JP6937346B2 - Drone port system and how to operate it - Google Patents

Description

The present invention relates to a drone port system capable of taking off and landing a drone, storing a landed drone, safely storing a load carried by the drone inside, and taking it out at any time, and a method of operating the drone port system.

A "drone" is a type of small unmanned helicopter. In recent years, it has been planned to use drones to transport small luggage unmanned, inspect structures such as bridges, and spray pesticides. Such a drone is called an "industrial drone".

As industrial drones become widespread, there is a demand for drone ports that can be installed on the rooftops of buildings and where drones can take off and land. In order to satisfy such a demand, for example, Patent Documents 1 and 2 are disclosed.

The "drone takeoff and landing device" of Patent Document 1 includes a drone hangar provided at the upper end of the tower and a roof for opening and closing the drone hangar by an opening / closing machine.
This configuration allows the drone to be housed in the hangar, take off from the hangar at any time, and land in the hangar. In addition, since the hangar is equipped with a roof, it is possible to prevent the drone housed from being exposed to wind and rain.

The "drone port system" of Patent Document 2 includes a luggage receiving box and a security box. When the drone airlifts the luggage and lands on the landing board, leaving the luggage on the landing board and the drone takes off, the landing board slides along the slide guide, the upper part of the receiving box opens and the luggage is received. It is dropped inside.
This configuration enables efficient and long-term operation of the drone.

Japanese Unexamined Patent Publication No. 2019-55730 Japanese Unexamined Patent Publication No. 2019-89461

However, the means of Patent Document 1 has the following problems.
(1) Since there is a roof that rotates and opens outward at the upper part of the takeoff and landing surface (hangar floor) where the drone takes off and landing, a part of the roof that is fully opened when the drone lands is located outside the takeoff and landing surface.
Therefore, a part of the roof located above the takeoff and landing surface becomes an obstacle, and it becomes difficult to control the position of the landing drone.
In addition, the downwash (downflow of air) generated by the drone rebounds on the takeoff and landing surface and the fully open roof, and the downwash and the upflow are mixed on the upper part of the takeoff and landing surface, which makes attitude control difficult.
(2) It is required to install a plurality of logistics drones adjacent to a parking space such as the roof of a self-propelled parking lot.
However, the drone port of Patent Document 1 cannot be installed adjacently because the fully opened roof overhangs outside the installation space.

In addition, the means of Patent Document 2 has the following problems.
(3) The landed drone cannot be stored.
(4) Since the landing plate slides along the slide guide and the upper part of the receiving box opens, the landing plate that slides to the outside of the receiving box projects greatly, so that it cannot be installed adjacently.

The present invention has been devised to solve the above-mentioned problems. That is, an object of the present invention is a drone port system capable of installing a plurality of drones adjacent to each other without interfering with each other, storing a landed drone inside, and safely storing a load carried by the drone inside. To provide a driving method.

According to the present invention, it is a drone port system in which a drone takes off and landing, and the drone that has landed and the transported luggage are stored inside.
A hollow box with a hollow interior and an opening on the top surface through which the drone can pass.
A roof device that can open and close the opening inside the hollow
A storage device for storing the drone inside the hollow is provided .
The roof device is
A plurality of rectangular roof plates that are adjacent to each other and horizontally close the opening,
A roof opening / closing device that moves the plurality of roof plates between a fully closed position that horizontally closes the opening and a fully open position that vertically positions the plurality of roof plates along the inner wall of the hollow box to fully open the opening. Have and
The roof plate has a plurality of guide rollers provided on the outer sides of both ends in the depth direction of the opening and freely rotating around a horizontal axis in the depth direction.
The roof opening / closing device
A guide plate provided on the outer sides of both ends in the depth direction of the opening and guiding the guide roller between the fully closed position and the fully open position.
Provided is a drone port system provided outside the opening and having a roof drive device that drives the roof plate between the fully closed position and the fully open position.

Further, according to the present invention, it is the above-mentioned method of operating the drone port system.
(A) When the drone lands, when the drone approaches, the roof device is fully opened.
(B) Provided is a method of operating a drone port system that fully closes the roof device when the drone lands on the containment device.

