JP2019172246A - vehicle - Google Patents

Abstract

To provide a vehicle which can load sub mobilities, each of which has an occupant therein, and enable the sub mobilities loaded therein to be charged in the vehicle.SOLUTION: A vehicle 1 includes: a vehicle body 3 in which sub mobilities 50 each having an occupant therein can be loaded; positioning mechanisms 81 to 83 which are provided at the vehicle body 3 and position the sub mobilities 50 in predetermined positions of the vehicle body 3; and power supply parts 20, each of which is provided at the vehicle body 3 and contacts with or moves close to a power reception part 61 of the sub mobility 50 positioned at the predetermined position to supply electric power to the power reception part 61. The power supply part 20 is placed in contact with or moved close to the power reception part 61 by self-propelling of the sub mobility 50.SELECTED DRAWING: Figure 5

Description

  The present invention relates to a vehicle that can move by loading sub-mobility on which an occupant is riding.

Conventionally, wheelchairs are used for elderly people and handicap persons who have difficulty walking on their own.
In recent years, personal mobility such as a wheelchair that can be self-propelled by an electric motor or the like has begun to be proposed.
In order to create a society where people who have difficulty walking on their own can easily work, personal mobility can be used not only for people who have difficulty walking on their own but also for people who can walk on their own. It is important to have
Therefore, for example, as disclosed in Patent Documents 1 and 2, for example, a wheelchair, it is considered important that a person can get into a vehicle such as an automobile while riding on personal mobility.

JP 2006-006702 A JP 2004-11495 A

  By the way, when the sub-mobility gets into the vehicle as described above, it is preferable that the sub-mobility on the vehicle can be charged in the vehicle. As a result, the occupant can get on the sub-mobility that is not fully charged and start moving to charge the sub-mobility within the vehicle. And after getting off the vehicle, it can move to the destination using the fully charged sub-mobility or move at the destination. With such added value, the convenience of the next-generation transportation system in which sub-mobility and vehicles are organically connected is enhanced, and the use thereof can be expected.

However, since the sub-mobility is formed separately from the vehicle, there is a possibility that the sub-mobility moves in the vehicle. Therefore, the sub-mobility loaded on the vehicle needs to be positioned so as to be fixed in the vehicle.
Moreover, when charging the sub-mobility loaded on the vehicle, the sub-mobility and the vehicle must be electrically connected in the positioned state.

  As described above, a vehicle capable of loading the sub-mobility in a state where a person is on is required to be able to charge the loaded sub-mobility in the vehicle.

  A vehicle according to the present invention is provided with a vehicle body on which a sub-mobility in a state in which a person gets on can be loaded, a positioning mechanism that is provided in the vehicle body, and that positions the sub-mobility at a predetermined position of the vehicle body, and is provided in the vehicle body. A power feeding unit that is in contact with or close to the power receiving unit of the sub-mobility positioned at a predetermined position and supplies power to the power receiving unit. , In contact with or close to the power receiving unit.

  Preferably, the power feeding unit is provided on a projecting member projecting from a floor surface or a side surface of the vehicle body, and the positioning mechanism performs the sub-mobility moving on the floor surface of the vehicle body toward the projecting member. The sub-mobility may be positioned at a predetermined position of the vehicle body by pressing.

  Preferably, a positioning recess into which the wheel of the sub-mobility enters is formed as the positioning mechanism on the floor surface of the vehicle body on which the sub-mobility moves. It is good to be positioned by falling into the recess and to be in contact with or close to the power receiving unit of the sub-mobility.

  Preferably, the power supply unit of the sub-mobility includes a main non-energized member that covers the power feeding unit that is in contact with or close to, and the main non-conductive member is movable when the sub-mobility moves to the predetermined position. Then, the power feeding unit is preferably exposed.

  Preferably, the main non-energizing member is slidable by being pushed by the sub-mobility moving to the predetermined position.

  Preferably, the sub-mobility includes a sub-non-energizing member that covers the power reception unit, and the sub-non-energization member is movable when the sub-mobility moves to the predetermined position to It should be exposed.

  Preferably, the sub-non-energizing member is slidable by being pushed in contact with the vehicle body when the sub-mobility moves to the predetermined position.

  Preferably, the main non-energized member or the sub-non-energized member may extend along the moving direction of the sub-mobility toward the predetermined position and function as a movement guide for the sub-mobility.

