiment, the current collecting device 1 of any of the first to ninth aspects has the following additional features. The arm portion 65 is coupled to the movable member 5 around the rotation axis. The axial direction of the rotating shaft intersects with the displacement direction. In the current collecting device 1 having this feature, the arm portion 65 is rotated with respect to the movable member 5, whereby the current collector 63 held by the arm portion 65 is displaced. Hereinafter, this current collecting device 1 will be referred to as "the power collecting device 1 of the tenth aspect."

In the current collecting device 1 of the tenth aspect described above, the displacement amount of the current collector 63 can be increased.

Further, the power transmission system 2 of the first embodiment and the second embodiment has the following features. The power transmission system 2 includes a power supply path 45 and a power collecting device 1. The current collecting device 1 includes collector arms 61 and 62, a movable member 5, and a displacement mechanism 9. The collector arms 61, 62 have a current collector 63 and an arm portion 65. The current collector 63 is in contact with the power supply path 45. One end of the arm portion 65 holds the current collector 63. The end of the arm portion 65 opposite to the current collector 63 is held by the movable member 5. The movable member 5 is connectable to a coupling member (fixing member 10) provided in the mobile device 30 via the displacement mechanism 9. The displacement mechanism 9 displaces the movable member 5 with respect to the joint member. The displacement mechanism 9 restricts the displacement direction of the movable member 5 to a direction different from the longitudinal direction of the power supply path 45. Hereinafter, this power transmission system 2 will be referred to as "the eleventh aspect of the power transmission system 2".

In the power transmission system 2 of the eleventh aspect described above, the mobile device 30 can be supplied with electric power from the power supply path 45 via the current collectors 63 of the collector arms 61 and 62. Further, even if a part of the power supply path 45 is disposed at a position deviated from the other portion, the movable member 5 is displaced relative to the connecting member, so that the current collector 6 becomes easily accessible to the power supply path 45.

Further, the power transmission system 2 according to the first embodiment and the second embodiment has the following additional features in the power transmission system 2 of the eleventh aspect. The power transmission system 2 is further provided with guiding members 21, 22 (or 23). The movable member 5 has a guided portion (caster 58). The guiding members 21, 22 (or 23) displace the movable member 5 by guiding the guided portion, and arrange the current collector 63 and the power supply path 45 at the same position in the displacement direction. Hereinafter, this power transmission system 2 will be referred to as "the power transmission system 2 of the twelfth aspect".

In the power transmission system 2 of the twelfth aspect described above, the current collector 63 and the power supply path 45 are caused in the displacement direction of the movable member 5 by guiding the guided portion with the guiding members 21, 22 (or 23). Configured in the same location. Therefore, the contact failure between the current collector 63 and the power supply path 45 can be suppressed.

Further, the power transmission system 2 according to the first embodiment and the second embodiment has the following additional features in the power transmission system 2 of the twelfth aspect. The power supply path 45 includes a first electric wire 451 and a second electric wire 452 which is provided at a position away from the first electric wire 451 in the longitudinal direction of the first electric wire 451. When the movable member 5 moves from the first electric wire 451 side to the second electric wire 452 side along the power supply path 45, the guided portion is guided by the guiding members 21, 22 (or 23). Thereby, the movable member 5 is displaced in the displacement direction so that the current collector 63 and the second electric wire 452 are disposed at the same position. Hereinafter, this power transmission system 2 will be referred to as "the power transmission system 2 of the thirteenth aspect".

In the power transmission system 2 of the thirteenth aspect, when the movable member 5 moves from the first electric wire 451 side to the second electric wire 452 side along the power supply path 45, the guiding members 21, 22 (or 23) are guided. Leading section. Thereby, the movable member 5 is displaced, and the current collector 63 and the second electric wire 452 are disposed at the same position in the displacement direction of the movable member 5. Therefore, the movable member 5 is displaced so that the current collector 63 comes into contact with the second electric wire 452, and the contact failure between the second electric wire 452 and the current collector 63 can be suppressed.