According to the present invention, since the roof device is configured so that the opening provided on the upper surface of the hollow box can be opened and closed inside the hollow, there is no portion protruding to the outside of the hollow box, and the hollow boxes interfere with each other. Multiple installations can be made adjacent to each other.

In addition, since the storage device stores the drone inside the hollow, after the drone has landed on the storage device , the landed drone can be stored inside by fully closing the roof device , and the luggage carried by the drone can be stored inside. Can be safely stored.

It is a front view of the drone port system by this invention. It is explanatory drawing of the hollow box. It is a front view of the drone port system which shows the internal structure of a hollow box. It is the AA arrow viewing plane of FIG. It is a top view of the slide roof. It is a front view of a slide roof. It is a top view of the landing platform. It is a top view of the elevating support stand. It is the figure which integrated the landing stand and the elevating support stand. It is a top view of the landing unit which is the same as FIG. 9A. It is a plan view (A) of the elevating support stand similar to FIG. 8 and a view taken along the line BB. 11 is a cross-sectional view taken along the line CC of FIG. 11 (A) and a partial top view thereof (B). It is explanatory drawing of the driving method at the time of a drone landing.

Hereinafter, embodiments of the present invention will be described with reference to the drawings. In addition, the same reference numerals are given to common parts in each figure, and duplicate description is omitted.

FIG. 1 is a front view of the drone port system 100 according to the present invention.
In this figure, the drone port system 100 includes a hollow box 10, on which the drone 1 takes off and landing, and the drone 1 that has landed and the luggage 9 carried by the drone 1 are stored inside the hollow box 10.

(Hollow box 10)
2A and 2B are explanatory views of the hollow box 10, where FIG. 2A is a front view, FIG. 2B is a top view, and FIG. 2C is a right side view.
The hollow box 10 has a hollow interior 11 of a rectangular pillar, and has a rectangular opening 12 in the center of the upper surface through which the drone 1 can pass. Further, the hollow box 10 has an outer wall opening 14 on its side surface (front surface in this example) for communicating the hollow inner portion 11 with the outside.
With the above-described configuration, a plurality of hollow boxes 10 can be installed adjacent to each other without interfering with each other.

Hereinafter, of the hollow interior 11, the space inside the rectangular opening 12 in a plan view is referred to as an "inner interior space 11a", and the space outside is referred to as an "outer interior space 11b". The inner inner space 11a has a solid rectangular pillar shape, and the outer inner space 11b has a thick hollow rectangular pillar shape.

The external dimensions of the hollow box 10 are, for example, 2 m in width, 2 m in depth, and 2.3 m in height. The size of the rectangular opening 12 is, for example, a square having a width of 1.6 m and a depth of 1.6 m. Further, the size of the outer wall opening 14 is, for example, a width of 760 mm and a height of 570 mm.
Hereinafter, in this figure, the width direction is referred to as the X direction, the depth direction is referred to as the Y direction, and the height direction is referred to as the Z direction. Further, XX is the central axis in the X direction, YY is the central axis in the Y direction, M is the center in a plan view, and is the intersection of the central axis XX and the central axis YY.

FIG. 3 is a front view of the drone port system 100 showing the internal structure of the hollow box 10, and FIG. 4 is a view plane taken along the line AA of FIG. The main body frame is not shown for the sake of clarity in the drawings.

In FIGS. 3 and 4, the drone port system 100 of the present invention includes a roof device 20 (hereinafter, “slide roof 20 ”) and a storage device 30 (hereinafter, “ landing unit 30 ”) .
The slide roof 20 is configured so that the rectangular opening 12 can be opened and closed in the hollow interior 11 of the hollow box 10.
Further, the landing unit 30 stores the drone 1 in the hollow interior 11. In this example, the landing unit 30 is configured to be able to move up and down between the upper surface height H1 of the hollow box 10 and the drone storage height H2 below the hollow box 10 in the hollow interior 11.
The difference between the top surface height H1 and the drone storage height H2 is set to be larger than the height of the drone 1, and the drone 1 is stored between them.