  Preferably, the sub-mobility moves in a state where the sub-mobility rides on a platform that is slidable toward a predetermined positioning position on the floor surface of the vehicle body.

In the present invention, since the positioning mechanism for the sub-mobility is provided in the vehicle body, the sub-mobility can be positioned at a predetermined position in the vehicle body.
In addition, in a state where the sub-mobility is positioned at the predetermined position, the sub-mobility power receiving unit can be brought into contact with or close to the vehicle power supply unit provided on the vehicle body. Sub-mobility and vehicle can be electrically connected.
Therefore, the vehicle can supply power to the power receiving unit of the submobility that is in contact with or close to the power feeding unit.

FIG. 1 is an overview of an example of sub-mobility applied to the present invention. FIG. 2 is an explanatory diagram of an example of the electric circuit of the submobility of FIG. FIG. 3 is a schematic overview of the automobile according to the present embodiment. FIG. 4 is an explanatory diagram of an example of the sub-mobility charging system for the automobile shown in FIG. FIG. 5 is an explanatory diagram of a positioning mechanism and an electrical connection mechanism for sub-mobility according to the first embodiment of the present invention. FIG. 6 is an explanatory diagram of a positioning mechanism and an electrical connection mechanism for sub-mobility in the second embodiment. FIG. 7 is an explanatory diagram of a sub-mobility positioning mechanism and an electrical coupling mechanism according to the third embodiment. FIG. 8 is an explanatory diagram of an electrical connection mechanism for sub-mobility in the fourth embodiment. FIG. 9 is an explanatory diagram of a positioning mechanism and an electrical connection mechanism for sub-mobility in the fifth embodiment.

  Hereinafter, embodiments of the present invention will be described with reference to the drawings.

[First Embodiment]
FIG. 1 is an overview of an example of a sub-mobility 50 applied to the present invention.
As shown in FIG. 1, the sub-mobility 50 has an egg-shaped body 51. A seat 52 on which an occupant is seated is disposed inside the body 51. Armrests 53 are disposed on the left and right sides of the seat 52. An operation lever 54 is disposed at the tip of the armrest 53. A plurality of wheels 55 are provided at the lower portion of the body 51.

FIG. 2 is an explanatory diagram of an example of an electric circuit of the submobility 50 of FIG.
As shown in FIG. 2, the sub-mobility 50 of FIG. 1 includes, as a power system circuit, a sub power receiving unit 61, a sub charger 62, a sub battery 63, a sub converter 64, and a sub power motor 65 that drives a plurality of wheels 55. , An auxiliary braking motor 66, an auxiliary steering motor 67, and an auxiliary equipment device 68 are provided.

The sub power receiving unit 61 is connected to, for example, a commercial power source and a power cord. The sub charger 62 charges the sub battery 63 with the power supplied from the sub power receiving unit 61.
The sub-converter 64 converts the stored electric power of the sub-battery 63 and supplies it to load devices such as the sub-power motor 65, the sub-braking motor 66, the sub steering motor 67, and the sub facility equipment 68.
When the auxiliary power motor 65 is driven, the plurality of wheels 55 rotate, and the submobility 50 can move forward or backward.
By driving the sub steering motor 67, the direction of the wheels 55 is changed, and the sub mobility 50 can be deployed left and right.
By driving the auxiliary braking motor 66, the rotation of the plurality of wheels 55 is braked. Thereby, the submobility 50 can be stopped.
In this way, the sub-mobility 50 can travel with the passenger on the seat 52 using the stored power of the sub-battery 63 charged by the power supplied from the sub-power receiving unit 61.

  Further, in FIG. 2, as a control system circuit, a sub power monitoring unit 71, a sub power control unit 72, a sub GPS (Global Positioning System) receiving unit 73, a sub input unit 74, a sub communication unit 75, a sub display unit 76 are provided. A sub sensor unit 77, a sub route generation unit 78, and a sub automatic operation unit 79. The sub power control unit 72, the sub route generation unit 78, and the sub automatic operation unit 79 may be realized by a CPU (Central Processing Unit) 80 executing a program. This control system circuit may receive power supply from the sub-converter 64 as a part of the sub-equipment device 68 described above.

