JP2023078873A - Container transfer device and container transfer method - Google Patents

Abstract

To enable a spreader unit to perform following movement in the horizontal direction and the vertical direction and to suppress the swing of the spreader unit in the horizontal direction when a container is transferred.SOLUTION: A container transfer device includes a spreader unit support part 12 inserted between a spreader unit 11 and an elevation unit 5. The spreader unit support part 12 regulates the movement of the spreader unit 11 in the horizontal direction with respect to a rotation unit 7 while a container C supported by the spreader unit 11 is horizontally moved without being contacted with a placement portion or while the spreader unit 11 is horizontally moved without being contacted with the container C. The spreader unit support part allows the movement of the spreader unit 11 at least in the horizontal direction with respect to the rotation unit 7 while the container C supported by the spreader unit 11 is contacted with the placement portion or while the spreader unit 11 not supporting the container C is contacted with the container C.SELECTED DRAWING: Figure 2

Description

The present invention relates to a container transfer device and a container transfer method.

Containers loaded and transported on container trucks may be temporarily stored, for example, in automated warehouses. Such containers are transferred from automated warehouses to container trucks or from container trucks to automated warehouses. For example, Patent Literature 1 discloses a container transfer system for loading and unloading container-shaped cargo on and off cargo trucks. As disclosed in Patent Document 1, a container transfer system includes a container spreader that can be expanded and contracted according to the length of the container. By extending and contracting the container spreader according to the length of the container and fixing the container spreader to metal fittings provided on the top of the container using a lock mechanism, the container can be suspended and supported.

JP-A-8-337390

By the way, in Patent Literature 1, a container spreader is suspended by a plurality of ropes so as to be vertically movable. By suspending and supporting the container spreader using these cords, the container spreader can move horizontally and vertically with respect to the support. Therefore, when the container spreader is brought into contact with the container from above, the horizontal and vertical positions of the container spreader can follow the shape of the container by means of the guide provided on the container or the like. Similarly, when a container held by a container spreader is placed on a container placement location, the horizontal and vertical positions of the container spreader (i.e., the horizontal and vertical positions of the container) are It is possible to follow the shape of the part.

However, when a spreader unit such as a container spreader disclosed in Patent Document 1 is suspended and supported by a plurality of cords, the spreader unit can be moved horizontally and vertically with respect to the support, but on the other hand, it is difficult to suspend the spreader unit. It becomes difficult to suppress horizontal rocking of the lowered spreader unit. If the spreader unit oscillates, it becomes difficult to ensure positioning accuracy, and the transfer cycle time is lengthened.

SUMMARY OF THE INVENTION The present invention has been devised in view of the above-described problems. The purpose is to make it possible to suppress movement.

The present invention employs the following configurations as means for solving the above problems.

A first aspect of the present invention is a container transfer apparatus for transferring a container, comprising: a spreader unit for supporting the container; and a spreader unit supporting portion interposed between the spreader unit and the elevating unit, wherein the spreader unit supporting portion makes contact with the placement location of the container supported by the spreader unit. In a state in which the spreader unit moves horizontally without contacting the container, or in a state in which the spreader unit moves horizontally without contacting the container, the horizontal movement of the spreader unit with respect to the lifting device is restricted, and the spreader unit supports the container. at least in a horizontal direction with respect to the lifting device of the spreader unit in a state in which the container which is supporting the container is in contact with the placing position or in a state in which the spreader unit which does not support the container is in contact with the container. Adopt a configuration that allows movement to.

According to a second aspect of the present invention, in the first aspect, the spreader unit supporting portion suspends and supports the spreader unit so as to be horizontally swingable with respect to the lifting device; A configuration is adopted in which the spreader unit is provided with a rocking fixing device capable of restricting or permitting at least horizontal movement of the spreader unit with respect to the lifting device.