(Slide roof 20)
FIG. 5 is a top view of the slide roof 20, and FIG. 6 is a front view of the slide roof 20.
In FIGS. 5 and 6, the slide roof 20 has a plurality of rectangular roof plates 22 and a roof opening / closing device 26.
A plurality of (four in this example) roof plates 22 horizontally close the rectangular openings 12 adjacent to each other in the X direction.
The roof plate 22 horizontally closes the rectangular opening 12 at the fully closed position C. Further, the roof plate 22 fully opens the rectangular opening 12 at the fully open position O. At the fully open position O, as shown by a thin line in FIG. 6, the plurality of roof plates 22 are vertically positioned along the inner wall of the hollow box 10.

In this figure, the four roof plates 22 are composed of a roof plate 22a located inside in the width direction (X direction) and a roof plate 22b located outside.
Each of the roof plates 22 has a plurality of guide rollers 23 provided on the outer sides of both ends of the rectangular opening 12 in the depth direction and freely rotating around the horizontal axis in the depth direction Y.
In this example, two roof plates 22a and 22b are arranged on the left and right sides of the central axis YY of the rectangular opening 12. Three guide rollers 23 are attached to both ends of each of the two roof plates 22a and 22b in the Y direction. Further, the guide roller 23 (23a) at the center of the three is attached to both of the two roof plates 22a and 22b, and the two are rotatably connected to each other about the horizontal axis.

The roof opening / closing device 26 moves the plurality of roof plates 22 between the fully closed position C and the fully open position O.
In FIGS. 5 and 6, the roof opening / closing device 26 has a guide plate 27 and a roof driving device 28.
The guide plate 27 is provided on the outer sides of both ends of the rectangular opening 12 in the depth direction, and guides the guide roller 23 between the fully closed position C and the fully open position O.

The roof driving device 28 is provided outside the rectangular opening 12 (that is, the outer internal space 11b), and drives the roof plate 22 between the fully closed position C and the fully open position O.
In this example, the roof drive 28 has a plurality of sprockets 28a, a plurality of endless chains 28b, and a connecting shaft 28c.
The plurality of sprockets 28a are located outside the rectangular opening 12 in the X direction and are configured to be rotatable about a horizontal axis in the Y direction.
The plurality of endless chains 28b are provided on both sides in the Y direction on the outside of the rectangular opening 12 (that is, the outer internal space 11b), and are guided by the sprocket 28a and extend horizontally in the X direction.
The connecting shaft 28c connects and synchronizes the sprockets 28a on both sides in the Y direction.

In this example, the roof drive 28 further includes a plurality of sprockets 29a, a plurality of endless chains 29b, and a chain drive 29c.
The plurality of sprockets 29a are vertically spaced apart from each other on the X-direction outer side of the rectangular opening 12, and a part of the sprockets 28a can be rotated.
The chain driving device 29c is located below the outer side of the rectangular opening 12 in the X direction, and drives the endless chain 28b via the sprocket 29a and the sprocket 28a.

With the above-described configuration of the roof drive device 28, the chain drive device 29c can horizontally move the endless chains 28b extending horizontally at intervals of the top and bottom in opposite directions.

In FIGS. 5 and 6, the two roof plates 22a closest to the central axis YY of the rectangular opening 12 have attachments 24 for connecting the guide rollers 23b closest to the center line in the X direction to the upper and lower endless chains 28b, respectively. Have.
With this configuration, the chain drive device 29c horizontally moves the upper and lower endless chains 28b in opposite directions, and horizontally moves the two roof plates 22a closest to the central axis YY in opposite directions via the attachment 24. Can be made to.

With the configuration of the slide roof 20 described above, the rectangular opening 12 can be opened and closed in the hollow interior 11, and the lower portion of the rectangular opening 12 corresponding to the rectangular opening 12 in a plan view can be maintained in the hollow.