The sub power monitoring unit 71 monitors the state of the sub battery 63. Examples of the state of the sub battery 63 include a charging voltage and a temperature.
The sub power control unit 72 controls the sub charger 62 and the sub converter 64 based on the information from the sub power monitoring unit 71. For example, when the power cord is connected to the sub power receiving unit 61 and the sub battery 63 can be charged by the sub charger 62, charging by the sub charger 62 is controlled until the voltage of the sub battery 63 reaches a predetermined maximum voltage. To do. When the voltage of the sub battery 63 is lower than the predetermined minimum voltage, the power conversion by the sub converter 64 is stopped. When the voltage is lower than the predetermined minimum voltage, the power supplied from the sub-converter 64 to each load device is reduced. The sub power control unit 72 notifies the sub route generation unit 78 and the sub automatic operation unit 79 of the power control state and the state of the sub battery 63 as appropriate or periodically.

The sub GPS receiver 73 receives radio waves from GPS satellites. The position of the submobility 50 can be calculated by receiving radio waves from a plurality of GPS satellites.
The sub input unit 74 is a device to which an occupant's operation is input, and includes the operation lever 54 described above, for example.
The sub-communication unit 75 communicates with other devices, for example, the main communication unit 35 of the automobile 1 to transmit and receive data. Further, the location information of the base station can be acquired by communicating with the base station.
The sub display unit 76 is, for example, a touch panel type liquid crystal device. This touch panel can function as a part of the sub input unit 74.
The sub sensor unit 77 detects the position, speed, ambient environment, and the like of the sub mobility 50.
The sub route generation unit 78 generates a patrol route from the current position of the sub-mobility 50 to the destination by inputting, for example, a destination.
The auxiliary automatic driving unit 79 outputs control signals to the auxiliary power motor 65, the auxiliary braking motor 66, and the auxiliary steering motor 67, for example, according to the generated patrol route. Thereby, the submobility 50 can automatically move to the destination by following the patrol route.

By the way, in order to create a society in which sub-mobility 50 is widely spread and, as a result, people who are unable to walk on their own are easily active, sub-mobility 50 is used not only for people who are unable to walk on their own, but also for those who can walk on their own. It is important to have
For this reason, it is considered important that a person can get into a vehicle such as the automobile 1 while getting on the sub-mobility 50.
In addition, when the sub-mobility 50 gets into the automobile 1 in this way, it is preferable that the sub-mobility 50 that is on the board 1 can be charged in the automobile 1. As a result, the occupant can get on the sub-mobility 50 in a state where sufficient charging has not been performed and start moving to charge the sub-mobility 50 in the automobile 1. And after getting off from the automobile 1, the sub-mobility 50 that is sufficiently charged can be used to move to the destination or move at the destination. Due to such added value, the convenience of the next-generation transportation system in which the sub-mobility 50 and the automobile 1 are organically coupled is enhanced, and the use thereof can be expected.

However, since the sub-mobility 50 is formed separately from the automobile 1, there is a possibility that the sub-mobility 50 moves within the automobile 1. Therefore, the sub-mobility 50 loaded on the automobile 1 needs to be positioned so as to be fixed in the vehicle.
Moreover, if the sub-mobility 50 loaded on the automobile 1 is to be charged, the sub-mobility 50 and the automobile 1 must be electrically connected in the positioned state.

  Thus, in the automobile 1 that can load the sub-mobility 50 in a state where a person is on, it is required to be able to charge the loaded sub-mobility 50 in the vehicle.

FIG. 3 is a schematic overview of the automobile 1 according to this embodiment. FIG. 3A is a side view. FIG. 3B is a plan view.
3 includes a vehicle body 3 having a passenger compartment 2 and wheels 4 provided at a lower portion of the vehicle body 3. In the passenger compartment 2, two sub-mobilities 50 are boarded in two rows of two each.
FIG. 3 also shows a main power receiving coil 12 provided on the floor surface of the vehicle body 3 and a power transmission coil 101 provided on a travel lane 100 on the road surface on which the automobile 1 can travel. The power transmission coil 101 can supply electric power to the automobile 1 running on the road lane 100 on the road surface in a contactless manner. The main power receiving coil 12 receives power supply from the power transmitting coil 101 outside the automobile 1.