According to a third aspect of the present invention, in the above-described second aspect, an opposing frame is arranged to face the spreader unit from above and to which the upper ends of the cord-like members are connected, and the rocking fixing device comprises the above-described It is fixed to the opposing frame and contacts the spreader unit to restrict horizontal movement of the spreader unit with respect to the lifting device, and separates from the spreader unit to at least move the spreader unit to the lifting device. A configuration that allows movement in the horizontal direction is adopted.

A fourth aspect of the present invention employs a configuration in which a plurality of the rocking fixing devices are provided in the second or third aspect.

A fifth aspect of the present invention is the spreader unit according to the first aspect, wherein the spreader unit support includes a plurality of inclined cord-like members connected to the spreader unit while being inclined with respect to a vertical axis. When the container supported by is not in contact with the placement location or when the spreader unit not supporting the container is not in contact with the container, the tension acting on the inclined cord-like member is is used to restrict the horizontal movement of the spreader unit with respect to the lifting device.

A sixth aspect of the present invention employs a configuration according to the fifth aspect, wherein the spreader unit support includes a plurality of inclined cord-like members inclined in different directions with respect to the vertical axis.

According to a seventh aspect of the present invention, in the fifth or sixth aspect, the spreader unit supporting portion includes a plurality of inclined cord-like members inclined in the same direction with respect to the vertical axis. do.

An eighth aspect of the present invention is a container transfer method for transferring a container, wherein the container supported by the spreader unit moves horizontally without coming into contact with the placement location or in the above-described state. The horizontal movement of the spreader unit is restricted in a state in which the spreader unit moves horizontally without contacting the container, and the container supported by the spreader unit contacts the placement location. A configuration is adopted in which the spreader unit is allowed to move at least in the horizontal direction when the spreader unit is in contact with the container, or when the spreader unit does not support the container and is in contact with the container.

According to the present invention, the horizontal movement of the spreader unit is restricted while the container supported by the spreader unit is not in contact with the placement location, and the container is in contact with the placement location. allows at least horizontal movement of the spreader unit. Therefore, according to the present invention, if the container supported by the spreader unit is not in contact with the mounting position, it is possible to suppress the swinging of the spreader unit even if the spreader unit is horizontally moved by a large amount. can. On the other hand, if the container is in contact with the placement location, the spreader unit will not swing. According to the present invention, since the spreader unit can move at least in the horizontal direction while the container is in contact with the placement position, the spreader unit can move along the container. Therefore, according to the present invention, when the container is transferred, it is possible to allow the spreader unit to follow at least the horizontal direction and to suppress the horizontal swinging of the spreader unit.

BRIEF DESCRIPTION OF THE DRAWINGS It is a schematic diagram which shows schematic structure of container storage provided with the container transfer apparatus in 1st Embodiment of this invention, (a) is a top view, (b) is a side view. 1 is a perspective view schematically showing a mechanical structure of a container transfer device according to a first embodiment of the present invention; FIG. 3 is a block diagram showing electrical connections of the container transfer device according to the first embodiment of the present invention; FIG. FIG. 4A is a schematic enlarged view including a turning unit and a spreader unit provided in the container transfer device according to the first embodiment of the present invention, where (a) is a plan view and (b) is a side view; FIG. 2 is a schematic diagram of a rocking fixing device included in the container transfer device according to the first embodiment of the present invention; 4 is a flowchart for explaining guidance processing of the container transfer device according to the first embodiment of the present invention; 4 is a flowchart for explaining cargo placement processing of the container transfer device according to the first embodiment of the present invention; 4 is a flow chart for explaining cargo pick-up processing of the container transfer device according to the first embodiment of the present invention; FIG. 9A is a schematic enlarged view including a turning unit and a spreader unit provided in a container transfer device according to a second embodiment of the present invention, where (a) is a plan view and (b) is a side view. FIG. 9 is a flowchart for explaining cargo placement processing of the container transfer device according to the second embodiment of the present invention; FIG. FIG. 10 is a flow chart for explaining pick-up processing of the container transfer device according to the second embodiment of the present invention; FIG.

An embodiment of a container transfer device and a container transfer method according to the present invention will be described below with reference to the drawings.