Further, an elastic sealing material (not shown) is attached to the two roof plates 22a closest to the central axis YY on the side of the central axis YY, and rainwater is provided between them at the fully closed position C. Is prevented from flowing in.
Sealing materials that prevent the inflow of rainwater are also attached to other parts of the slide roof 20.
With this configuration, it is possible to prevent rainwater from flowing into the hollow box 10 at the fully closed position C of the slide roof 20.

In FIG. 3, the landing unit 30 includes a landing base 32, an elevating support base 34, an elevating guide 36, and an elevating drive unit 38.

(Landing platform 32)
FIG. 7 is a plan view of the landing platform 32. The landing platform 32 includes a frame 32a arranged horizontally in a grid pattern and a landing plate 32b horizontally attached to the upper surface thereof.
The landing platform 32 is located inside the rectangular opening 12 (that is, the inner internal space 11a) in a plan view, and has a landing surface 33 on which the drone 1 can take off and land. The landing surface 33 is the upper surface of the landing plate 32b.

Further, in this figure, the landing platform 32 has a luggage opening 32c. The luggage opening 32c is located at the center M of the landing surface 33, and has a size that allows the luggage 9 carried by the drone 1 to pass in the vertical direction. The size of the luggage opening 32c is, for example, a width of 400 mm and a depth of 400 mm.
The luggage opening 32c is provided with a luggage door 51 that can be opened and closed. The upper surface of the luggage door 51 is set at the same height as the landing surface 33 when fully closed.
The opening / closing structure of the luggage door 51 will be described later.

(Elevating support base 34)
FIG. 8 is a plan view of the elevating support base 34.
The elevating support base 34 is fixed below the landing base 32 at regular intervals, and the four corners are located outside the rectangular opening 12 (that is, the outer internal space 11b).
The upper ends of the guide bar 36a, which will be described later, are fixed to the ears 34a at the four corners of the elevating support base 34 on the outside of the rectangular opening 12 (outer internal space 11b).
Further, the elevating support base 34 does not have a frame at a position corresponding to the luggage opening 32c in a plan view, and the cargo 9 falling from the luggage opening 32c passes downward as it is.

(Elevating guide 36)
In FIG. 3, the elevating guide 36 has a vertical guide bar 36a whose upper ends are fixed to the four corners of the elevating support base 34 and extends vertically downward on the outside of the rectangular opening 12, and a vertical guide bar 36a fixed to a main body frame (not shown) to which the guide bar 36a fits. It has a guide plate 36b having a through hole.
With the configuration of the elevating guide 36, the landing surface 33 can be held horizontally and the landing surface 33 can be guided up and down between the upper surface height H1 and the drone storage height H2.

(Elevating drive unit 38)
In FIG. 3, the elevating drive unit 38 is, for example, an electric lifter in which a ball screw is rotationally driven by an electric motor and a speed reducer to elevate and lower the mounting plate 38a along a linear guide. As a result, the elevating drive unit 38 raises and lowers the elevating support base 34 while maintaining the horizontal position via the connecting metal fitting 38b fixed to the mounting plate 38a.

(Landing platform 32 and elevating support platform 34)
9A and 9B are views in which the landing platform 32 and the elevating support platform 34 are integrated, FIG. 9A is a plan view, FIG. 9B is a front view, and FIG. 9C is a right side view.

In this figure, the landing platform 32 and the elevating support platform 34 are fixed at regular intervals by connecting fittings 35 provided at both ends in the X direction. Further, in this example, the six connecting metal fittings 35 are located only at both ends of the landing base 32 and the elevating support base 34 in the X direction, and an interfering object is provided between the left and right connecting metal fittings 35 in the X direction and the Y direction. A hollow space is formed.

In FIG. 9, the ears 34a at the four corners of the elevating support base 34 to which the upper end of the guide bar 36a is fixed are located outside the rectangular opening 12 (outer internal space 11b) in a plan view.
Further, both ends of the landing base 32 and the elevating support base 34 in the Y direction are located inward from the inner edge of the rectangular opening 12 with a gap (indicated by diagonal lines in the figure).

(Centering device 40)
In FIGS. 3 and 4, the landing unit 30 further includes a centering device 40 that horizontally moves the drone 1 mounted on the landing surface 33 to the center M of the landing surface 33.