FIG. 4 is an explanatory diagram of an example of the sub-mobility charging system of the automobile 1 in FIG. The automobile 1 is an example of a vehicle.
As shown in FIG. 4, the car 1 of FIG. 3 drives a main power receiving connector 11, a main power receiving coil 12, a main charger 13, a main battery 14, a main converter 15, and a plurality of wheels 4 as power system circuits. A main power motor 16, a main brake motor 17, a main steering motor 18, a main equipment 19, and a main power feeding unit 20 are provided.

The main power receiving connector 11 is used when the automobile 1 is parked, and is connected to, for example, a commercial power source and a power cord. The main charger 13 charges the main battery 14 with electric power supplied from the main power receiving coil 12 or the main power receiving connector 11.
Main converter 15 converts the stored electric power of main battery 14 and supplies it to load devices such as main power motor 16, main braking motor 17, main steering motor 18, main equipment 19, and main power supply unit 20. The main converter 15 supplies the power supplied to the main power receiving connector 11 and the main power receiving coil 12 or the stored power of the main battery 14 to the power feeding connector.
The main power feeding unit 20 is connected to the sub power receiving unit 61 of the loaded sub mobility 50 by a power cord or the like. This is used to supply electric power of the automobile 1 to the loaded sub-mobility 50.
When the main power motor 16 is driven, the plurality of wheels 4 rotate, and the automobile 1 can move forward or backward.
When the main steering motor 18 is driven, the direction of the wheels 4 is changed, and the automobile 1 can be deployed left and right.
By driving the main braking motor 17, the rotation of the plurality of wheels 4 is braked. Thereby, the automobile 1 can be stopped.
Thus, the automobile 1 can travel with the sub-mobility 50 using the stored power of the main battery 14 charged by the power supplied from the main power receiving coil 12 or the main power receiving connector 11.

  Further, in FIG. 4, a main power monitoring unit 31, a main power control unit 32, a main GPS receiving unit 33, a main input unit 34, a main communication unit 35, a main display unit 36, and a main sensor unit 37 are provided as control system circuits. The main route generation unit 38 and the main automatic operation unit 39 are provided. The main power control unit 32, the main route generation unit 38, and the main automatic operation unit 39 may be realized by the CPU 40 as the control unit executing a program. The CPU 40 may be provided in the automobile 1 as an ECU. Each part of these control systems may receive power supply from the main converter 15 as a part of the main equipment 19 described above.

The main power monitoring unit 31 monitors the state of the main battery 14. Examples of the state of the main battery 14 include a charging voltage and a temperature.
The main power control unit 32 controls the main charger 13 and the main converter 15 based on information from the main power monitoring unit 31. The main power control unit 32 controls power supply to the submobility 50 through the main power supply unit 20 by the main converter 15. For example, when the main power connector is connected to the main power receiving connector 11 and the main battery 14 can be charged by the main charger 13, the charging by the main charger 13 is controlled until the voltage of the main battery 14 reaches a predetermined maximum voltage.

The main GPS receiver 33 receives radio waves from GPS satellites. The position of the automobile 1 can be calculated by receiving radio waves from a plurality of GPS satellites. Note that the main GPS receiving unit 33 may receive other radio waves and obtain a corrected position, for example.
The main input unit 34 is a device to which an occupant's operation is input.
The main communication unit 35 communicates with other devices, for example, the sub communication unit 75 of the sub mobility 50, and transmits and receives data. Further, the location information of the base station can be acquired by communicating with the base station.
The main display unit 36 is, for example, a touch panel type liquid crystal device. This touch panel can function as a part of the main input unit 34. The touch panel type liquid crystal device is disposed on the front surface of the passenger compartment 2, for example. Thereby, the passenger | crew who boarded the some submobility 50 can browse a common display.
The main sensor unit 37 detects the position, speed, ambient environment, and the like of the automobile 1.
The main route generation unit 38 generates a patrol route from the current position of the automobile 1 to a stop-by place, for example, by inputting a destination or the like. The stop-off place may be the same as the destination or a parking place near the destination.
The main automatic driving unit 39 outputs a control signal to the main power motor 16, the main braking motor 17, and the main steering motor 18, for example, according to the generated patrol route. Thereby, the automobile 1 can automatically move to the destination by following the patrol route.