(First embodiment)
FIG. 1 is a schematic diagram showing a schematic configuration of a container hangar 100, where (a) is a plan view and (b) is a side view. The container hangar 100 is a hangar for temporarily storing containers C. As shown in FIG. The container C stored in the container hangar 100 is, for example, a marine container or a railroad container. As shown in FIG. 1, the container hangar 100 includes an automated warehouse 200, a loading/unloading device 300, and a container transfer device 400 of the present embodiment.

The automated warehouse 200 includes multiple racks 201 and multiple stacker cranes 202 . The rack 201 has a plurality of container storage units arranged horizontally and vertically. The rack 201 can store the container C in each container storage section. These racks 201 are arranged so as to sandwich the travel track of the stacker crane 202 .

The stacker crane 202 is a crane that moves the container C within the automated warehouse 200 . The stacker crane 202 moves the container C between the container storage section of the rack 201 and the loading/unloading device 300 . Also, the stacker crane 202 moves the container C between the container storage units of the rack 201 .

The loading/unloading device 300 is arranged between the automated warehouse 200 and the container transfer device 400 , and is a device for loading/unloading the container C into/from the automated warehouse 200 . A loading/unloading device 300 is provided for each rack 201 . Each loading/unloading device 300 is arranged at the entrance/exit of the rack 201 and has a carriage 301 for loading/unloading the container C. As shown in FIG. Such a carriage 301 is provided movably between the inside of the rack 201 and the inside of the container transfer device 400 .

The container transfer device 400 of this embodiment is a device that transfers containers C between the loading/unloading device 300 and the container transport truck T. As shown in FIG. Further, the container transfer device 400 includes a building 401 having a truck stop area R1 and a truck arrangement area R2.

The container transfer device 400 transfers the container C to the container transport truck T in the truck stop area R1. That is, the container transfer device 400 can transfer the container C to the container transport truck T stopped in the truck stop area R1. Further, the container transfer device 400 can receive a container C from a container transport truck T stopped in the truck stop area R1.

Further, the container transfer device 400 transfers the container C to the carriage 301 of the loading/unloading device 300 in the carriage arrangement area R2. That is, the container transfer device 400 can transfer the container C to the truck 301 arranged in the truck arrangement area R2. Further, the container transfer device 400 can receive the container C from the truck 301 arranged in the truck arrangement area R2.

That is, the container transfer device 400 of the present embodiment transfers the container C from the container transport truck T to the loading/unloading device 300 and transfers the container C from the loading/unloading device 300 to the container transport truck T.

For example, the automated warehouse 200, the loading/unloading device 300, and the container transfer device 400 are each controlled by an integrated control unit that controls them in an integrated manner. That is, for example, the container hangar 100 includes an integrated control unit that controls the automated warehouse 200, the loading/unloading device 300, and the container transfer device 400 in an integrated manner.

The container transfer device 400 of this embodiment will be described in more detail. FIG. 2 is a perspective view schematically showing the mechanical structure of the container transfer device 400. As shown in FIG. 3 is a block diagram showing electrical connections of the container transfer device 400. As shown in FIG.

For example, as shown in FIG. 2, the container transfer device 400 includes a rail 1, a traveling unit 2, a traveling unit 3, a girder frame 4, an elevating unit 5, a traversing unit 6, a turning unit 7, It comprises a suspension chain 8 (a cord-like member), a rocking fixing device 9 , a rocking fixing device 10 and a spreader unit 11 .

The rail 1 is laid on the ceiling of the building 401 and guides the movement of the mechanical structure of the container transfer device 400 . Two rails 1 are provided parallel to each other. Each rail 1 extends horizontally and linearly so as to connect the truck stop area R1 and the truck arrangement area R2 when viewed from above.