FIG. 10 is a plan view of the landing unit 30 similar to FIG. 9A.
In this figure, the centering device 40 has a horizontal movement unit 42 that can move horizontally along the upper surface of the landing surface 33. The horizontal movement unit 42 has a function of horizontally moving the drone 1 to the center M of the landing surface 33.

In this example, the horizontal moving unit 42 has a pair of X-direction moving plates 42a, a pair of Y-direction moving plates 42b, and four connecting plates 42c.
The pair of X-direction moving plates 42a extend horizontally in the depth direction (Y direction) of the rectangular opening 12, and both ends are located outside the landing surface 33.
The pair of Y-direction moving plates 42b extend horizontally in the width direction (X direction) of the rectangular opening 12, and both ends are located outside the luggage opening 32c.
The four connecting plates 42c diagonally connect both ends of the X-direction moving plate 42a and both ends of the Y-direction moving plate 42b in a plan view.
Further, the X-direction moving plate 42a, the Y-direction moving plate 42b, and the connecting plate 42c are connected by a hinge 42d so as to surround the luggage opening 32c so as to be freely rotatable around the vertical axis.

Further, in this figure, both ends of the pair of X-direction moving plates 42a are fixed to four horizontal moving metal fittings 43 that can move in the X-direction. Further, the four horizontal moving metal fittings 43 are located in the gaps (hatched portion in FIG. 9A) between the landing base 32 and the elevating support base 34 and both ends of the rectangular opening 12 in the Y direction.

With the above configuration, by moving the four horizontal moving brackets 43 inward in the X direction in synchronization with each other, the pair of moving plates 42a in the X direction are parallel to each other from the standby position (solid line) to the center position (broken line). Can be moved inward in the X direction while maintaining.
Further, in conjunction with this, the pair of Y-direction moving plates 42b connected by the connecting plate 42c and the hinge 42d can be moved inward in the Y-direction while maintaining parallelism with each other.

FIG. 11 is a plan view (A) of the elevating support base 34 similar to that of FIG. 8 and a view taken along the line BB.
In this figure, the centering device 40 further includes a centering drive device 44 that drives the horizontal movement unit 42.

In this example, the centering drive 44 has a pair of drive plates 46 and a horizontal drive 48.
The pair of drive plates 46 are located between the landing base 32 and the elevating support base 34, and are freely rotatably connected to both ends of the pair of X-direction moving plates 42a via the horizontal moving metal fittings 43. Has been done.
Further, the horizontal drive device 48 is provided on the elevating support base 34 and drives the pair of drive plates 46 horizontally in the opening / closing direction (X direction) in synchronization with each other. In this example, the horizontal drive device 48 includes a pair of linear guides 48a and a pair of ball screw drive devices 48b.
A ball nut that meshes with the ball screw of the ball screw driving device 48b is fixed to the drive plate 46, and the ball nut is horizontally driven in the X direction via the ball screw.

According to the configuration of the centering device 40 described above, the horizontal drive device 48 synchronizes the pair of drive plates 46 to drive horizontally in the width direction (X direction), thereby synchronizing the four horizontal moving metal fittings 43 with each other in the X direction. You can move to.
Therefore, the pair of X-direction moving plates 42a can be kept parallel and moved inward in the X direction, and at the same time, the pair of Y-direction moving plates 42b can be kept parallel and moved inward in the Y direction. .. As a result, the X-direction moving plate 42a and the Y-direction moving plate 42b can be moved from the standby position to the center position that surrounds the luggage opening 32c in close proximity, and the drone 1 mounted on the landing surface 33 can be horizontally moved to the center M of the landing surface 33. Can be made to.
The drone 1 preferably moves freely along the upper surface of the landing platform 32.