1‧‧‧ Collector
10‧‧‧Fixed components (connecting members)
11‧‧‧1st link
12‧‧‧2nd link
13‧‧‧ Fixed Department
141‧‧‧1st shaft through hole
142‧‧‧2nd shaft through hole
15‧‧‧Flexible components
151‧‧‧1st Elastomer
152‧‧‧2nd elastomer
161‧‧‧1st spring
162‧‧‧2nd spring
2‧‧‧Power transmission system
21‧‧‧1st guiding member
22‧‧‧2nd guiding member
23‧‧‧Guide members
24‧‧‧ movable member guide
25‧‧‧ movable member guide
26‧‧‧ Collector guides
27‧‧‧Parallel
28‧‧‧ inclined section
29‧‧‧ Guide groove
30‧‧‧Mobile devices
41‧‧‧1st power supply track
42‧‧‧2nd power supply track
44‧‧‧ sheath
45‧‧‧Power supply path
451‧‧‧1st wire
452‧‧‧2nd wire
46‧‧‧ Storage ditch
47‧‧‧Contact surface
5‧‧‧ movable components
50‧‧‧Frame
51‧‧‧1st connected department
510‧‧‧Protruding
52‧‧‧2nd connected department
520‧‧‧protrusion
53‧‧‧Installation Department
54‧‧‧Installation Department
55‧‧‧ Wheels
56‧‧‧Retaining body
57‧‧‧ Holding Department
58‧‧‧ casters (guided)
59‧‧‧ Frame Department
61‧‧‧1st collector arm
62‧‧‧2nd collector arm
63‧‧‧ Collectors
64‧‧‧Contacted
65‧‧‧arms
66‧‧‧ Collector holder
67‧‧‧arm body
68‧‧‧Contacts
69‧‧‧ biasing members
71‧‧‧1st rotating member
72‧‧‧2nd rotating member
73‧‧‧3rd rotating member
74‧‧‧Connected components
75‧‧‧Rotation suppression component
80‧‧‧Fixed parts
81‧‧‧1st spring piece
82‧‧‧2nd spring piece
9‧‧‧displacement mechanism
91‧‧‧1st bearing
92‧‧‧2nd bearing
93‧‧‧ bearing body
941‧‧‧1st axis
942‧‧‧2nd axis
D1‧‧‧Up and down direction
D2‧‧‧ direction
D3‧‧‧Mobile device movement direction
D4‧‧‧Moving direction of the current collector

Fig. 1 is a perspective view of the power collecting device of the first embodiment as seen from the front side. Fig. 2 is a perspective view seen from the rear side of the current collecting device. Fig. 3 is a plan view showing a power transmission system according to the first embodiment. Fig. 4 is a cross-sectional view showing a pattern in which a current collector of the current collecting device is in contact with a power supply path. 5A to 5D are rear views showing the pattern in which the current collecting device is guided by the guiding member and moved on the first feeding rail side. Fig. 6 is a plan view showing a power transmission system and a mobile device according to a second embodiment. Fig. 7 is a perspective view showing a first power supply rail, a guide member, and a current collecting device according to a second embodiment.

1‧‧‧ Collector

10‧‧‧Fixed components (connecting members)

11‧‧‧1st link

12‧‧‧2nd link

13‧‧‧ Fixed Department

15‧‧‧Flexible components

151‧‧‧1st Elastomer

152‧‧‧2nd elastomer

161‧‧‧1st spring

162‧‧‧2nd spring

5‧‧‧ movable components

50‧‧‧Frame

51‧‧‧1st connected department

510‧‧‧Protruding

53‧‧‧Installation Department

54‧‧‧Installation Department

55‧‧‧ Wheels

56‧‧‧Retaining body

57‧‧‧ Holding Department

58‧‧‧ casters (guided)