Next, a structure in which the sub-mobility 50 is mounted on the automobile 1 and electrically connected will be described.
FIG. 5 is an explanatory diagram of a positioning mechanism and an electrical connection mechanism for the sub-mobility 50 in the first embodiment of the present invention.
In FIG. 5, the sub-mobility 50 is loaded on the floor surface of the passenger compartment 2 formed in the vehicle body 3 of the automobile 1.

The automobile 1 has a front side stop member 81, a rear side stop member 82, and a stop actuator 83 as positioning mechanisms.
The front side stop member 81 protrudes upward from the floor surface of the passenger compartment 2. The wheel 55 of the submobility 50 is hit.
The vehicle stop actuator 83 is disposed below the floor surface of the passenger compartment 2 and moves up and down the rear vehicle stop member 82. The rear side stop member 82 can protrude upward from the floor surface on the rear side of the wheel 55 that hits the front side stop member 81.
Thereby, the wheel 55 of the submobility 50 is positioned on the floor surface of the passenger compartment 2 so as not to rotate.

In addition, the automobile 1 is provided with a protruding member 86 that protrudes upward from the floor surface of the passenger compartment 2 near the front side stop member 81.
On the upper surface of the protruding member 86, the main power feeding unit 20 is disposed so as to be exposed as an electrical connection mechanism on the automobile 1 side. The exposed portion of the main power feeding unit 20 may be, for example, a metal plate connected to the main converter 15.
A main cover member 87 is provided on the upper side of the projecting member 86 so as to be slidable so as to cover the main power feeding unit 20. The main cover member 87 may be formed in a non-energized manner with an insulating material. Thereby, the main power feeding unit 20 formed of a metal plate is usually covered with the insulating main cover member 87.

The sub-mobility 50 has a protrusion 91 protruding downward at the center of the lower surface of the egg-shaped body 51.
On the lower surface of the protrusion 91, the sub power receiving unit 61 is disposed so as to be exposed as an electrical coupling mechanism on the submobility 50 side. The exposed portion of the sub power receiving unit 61 may be, for example, a metal plate connected to the sub charger 62.
A sub cover member 92 is provided below the protrusion so as to be slidable so as to cover the sub power receiving unit 61. The sub cover member 92 may be formed in a non-energized manner with an insulating material. Thus, the sub power receiving unit 61 formed of a metal plate is usually covered with the insulating sub cover member 92.

Then, as shown in FIG. 5A, the submobility 50 gets on the floor surface of the passenger compartment 2 from a position away from the protruding member 86.
Next, as shown in FIG. 5B, the sub-mobility 50 self-travels toward the protruding member 86.
As a result, the sub cover member 92 slidably provided on the lower side of the projecting portion of the submobility 50 hits the main cover member 87 slidably provided on the upper side of the projecting member 86.
Further, when the sub-mobility 50 is self-propelled, as shown in FIG. 5C, the sub-cover member 92 and the main cover member 87 that are pressed against each other are pushed and slid together, and the main power feeding portion 20 on the upper surface of the projecting member 86. And the sub power receiving unit 61 on the lower surface of the protrusion 91 are exposed and come into contact with each other. Thereby, the main power feeding unit 20 and the sub power receiving unit 61 are in contact with each other and are electrically connected.
Further, the rear stop member 82 is driven upward by the stop actuator 83, and the wheels 55 of the sub-mobility 50 are sandwiched and held by the front stop member 81 and the rear stop member 82 of the positioning mechanism.
As a result, the sub-mobility 50 is positioned and fixed on the floor surface of the vehicle body 3 at a position where the main power feeding unit 20 and the sub power receiving unit 61 are in electrical contact with each other.
In addition, the automobile 1 can supply power to the positioned sub-mobility 50.