(Opening and closing door device 50)
FIG. 12 is a cross-sectional view taken along the line CC of FIG. 11 (A) and a partial top view (B) thereof.
In this figure, the landing unit 30 has an opening / closing door device 50 capable of opening / closing the luggage opening 32c.
The opening / closing door device 50 has a pair of luggage doors 51 and a door driving device 54.
The pair of luggage doors 51 are adjacent to each other and are horizontally positioned, and the luggage opening 32c is fully closed. The outer ends of the pair of luggage doors 51 in the X direction are rotatably supported around a rotation shaft 51a in the Y direction.
The door drive device 54 swings (turns) a pair of luggage doors 51 downward in synchronization with the rotation shaft 51a. In this example, the door drive device 54 includes a pair of swing drive devices 55.

With the configuration of the opening / closing door device 50 described above, the luggage 9 placed on the luggage door 51 with the luggage opening 32c fully closed can be dropped downward by fully opening the luggage opening 32c. ..

(Transport device 60)
In FIGS. 3 and 4, the drone port system 100 is located below the cargo opening 32c and includes a transport device 60 that horizontally transports the cargo 9.
The transport device 60 includes a conveyor device 62 that transports the cargo 9 in the Y direction, and a storage device 64 that transports and stores the cargo 9 in the X direction.

In FIG. 3, the drone port system 100 includes an elevating drive unit 68 that elevates and elevates the conveyor device 62. The elevating drive unit 68 is, for example, an electric lifter that rotationally drives a ball screw with an electric motor and a speed reducer to elevate and elevate the mounting plate 68a along a linear guide, and is a conveyor via a connecting metal fitting 63 fixed to the mounting plate 68a. The device 62 is moved up and down.
With this configuration, by raising the conveyor device 62 to near directly below the cargo opening 32c, it is possible to prevent damage to the cargo 9 falling from the cargo opening 32c. Further, the conveyor device 62 can be positioned at a height that matches the storage device 64 and a height that matches the outer wall opening 14.

Further, the conveyor device 62 can be expanded and contracted forward in the Y direction, and the load 9 is conveyed to the outside of the hollow box 10 through the outer wall opening 14.

In FIG. 4, the storage device 64 stores the cargo 9 inside the outer wall opening 14 on the opposite side via the conveyor device 62.
The storage device 64 is, for example, a right-angle direction changer (not shown) that changes the direction of the luggage 9 between the Y direction and the X direction, and a conveyor device (not shown) that is continuously installed therein and conveys the luggage 9 in the X direction. It consists of (Zezu).
With this configuration, a plurality of luggage 9s can be stored in the storage device 64.

(Outer wall opening / closing device 70)
In FIG. 4, the drone port system 100 includes an outer wall opening / closing device 70 that opens / closes the outer wall opening 14.
The outer wall opening / closing device 70 includes an outer wall door 72 that completely closes the outer wall opening 14 from the inside, and an opening / closing drive device 74 that opens and closes the outer wall door 72 from the inside.
The opening / closing drive device 74 includes a slide guide 75 that retracts the outer wall door 72 from the front surface and slides it upward, and a vertical drive device 76 that moves the outer wall door 72 up and down.
With this configuration, the outer wall door 72 can be opened and closed from the inside to open and close the outer wall opening 14.

The operation method of the present invention using the drone port system 100 described above will be described below.

(Standby state)
In the standby state, the rectangular opening 12 on the upper surface of the hollow box 10 shown in FIG. 2 is fully closed by the roof plate 22, and the outer wall opening 14 on the front surface is fully closed by the outer wall door 72.
Therefore, in the standby state, the luggage 9 stored inside the hollow box 10 cannot be accessed from the outside by a third party, and the luggage 9 can be safely stored.

(At the time of drone landing)
FIG. 13 is an explanatory diagram of a driving method at the time of landing of the drone. In this figure, (A) indicates a standby state, and (B) indicates a landing state.
In the state of FIG. 13A, when the drone 1 lands, the slide roof 20 is fully opened when the drone 1 approaches.
Next, after the slide roof 20 is fully opened, the upper surface (landing surface 33) of the landing unit 30 is raised to the upper surface height H1 of the hollow box 10 as shown in FIG. 13 (B).
Therefore, at the time of drone landing, only the landing surface 33 is exposed inside the rectangular opening 12, and the height of the landing surface 33 is located at the upper surface height H1 of the hollow box 10. Therefore, when the drone 1 lands, there are no obstacles in the vicinity, and position control and attitude control can be easily performed.