In addition, in the following description, the direction in which the rail 1 extends is referred to as the Y-axis direction for convenience of description. A horizontal direction orthogonal to the Y-axis direction is called an X-axis direction. A direction perpendicular to the X-axis and the Y-axis (that is, the vertical direction) is referred to as the Z-axis direction. That is, the Y-axis is an axis extending parallel to the rail 1 . Also, the X-axis is a horizontal axis perpendicular to the rail 1 . Also, the Z-axis is the vertical axis.

The traveling unit 2 and the traveling unit 3 are units that travel on the rail 1 . A traveling unit 2 travels on one rail 1 . Also, the traveling unit 3 travels on the other rail 1 . These traveling unit 2 and traveling unit 3 travel synchronously in the Y-axis direction.

The traveling unit 2 includes a traveling frame 2a that supports the girder frame 4, as shown in FIG. The traveling frame 2a can move on one rail 1 with low friction by means of wheels (not shown) or the like. The traveling frame 2a supports one end of the girder frame 4 from below.

In addition, as shown in FIG. 3, the travel unit 2 includes a travel drive section 2b (not shown in FIG. 2). The traveling drive section 2b is supported by the traveling frame 2a, generates power for the traveling unit 2 to travel on the rail 1, and transmits the generated power to the traveling frame 2a. Such a travel drive unit 2b includes, for example, a servomotor and a transmission mechanism that transmits power generated by the servomotor.

The traveling unit 3 also includes a traveling frame 3a that supports the girder frame 4, as shown in FIG. The traveling frame 3a can move on the other rail 1 with low friction by means of wheels (not shown) or the like. The traveling frame 3a supports the other end of the girder frame 4 from below.

Further, the traveling unit 3, as shown in FIG. 3, includes a traveling drive section 3b (not shown in FIG. 2). The traveling drive section 3b is supported by the traveling frame 3a, generates power for the traveling unit 3 to travel on the rail 1, and transmits the generated power to the traveling frame 3a. Such a travel drive unit 3b includes, for example, a servomotor and a transmission mechanism that transmits power generated by the servomotor.

The girder frame 4 is a strength member that directly or indirectly supports the lifting unit 5, the traversing unit 6, the turning unit 7, the spreader unit 11, and the like. The girder frame 4 extends in the X direction, and has one end connected to the traveling unit 2 and the other end connected to the traveling unit 3 . Therefore, the girder frame 4 is moved in the Y-axis direction together with the traveling unit 2 and the traveling unit 3 as the traveling unit 2 and the traveling unit 3 travel on the rail 1 .

The lifting unit 5 includes a lifting frame 5a, as shown in FIG. The elevating frame 5a is a frame member supported so as to be able to ascend and descend with respect to the girder frame 4. As shown in FIG. This elevating frame 5a is attached so as to be able to ascend and descend along the Z-axis direction while its movement in the X-axis direction and the Y-axis direction is restricted. For example, guides are provided for the girder frame 4 to restrict movement of the lift frame 5a in the X-axis direction and the Y-axis direction, and the lift frame 5a is prevented from moving in the X-axis direction and the Y-axis direction by the guides. Regulated. That is, the lifting unit 5 moves up and down while the lifting frame 5a is restricted from moving in the horizontal direction.

In addition, as shown in FIG. 3, the lift unit 5 includes a lift drive section 5b. The elevating drive unit 5b is supported by the girder frame 4, generates power for elevating the elevating frame 5a, and transmits the generated power to the elevating frame 5a. Such an up-and-down drive unit 5b includes, for example, a servomotor and a transmission mechanism that transmits power generated by the servomotor.

Such a lifting unit 5 is moved together with the girder frame 4 . That is, when the traveling unit 2 and the traveling unit 3 travel on the rail 1, they are moved together with the girder frame 4 in the Y-axis direction.

The traversing unit 6, as shown in FIG. 2, includes a traversing frame 6a. The transverse frame 6a is a frame member supported movably in the X-axis direction with respect to the elevating frame 5a. The transverse frame 6a is mounted so as to be movable along the X-axis direction while its movement in the Y-axis direction and the Z-axis direction is restricted. For example, a guide for restricting movement of the traverse frame 6a in the Y-axis direction and the Z-axis direction is provided for the lift frame 5a, and the traverse frame 6a is prevented from moving in the Y-axis direction and the Z-axis direction by the guide. Regulated.