As described above, in the present embodiment, since the mechanism for positioning the sub-mobility 50 in the automobile 1 is provided, the sub-mobility 50 can be positioned in a predetermined position in the automobile 1.
In addition, in a state where the submobility 50 is positioned at the predetermined position, the sub power receiving unit 61 of the submobility 50 can be brought into contact with or close to the main power feeding unit 20 provided in the automobile 1. The submobility 50 and the automobile 1 can be electrically connected.
Therefore, the automobile 1 can supply power to the sub power receiving unit 61 of the sub mobility 50 that is in contact with or close to the main power feeding unit 20.
In the present embodiment, the sub-mobility 50 is positioned at a predetermined position of the vehicle body 3 by moving on the floor surface of the vehicle body 3 toward the protruding member 86 and being pressed by the positioning mechanism.
In the present embodiment, the main power feeding unit 20 is covered with the main cover member 87 in a state where the sub-mobility 50 has not moved to a predetermined position. Therefore, at least during non-energization, the main power feeding unit 20 is difficult to get dirty or wet due to dirt or the like of the loaded sub-mobility 50.
In the present embodiment, the main cover member 87 is pushed and slid by the sub-mobility 50 that moves to a predetermined position. Therefore, the main power supply unit 20 can be uncovered by the main cover member 87 only when the sub-mobility 50 is in a predetermined position. In other cases, the main power feeding unit 20 can be maintained in a state covered with the main cover member 87.
In the present embodiment, the sub power receiving unit 61 is covered with the sub cover member 92 in a state where the sub mobility 50 has not moved to a predetermined position. Therefore, at least when power is not supplied, the sub power receiving unit 61 is difficult to get dirty or wet.
In the present embodiment, the sub cover member 92 is slid by being pushed in contact with the member on the vehicle body 3 side when the sub mobility 50 moves to a predetermined position. Therefore, the covering of the sub power receiving unit 61 by the sub cover member 92 can be released only when the sub mobility 50 is at a predetermined position. In other cases, the sub power receiving unit 61 can be kept covered with the sub cover member 92.

  In the present embodiment, the protruding member 86 protrudes upward from the floor surface of the passenger compartment 2. In addition, for example, the projecting member 86 may project sideways from the side panel or other members of the passenger compartment 2.

[Second Embodiment]
Next, the automobile 1 according to the second embodiment of the present invention will be described.
About the thing similar to 1st Embodiment, the same name as 1st Embodiment is used and description and illustration of 1st Embodiment are utilized. In the following, differences from the first embodiment will be mainly described.

FIG. 6 is an explanatory diagram of a positioning mechanism and an electrical connection mechanism for the sub-mobility 50 in the second embodiment.
In the automobile 1, a wheel recess 84 is formed on the floor surface of the vehicle body 3 as a positioning mechanism.

Then, the sub-mobility 50 moves from the position separated from the protruding member 86 on the floor surface of the passenger compartment 2 as shown in FIG. 6A toward the protruding member 86 as shown in FIG. 6B.
Then, as shown in FIG. 6C, the wheel 55 of the submobility 50 falls into the wheel recess 84 and is positioned.
At this time, the sub power receiving unit 61 is lowered toward the main power feeding unit 20, and the sub power receiving unit 61 and the main power feeding unit 20 are in contact with each other and are electrically connected.
As a result, the sub-mobility 50 is positioned and fixed on the floor surface of the vehicle body 3 at a position where the main power feeding unit 20 and the sub power receiving unit 61 are in electrical contact with each other.
In addition, the automobile 1 can supply power to the positioned sub-mobility 50.

  In the present embodiment, the main power feeding unit 20 is not covered with the main cover member 87. The sub power receiving unit 61 is not covered with the sub cover member 92. In addition, for example, the main power feeding unit 20 may be covered with the main cover member 87 and the sub power receiving unit 61 may be covered with the sub cover member 92.

[Third Embodiment]
Next, an automobile 1 according to a third embodiment of the present invention will be described.
About the thing similar to 2nd Embodiment, the same name as 2nd Embodiment is used and description and illustration of 2nd Embodiment are utilized. In the following, differences from the second embodiment will be mainly described.

FIG. 7 is an explanatory diagram of a positioning mechanism and an electrical connection mechanism of the sub-mobility 50 in the third embodiment.
In FIG. 7, the sub power receiving unit 61 and the main power feeding unit 20 are close to each other while being separated from each other.
In this case, by forming the sub power receiving unit 61 and the main power feeding unit 20 with coils or the like, they can be electrically coupled in a state of being separated from each other.

[Fourth Embodiment]
Next, an automobile 1 according to a fourth embodiment of the present invention will be described.
About the thing similar to 1st Embodiment, the same name as 1st Embodiment is used and description and illustration of 1st Embodiment are utilized. In the following, differences from the first embodiment will be mainly described.