Further, after landing the drone, before lowering the landing unit 30, the drone 1 placed on the upper surface (landing surface 33) of the landing unit 30 is horizontally moved to the center of the upper surface of the landing surface 33 by the centering device 40.
Further, after the landing of the drone 1 and before the slide roof 20 is fully closed, the upper surface (landing surface 33) of the landing unit 30 is lowered to the drone storage height H2, and then the slide roof 20 is fully closed for landing. The drone 1 can be safely stored inside.

Further, the luggage 9 carried by the drone 1 is safely stored inside by opening the luggage door 51 by the opening / closing door device 50, dropping the luggage 9 onto the conveyor device 62, and then transporting the luggage 9 to the storage device 64 for storage. can.
Further, the administrator (or user) of the drone port system 100 can operate the transport device 60 and the outer wall opening / closing device 70 with, for example, a remote control switch to take out the luggage 9 stored inside at any time.

According to the above-described embodiment of the present invention, the slide roof 20 is configured so that the rectangular opening 12 provided in the center of the upper surface of the hollow box 10 can be opened and closed inside the hollow interior 11. Therefore, there is no portion protruding to the outside of the hollow box 10, and a plurality of hollow boxes 10 can be installed adjacent to each other without interfering with each other.

Further, the landing unit 30 is configured so as to be able to move up and down between the upper surface height H1 of the hollow box 10 and the drone storage height H2 below the upper surface height H1 in the hollow interior 11 of the hollow box 10.
With this configuration, the slide roof 20 is fully opened, and then the landing unit 30 is raised to the height H1 on the upper surface of the hollow box 10, so that there are no obstacles in the vicinity when the drone 1 lands, and the position can be easily controlled. Attitude control is possible.

It should be noted that the present invention is not limited to the above-described embodiment, and it goes without saying that various modifications can be made without departing from the gist of the present invention.

C fully closed position, H1 top surface height, H2 drone storage height, M center,
O fully open position, X width direction, Y depth direction, Z height direction,
1 drone, 9 luggage, 10 hollow box, 11 hollow inside,
11a inner interior space, 11b outer interior space, 12 rectangular openings, 14 outer wall openings,
20 slide roof, 22, 22a, 22b roof plate,
23, 23a, 23b guide rollers, 24 attachments,
26 roof switchgear, 27 guide plate, 28 roof drive device,
28a sprocket, 28b endless chain, 28c connecting shaft,
29a sprocket, 29b endless chain, 29c chain drive,
30 landing unit, 32 landing platform, 32a frame, 32b landing board,
32c luggage opening, 33 landing surface, 34 lift support, 34a ears,
35 connecting bracket, 36 lifting guide, 36a guide bar, 36b guide plate,
38 Lifting drive unit, 38a mounting board, 38b connecting bracket,
40 Centering device, 42 Horizontal movement unit, 42a X direction movement plate,
42b Y-direction moving plate, 42c connecting plate, 42d hinge, 43 horizontal moving bracket,
44 centering drive, 46 drive plate, 48 horizontal drive,
48a straight guide, 48b ball screw drive, 50 open / close door device,
51 Luggage door, 51a rotating shaft, 54 door drive device, 55 rocking drive device,
60 Conveyor device, 62 Conveyor device, 63 Connecting bracket, 64 Storage device,
68 Lifting drive unit, 68a mounting board, 70 outer wall switchgear, 72 outer wall door,
74 Open / close drive, 100 drone port system

Claims (13)