Further, the traverse unit 6 includes a traverse driving section 6b, as shown in FIG. The traversing driving section 6b is supported by the traversing frame 6a, generates power for traversing the traversing frame 6a, and transmits the generated motive power to the traversing frame 6a. Such a traverse drive unit 6b includes, for example, a servomotor and a transmission mechanism for transmitting power generated by the servomotor.

The turning unit 7, as shown in FIG. 2, includes a turning frame 7a (opposing frame) and a turning ring 7b. The revolving frame 7a is a frame member that is connected to the traversing frame 6a via a revolving ring 7b and that can be revolved around a revolving axis La parallel to the Z-axis. The turning ring 7b connects the traversing frame 6a and the turning frame 7a, and supports the turning frame 7a so as to turn.

In addition, as shown in FIG. 3, the turning unit 7 has a turning drive section 7c. The turning drive unit 7c is supported by, for example, the traversing frame 6a, generates power for turning the turning frame 7a, and transmits the generated power to the turning frame 7a. Such a turning drive unit 7c includes, for example, a servomotor and a transmission mechanism that transmits power generated by the servomotor.

The suspension chain 8 is a cord-like member that connects the swivel unit 7 and the spreader unit 11 . In this embodiment, the suspension chain 8 is used as the cord-like member, but any cord-like member may be used, and it is also possible to use, for example, a wire as the cord-like member.

4A and 4B are schematic enlarged views including the swivel unit 7 and the spreader unit 11, where (a) is a plan view and (b) is a side view. As shown in FIG. 4, in this embodiment, suspension chains 8 are provided at respective corners of a substantially rectangular revolving frame 7a in plan view. That is, in this embodiment, four suspension chains 8 are provided. The upper end of each suspension chain 8 is connected to the revolving frame 7a.

Each suspension chain 8 is suspended from the revolving frame 7a so as to be parallel to the Z-axis. Each suspension chain 8 has a lower end connected to a fixed frame 11a of the spreader unit 11, which will be described later. These suspension chains 8 suspend and support the spreader unit 11 so as to be horizontally swingable with respect to the turning unit 7 (that is, the lifting unit 5).

The rocking fixing device 9 and the rocking fixing device 10 are locking devices that restrict or allow horizontal movement of the spreader unit 11 with respect to the turning unit 7 . That is, the rocking fixing device 9 and the rocking fixing device 10 restrict the movement of the spreader unit 11 in the horizontal direction with respect to the turning unit 7 and the movement of the spreader unit 11 in the horizontal direction and the vertical direction with respect to the turning unit 7. It is possible to switch the state of the spreader unit 11 between a state that allows

The state in which the horizontal movement of the spreader unit 11 with respect to the revolving unit 7 is restricted means that the spreader unit 11 suspended by the suspension chain 8 moves horizontally with respect to the revolving unit 7 (support). It means the state of stopping rocking. The state in which the spreader unit 11 is allowed to move horizontally and vertically with respect to the revolving unit 7 means that the spreader unit 11 suspended by the suspension chain 8 moves horizontally with respect to the revolving unit 7 (support). This means a state in which the spreader unit 11 is allowed to swing and the swinging of the spreader unit 11 is not restricted.

The swing fixing device 9 is fixed to one of the corners of the swing frame 7a, as shown in FIG. Further, the rocking fixing device 10 is fixed to a corner located diagonally across the turning axis La from the corner where the rocking fixing device 9 is provided. The revolving frame 7a is a frame member that faces the spreader unit 11 from above. That is, in this embodiment, the rocking fixing device 9 and the rocking fixing device 10 are arranged to face the spreader unit 11 from above and are fixed to the revolving frame 7a to which the upper end of the suspension chain 8 is connected. .