FIG. 8 is an explanatory diagram of an electrical connection mechanism for the sub-mobility 50 in the fourth embodiment. In FIG. 8, the illustration of the positioning mechanism is omitted.
In FIG. 8, the main cover member 87 includes a covering portion 88 that covers the main non-conducting member on the upper side of the projecting member 86, and a pair of guide portions 89 provided on both sides of the covering portion 88. The pair of guide portions 89 protrude rearward from the covering portion 88 along the direction in which the sub-mobility 50 approaches the protruding member 86.

In this case, the sub-mobility 50 is self-propelled from the boarding position in FIG. 8A toward the protruding member 86 as shown in FIG. 8B. The sub cover member 92 slidably provided on the lower side of the projecting portion of the sub-mobility 50 fits between the pair of guide portions 89 of the main cover member 87 slidably provided on the upper side of the projecting member 86. .
Further, when the sub-mobility 50 is self-propelled, as shown in FIG. 8C, the sub-cover member 92 and the main cover member 87 that are pressed against each other are pressed and slid together, and the main power feeding portion 20 on the upper surface of the protruding member 86 is slid. And the sub power receiving unit 61 on the lower surface of the protrusion 91 are exposed and come into contact with each other. Thereby, the main power feeding unit 20 and the sub power receiving unit 61 are in contact with each other and are electrically connected.
The automobile 1 can supply power to the positioned sub-mobility 50.

As described above, in the present embodiment, the main cover member 87 includes the pair of guide portions 89 extending along the moving direction of the submobility 50 toward the predetermined positioning position.
Therefore, when the submobility 50 approaches from the direction, the submobility sub cover member 92 enters between the pair of guide portions 89 of the main cover member 87, and the main power feeding unit 20 and the sub power receiving unit 61 are electrically connected. The moving direction of the sub-mobility 50 can be finely adjusted so as to be able to come into contact. The submobility 50 can be stably positioned at the positioning position.
Moreover, since the sub-mobility 50 moves from a certain direction, the main cover member 87 and the sub-cover member 92 that are slid by being moved by the movement of the sub-mobility 50 can be pushed and slid in an appropriate direction.

[Fifth Embodiment]
Next, an automobile 1 according to a fifth embodiment of the present invention will be described.
About the thing similar to 1st Embodiment, the same name as 1st Embodiment is used and description and illustration of 1st Embodiment are utilized. In the following, differences from the first embodiment will be mainly described.

FIG. 9 is an explanatory diagram of a positioning mechanism and an electrical connection mechanism for the sub-mobility 50 in the fifth embodiment.
In FIG. 9, a platform 85 on which the submobility 50 is loaded is provided on the floor surface of the vehicle body 3.
The platform 85 is provided on the floor surface of the vehicle body 3 so as to be slidable from the boarding position of the sub-mobility 50 toward the protruding member 86 by an actuator (not shown).

In this case, the sub-mobility 50 gets on the platform 85 at the boarding position in FIG. The sub-mobility 50 may be fixed so as to be positioned on the platform 85 at the time of getting on.
Next, the platform 85 moves toward the protruding member 86 as shown in FIG. The sub-cover member 92 slidably provided on the lower side of the projecting portion of the sub-mobility 50 contacts the main cover member 87 slidably provided on the upper side of the projecting member 86.
When the platform 85 further moves, as shown in FIG. 9C, the sub cover member 92 and the main cover member 87 pressed against each other are slid together, and the main power feeding portion 20 and the protrusion on the upper surface of the protruding member 86 are slid. The sub power receiving unit 61 on the lower surface of the unit 91 is exposed and is in contact with each other.
Thereby, the main power feeding unit 20 and the sub power receiving unit 61 are in contact with each other and are electrically connected.
The automobile 1 can supply power to the sub-mobility 50 positioned on the platform 85.

  As described above, in the present embodiment, the platform 85 that is slidable toward the predetermined positioning position is provided on the floor surface of the vehicle body 3, and the sub-mobility 50 is on the platform 85 toward the positioning position. Moving. Therefore, the sub-mobility 50 loaded on the automobile 1 can be stably positioned at the positioning position without causing the sub-mobility 50 to self-propel in the vehicle. It is possible to suppress the occurrence of inconvenience due to the sub-mobility 50 traveling on its own in a vehicle in which various members are arranged.

  The above embodiment is an example of a preferred embodiment of the present invention, but the present invention is not limited to this, and various modifications or changes can be made without departing from the scope of the invention.