It is a drone port system that stores the drone that the drone took off and landed and the carried luggage inside.
A hollow box with a hollow interior and an opening on the top surface through which the drone can pass.
A roof device that can open and close the opening inside the hollow
A storage device for storing the drone inside the hollow is provided .
The roof device is
A plurality of rectangular roof plates that are adjacent to each other and horizontally close the opening,
A roof opening / closing device that moves the plurality of roof plates between a fully closed position that horizontally closes the opening and a fully open position that vertically positions the plurality of roof plates along the inner wall of the hollow box to fully open the opening. Have and
The roof plate has a plurality of guide rollers provided on the outer sides of both ends in the depth direction of the opening and freely rotating around a horizontal axis in the depth direction.
The roof opening / closing device
A guide plate provided on the outer sides of both ends in the depth direction of the opening and guiding the guide roller between the fully closed position and the fully open position.
A drone port system provided outside the opening and comprising a roof drive device that drives the roof plate between the fully closed position and the fully open position. The drone port system according to claim 1, wherein the storage device can move up and down between the height of the upper surface of the hollow box and the height of the drone storage below the hollow box. The storage device is
A landing platform located inside the opening in plan view and having a landing surface on which the drone can take off and land.
An elevating support that is fixed below the landing platform at intervals and whose four corners are located outside the opening.
An elevating guide that holds the landing surface horizontally and guides the elevating support base so that it can be elevated.
The drone port system according to claim 1, further comprising an elevating drive unit for elevating and elevating the elevating support base. It is a drone port system that stores the drone that the drone took off and landed and the carried luggage inside.
A hollow box with a hollow interior and an opening on the top surface through which the drone can pass.
A roof device that can open and close the opening inside the hollow
A storage device for storing the drone inside the hollow is provided.
The storage device has a centering device that horizontally moves the drone located inside the opening in a plan view and rests on a landing surface on which the drone can take off and land to the center of the landing surface.
The centering device has a horizontal moving unit that is horizontally movable along the upper surface of the landing surface and moves the drone horizontally to the center of the landing surface.
The horizontal movement unit is
A pair of X-direction moving plates extending horizontally in the depth direction of the opening and having both ends located outside the landing surface.
A pair of Y-direction moving plates extending horizontally in the width direction of the opening and having both ends located outside the luggage opening.
It has four connecting plates that diagonally connect both ends of the X-direction moving plate and both ends of the Y-direction moving plate in a plan view.
A drone port system in which the X-direction moving plate, the Y-direction moving plate, and the connecting plate are hinged so as to surround the luggage opening so as to be freely rotatable around a vertical axis. The centering device is
Has a centering drive device for driving the horizontal moving unit, drones port system according to claim 4. The centering drive device is
A landing pad with the landing surface, four corners are fixed at an interval below the該着land base is located between the lifting support base located outside of the opening, a pair the two ends of the X direction moving plate A pair of drive plates that are freely rotatable around the vertical axis and
The drone port system according to claim 5 , further comprising a horizontal drive device provided on the elevating support base and synchronously driving a pair of the drive plates horizontally in the width direction. The landing platform is located at the center of the landing surface and has a luggage opening for passing the cargo carried by the drone in the vertical direction.
The drone port system according to claim 3 , wherein the storage device includes an opening / closing door device capable of opening and closing the luggage opening. The drone port system according to claim 6 , further comprising a transport device for horizontally transporting the luggage, which is located below the luggage opening. The hollow box has an outer wall opening on its side surface that communicates the inside of the hollow with the outside.
The drone port system according to claim 8 , wherein the transport device includes a conveyor device that transports the load to the outside of the hollow box through the outer wall opening. The drone port system according to claim 9 , wherein the transport device includes a storage device that stores the luggage inside the opposite side of the outer wall opening via the conveyor device. The method of operating the drone port system according to claim 1.
(A) When the drone lands, when the drone approaches, the roof device is fully opened.
(B) A method of operating a drone port system in which the roof device is fully closed when the drone lands on the storage device. After the roof device is fully opened, the upper surface of the storage device is raised to the height of the upper surface of the hollow box.
The method for operating a drone port system according to claim 11 , wherein the upper surface of the storage device is lowered to the drone storage height after the drone has landed and before the roof device is fully closed. The method for operating a drone port system according to claim 12 , wherein the drone mounted on the upper surface of the storage device is horizontally moved to the center of the upper surface of the storage device after the drone has landed and before the storage device is lowered.

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