59‧‧‧ Frame Department

61‧‧‧1st collector arm

62‧‧‧2nd collector arm

63‧‧‧ Collectors

64‧‧‧Contacted

65‧‧‧arms

66‧‧‧ Collector holder

67‧‧‧arm body

68‧‧‧Contacts

69‧‧‧ biasing members

71‧‧‧1st rotating member

72‧‧‧2nd rotating member

73‧‧‧3rd rotating member

74‧‧‧Connected components

75‧‧‧Rotation suppression component

80‧‧‧Fixed parts

81‧‧‧1st spring piece

82‧‧‧2nd spring piece

9‧‧‧displacement mechanism

91‧‧‧1st bearing

92‧‧‧2nd bearing

93‧‧‧ bearing body

942‧‧‧2nd axis

D1‧‧‧Up and down direction

D2‧‧‧ direction

Claims (13)

A current collecting device comprising: a collecting arm, a movable member and a displacement mechanism, the collecting arm having: a current collector contacting the power supply path; and an arm portion, the one end portion holding the current collector, and the opposite side of the current collector The end portion is held by the movable member, and the movable member is coupled to the connecting member provided on the mobile device via the displacement mechanism, the displacement mechanism can displace the movable member relative to the connecting member, and the movable member is The direction of displacement of the connecting member is limited to a direction different from the longitudinal direction of the power feeding path. The current collecting device of claim 1, wherein the displacement direction of the movable member intersects with a longitudinal direction of the power supply path and is opposite to the current collector and the power supply path. The direction in which the directions intersect. The current collecting device of claim 1 or 2, further comprising: an elastic member, wherein the movable member is displaced toward the displacement direction from a reference position within a displacement range of the displacement mechanism The direction of displacement to the reference position imparts an elastic force. The current collecting device of claim 3, wherein the elastic member has a spring, and the movable member is held by the connecting member via the spring. The current collecting device of claim 1 or 2, wherein the displacement mechanism has: a bearing disposed in one of the movable member and the connecting member; and a shaft disposed in the movable member and the connecting member Alternatively, the shaft is supported by the bearing in such a manner as to be axially movable along the shaft, whereby the movable member is displaceable relative to the joint member. The current collecting device of claim 5, wherein the shaft is disposed on the connecting member, and the bearing is disposed on the movable member. The current collecting device of claim 1 or 2, wherein the movable member has a guided portion guided by a guiding member provided on the power supply path to displace the movable member And in the displacement direction, the current collector and the power supply path are disposed at the same position. The current collecting device of claim 7, wherein the guided portion is provided at an end portion on a front side in a traveling direction of the movable member that moves along the power supply path. The current collecting device of claim 8, wherein the guided portion is a caster. The current collecting device of claim 1 or 2, wherein the arm portion is coupled to be rotatable about a rotating shaft with respect to the movable member, and an axial direction of the rotating shaft intersects the displacement direction. A power transmission system including a power supply path and a current collecting device, the power collecting device includes: a collector arm, a movable member, and a displacement mechanism, the collector arm having: a current collector contacting the power supply path; and an arm portion The portion holds the current collector, and the end portion opposite to the current collector is held by the movable member, and the movable member is coupled to the connecting member provided on the mobile device via the displacement mechanism, and the displacement mechanism can The movable member is displaced with respect to the coupling member, and the displacement direction of the movable member is restricted to a direction different from the longitudinal direction of the power supply path. The power transmission system of claim 11, further comprising a guiding member having a guided portion, the guiding member displaces the movable member by guiding the guided portion In the displacement direction, the current collector and the power supply path are disposed at the same position. The power transmission system of claim 12, wherein the power supply path includes: a first electric wire; and a second electric wire provided at a position away from the first electric wire in a longitudinal direction of the first electric wire When the member moves along the power supply path from the first electric wire side to the second electric wire side, the guided portion is guided by the guiding member, thereby displacing the movable member, and the displacement is made in the displacement direction. The current collector and the second electric wire are disposed at the same position.