  DESCRIPTION OF SYMBOLS 1 ... Automobile (vehicle), 2 ... Passenger compartment, 3 ... Vehicle body, 4 ... Wheel, 11 ... Main power receiving connector, 12 ... Main power receiving coil, 13 ... Main charger, 14 ... Main battery, 15 ... Main converter, 16 ... Main power motor, 17 ... main braking motor, 18 ... main steering motor, 19 ... main equipment, 20 ... main power feeding unit, 31 ... main power monitoring unit, 32 ... main power control unit, 33 ... main GPS receiving unit, 34 ... main input part, 35 ... main communication part, 36 ... main display part, 37 ... main sensor part, 38 ... main route generation part, 39 ... main automatic driving part, 40 ... CPU (control part), 50 ... sub-mobility, DESCRIPTION OF SYMBOLS 51 ... Body, 52 ... Seat, 53 ... Armrest, 54 ... Operation lever, 55 ... Wheel, 61 ... Sub power receiving part, 62 ... Sub charger, 63 ... Sub battery, 64 ... Sub converter, 65 ... Sub power motor, 66 ... sub braking motor, 67 ... sub steering motor, 8 ... Sub-equipment equipment, 71 ... Sub-power monitoring unit, 72 ... Sub-power control unit, 73 ... Receiving unit, 74 ... Sub-input unit, 75 ... Sub-communication unit, 76 ... Sub-display unit, 77 ... Sub-sensor unit, 78 DESCRIPTION OF SYMBOLS ... Sub route production | generation part, 79 ... Sub automatic operation part, 81 ... Front side vehicle stop member, 82 ... Rear side vehicle stop member, 83 ... Car stop actuator, 84 ... Recess for wheel, 85 ... Platform, 86 ... Projection member, 87 DESCRIPTION OF SYMBOLS ... Main cover member, 88 ... Cover | cover part, 89 ... Guide part, 91 ... Protrusion part, 92 ... Sub cover member, 100 ... Travel lane, 101 ... Power transmission coil.

Claims (9)

A vehicle body that can be loaded with sub-mobility in a state where a person is on board,
A positioning mechanism provided on the vehicle body and positioning the sub-mobility at a predetermined position of the vehicle body;
A power feeding unit that is provided on the vehicle body and is in contact with or in proximity to a power receiving unit of the sub-mobility positioned at a predetermined position, and supplies power to the power receiving unit;
Have
The power feeding unit is
A vehicle that is brought into contact with or close to the power receiving unit when the sub-mobility is self-propelled. The power feeding portion is provided on a projecting member projecting from a floor surface or a side surface of the vehicle body,
The positioning mechanism positions the sub-mobility at a predetermined position of the vehicle body by pressing the sub-mobility moving on the floor surface of the vehicle body toward the protruding member.
The vehicle according to claim 1. On the floor surface of the vehicle body on which the sub-mobility moves, as the positioning mechanism, a positioning recess into which the wheel of the sub-mobility enters is formed.
The power feeding unit is positioned with the wheel of the submobility falling into the recess, and is in contact with or close to the power receiving unit of the submobility.
The vehicle according to claim 1. A main non-energizing member that covers the power feeding unit in contact with or close to the power receiving unit of the sub-mobility,
The main non-energizing member is movable when the sub-mobility moves to the predetermined position to expose the power feeding unit.
The vehicle according to any one of claims 1 to 3. The main de-energizing member is slid by being pushed by the sub-mobility moving to the predetermined position;
The vehicle according to claim 4. The sub-mobility has a sub-non-energizing member that covers the power receiving unit,
The sub-non-energizing member is movable when the sub-mobility moves to the predetermined position to expose the power receiving unit.
The vehicle according to any one of claims 1 to 5. The sub-non-energizing member is slidably moved by being pressed in contact with the vehicle body when the sub-mobility moves to the predetermined position.
The vehicle according to claim 6. The main de-energized member or the sub-non-energized member extends along the moving direction of the sub-mobility toward the predetermined position, and can function as a movement guide for the sub-mobility.
The vehicle according to any one of claims 4 to 7. The sub-mobility moves while riding on a platform that is slidable toward a predetermined positioning position on the floor of the vehicle body,
The vehicle according to any one of claims 1 to 8.