FIG. 5 is a schematic diagram of the rocking fixing device 9 (rocking fixing device 10). As shown in this figure, the rocking fixing device 9 includes a support portion 9a, a rotating piece 9b, a toggle mechanism 9c, and a toggle mechanism driving portion 9d.

The support portion 9a is fixed to the turning frame 7a and supports the turning piece 9b and the toggle mechanism 9c. The rotating piece 9b is rotatably connected to the supporting portion 9a. The rotating piece 9b is provided so as to be rotatable between an accommodation posture as shown in FIG. 5(a) and a locking posture as shown in FIG. 5(c). Note that the accommodation posture is a posture in which the tip of the rotating piece 9b faces the horizontal direction and the tip of the rotating piece 9b is separated from the spreader unit 11 . The locked posture is a posture in which the tip of the rotating piece 9b faces downward and the tip of the rotating piece 9b is in contact with the spreader unit 11. As shown in FIG.

The toggle mechanism 9c is a link mechanism that connects the rotating piece 9b and the toggle mechanism driving portion 9d. The toggle mechanism 9c increases the force input from the toggle mechanism driving portion 9d and transmits it to the rotating piece 9b. Further, the toggle mechanism 9c is formed so as to prevent force from being transmitted from the rotating piece 9b to the toggle mechanism driving portion 9d when the rotating piece 9b is in the locked posture.

The toggle mechanism drive unit 9d is supported by the revolving frame 7a, generates power for driving the toggle mechanism 9c, and transmits the generated power to the toggle mechanism 9c. Such a toggle mechanism driving portion 9d is composed of, for example, an induction motor or a servomotor.

When power is transmitted from the toggle mechanism driving portion 9d to the rotating piece 9b via the toggle mechanism 9c, the rotating piece 9b is rotated. Specifically, the rotating piece 9b moves from the stored posture shown in FIG. 5(a) to the intermediate posture shown in FIG. c) is pivoted into the locked position. Further, the rotating piece 9b is rotated from the locking posture shown in FIG. 5(c) to the accommodation posture shown in FIG. 5(a) via the intermediate posture shown in FIG. 5(b).

The rocking fixing device 10 has the same configuration as the rocking fixing device 9 . That is, the rocking fixing device 10 includes a support portion 10a, a rotating piece 10b, a toggle mechanism 10c, and a toggle mechanism driving portion 10d.

The supporting portion 10a is fixed to the turning frame 7a and supports the turning piece 10b and the toggle mechanism 10c. The rotating piece 10b is rotatably connected to the supporting portion 10a. The rotating piece 10b is provided so as to be rotatable between an accommodation posture as shown in FIG. 5(a) and a locking posture as shown in FIG. 5(c). Note that the accommodation posture is a posture in which the tip of the rotating piece 10b faces the horizontal direction and the tip of the rotating piece 10b is separated from the spreader unit 11 . The locked posture is a posture in which the tip of the rotating piece 10b faces downward and the tip of the rotating piece 10b is in contact with the spreader unit 11. As shown in FIG.

The toggle mechanism 10c is a link mechanism that connects the rotating piece 10b and the toggle mechanism drive section 10d. The toggle mechanism 10c increases the force input from the toggle mechanism driving portion 10d and transmits it to the rotating piece 10b. Further, the toggle mechanism 10c is formed so as to prevent force from being transmitted from the rotating piece 10b to the toggle mechanism driving portion 10d when the rotating piece 10b is in the locked posture.

The toggle mechanism drive unit 10d is supported by the revolving frame 7a, generates power for driving the toggle mechanism 10c, and transmits the generated power to the toggle mechanism 10c. Such a toggle mechanism driving section 10d is composed of, for example, a stepping motor.

When power is transmitted from the toggle mechanism driving portion 10d to the rotating piece 10b via the toggle mechanism 10c, the rotating piece 10b is rotated. Specifically, the rotating piece 10b is rotated from the accommodation posture shown in FIG. 5(a) to the locking posture shown in FIG. 5(c) via the intermediate posture shown in FIG. 5(b). . Further, the rotating piece 10b is rotated from the locking posture shown in FIG. 5(c) to the accommodation posture shown in FIG. 5(a) via the intermediate posture shown in FIG. 5(b).

When the pivoting piece 9b of the pivoting fixing device 9 and the pivoting piece 10b of the pivoting fixing device 10 are in the accommodated posture, the pivoting fixing device 9 and the pivoting fixing device 10 are connected to the spreader unit 11. do not come into contact with Therefore, the spreader unit 11 can swing by moving horizontally with respect to the turning unit 7 while being suspended by the suspension chain 8 .

On the other hand, when the rotating piece 9b of the rocking fixing device 9 and the rotating piece 10b of the rocking fixing device 10 are in the locking posture, the rocking fixing device 9 and the rocking fixing device 10 are attached to the spreader unit 11. abut. Therefore, the spreader unit 11 is restricted from swinging in the horizontal direction with respect to the revolving unit 7 while being suspended by the suspension chain 8 .

In this manner, the rocking fixing device 9 and the rocking fixing device 10 restrict the movement of the spreader unit 11 in the horizontal direction with respect to the turning unit 7 by coming into contact with the spreader unit 11 , and move away from the spreader unit 11 . Allows horizontal movement of the spreader unit 11 with respect to the swivel unit 7 . The vertical movement of the spreader unit 11 with respect to the swivel unit 7 is also restricted by the abutment of the rocking fixing device 9 and the rocking fixing device 10 on the spreader unit 11 . Further, by separating the swing fixing device 9 and the swing fixing device 10 from the spreader unit 11 , the spreader unit 11 is allowed to move in the vertical direction with respect to the swivel unit 7 .

The rocking fixing device 9 and the rocking fixing device 10 move the container C supported by the spreader unit 11 without coming into contact with the container transport truck T or the truck 301 under the control of the transfer device control unit 20, which will be described later. In the state of horizontal movement, the horizontal movement of the spreader unit 11 with respect to the revolving unit 7 is restricted.

Further, the rocking fixing device 9 and the rocking fixing device 10 move horizontally without the spreader unit 11 coming into contact with the container C (that is, without supporting the container C) under the control of the transfer device control unit 20. In this state, the horizontal movement of the spreader unit 11 with respect to the turning unit 7 is restricted.

On the other hand, the rocking fixing device 9 and the rocking fixing device 10 are controlled by the transfer device control section 20 so that the container C supported by the spreader unit 11 contacts the container transport truck T or the carriage 301 . In this state, the spreader unit 11 is allowed to move horizontally and vertically with respect to the revolving unit 7 .

Further, the swing fixing device 9 and the swing fixing device 10 are controlled by the transfer device control section 20 when the spreader unit 11 not supporting the container C is placed on the container transport truck T or the carriage 301. While in contact with the container C, the spreader unit 11 is allowed to move horizontally and vertically with respect to the revolving unit 7 .

In this embodiment, the suspension chain 8 , the rocking fixing device 9 and the rocking fixing device 10 are interposed between the spreader unit 11 and the turning unit 7 . That is, the suspension chain 8 , the rocking fixing device 9 and the rocking fixing device 10 are interposed between the spreader unit 11 and the lifting unit 5 . Further, the suspension chain 8, the rocking fixing device 9, and the rocking fixing device 10 restrict or allow the horizontal movement of the spreader unit 11 with respect to the revolving unit 7 as described above.

The suspension chain 8 , the rocking fixing device 9 and the rocking fixing device 10 as described above constitute a spreader unit supporting portion 12 interposed between the spreader unit 11 and the lifting unit 5 . When the container C supported by the spreader unit 11 moves horizontally without coming into contact with the container transport truck T or the carriage 301, the spreader unit support 12 prevents the spreader unit 11 from moving in the horizontal direction. to regulate. Further, when the spreader unit 11 moves horizontally without contacting the container C, the spreader unit support part 12 restricts the horizontal movement of the spreader unit 11 with respect to the turning unit 7 .

Under the control of the transfer device control section 20, the spreader unit support section 12 is in a state where the container C supported by the spreader unit 11 is in contact with the container transport truck T or the carriage 301. It allows horizontal and vertical movement of the unit 11 with respect to the turning unit 7 . In addition, the spreader unit supporting portion 12 is configured to support the rotation unit 7 of the spreader unit 11 when the spreader unit 11 not supporting the container C is in contact with the container C placed on the container transport truck T or the carriage 301 . Allows horizontal and vertical movement.

Returning to FIG. 2, the spreader unit 11 is a unit that supports the container C. As shown in FIG. This spreader unit 11 comprises a fixed frame 11a and a movable frame 11b. The fixed frame 11a is connected to the revolving frame 7a via the suspension chain 8. As shown in FIG. The moving frame 11b is a frame member attached to the fixed frame 11a so as to be movable in the X-axis direction. As shown in FIG. 2, the moving frames 11b are provided on both ends of the fixed frame 11a in the X-axis direction. That is, two moving frames 11b are provided.

These moving frames 11b are synchronously moved in opposite directions to each other in the X-axis direction. That is, when one moving frame 11b is moved in the +X direction, the other moving frame 11b is moved in the -X direction by the same distance. By moving the moving frame 11b with respect to the fixed frame 11a in this manner, the spreader unit 11 expands and contracts.

The spreader unit 11 also includes a moving frame drive section 11c, as shown in FIG. The moving frame drive section 11c is supported by, for example, the fixed frame 11a, generates power for extending and retracting the moving frame 11b, and transmits the generated power to the moving frame 11b. Such a moving frame driving section 11c includes, for example, a servomotor and a transmission mechanism for transmitting power generated by the servomotor.

The spreader unit 11 also includes a twist lock device 14 and a twist lock device 14 . The twist lock device 13 and the twist lock device 14 are provided at the tip of the moving frame 11 b of the spreader unit 11 . The twist lock device 13 is provided at one end of the two moving frames 11b. Also, the twist lock device 14 is provided at the other end of the three moving frames 11b. These twist lock device 13 and twist lock device 14 are devices for connecting the spreader unit 11 and the container C. As shown in FIG.

The twist lock device 13 has two twist lock pins 13a. These twist lock pins 13a are spaced apart in the Y-axis direction. These twist lock pins 13a are provided to the moving frame 11b so as to be rotatable around a rotation axis Lb parallel to the Z-axis direction. These twist lock pins 13a are formed in a shape that tapers downward. Further, these twist lock pins 13a are formed in such a shape that the horizontal width before rotation and the horizontal width after rotation change by rotating about the rotation axis Lb.

Such a twist lock pin 13a rotates around the rotation axis Lb to change its posture between the unlocked posture and the locked posture. The unlocking posture is a posture in which the twist lock pin 13a can be inserted into and pulled out of the fixture C1 provided at the corner of the container C. As shown in FIG. On the other hand, the lock posture is a posture in which the twist lock pin 13a cannot be inserted into or removed from the fixing bracket C1 of the container C. As shown in FIG. That is, the container C is locked with respect to the spreader unit 11 by inserting the twist lock pin 13a in the unlocked posture into the fixture C1 and then changing the posture to the locked posture.

Further, the twist lock device 13 (that is, the spreader unit 11) is provided with a twist lock pin driving portion 13b, as shown in FIG. The twist lock pin driving portion 13b generates power for rotationally driving the twist lock pin 13a and transmits the generated power to the two twist lock pins 13a. Such a twist lock pin driving portion 13b includes, for example, an induction motor or a servomotor, and a transmission mechanism for transmitting the power of the induction motor or the servomotor.

The twist lock device 14 has a configuration similar to that of the twist lock device 13 . That is, the twist lock device 14 has two twist lock pins 14a. These twist lock pins 14a are spaced apart in the Y-axis direction. These twist lock pins 14a are provided to the moving frame 11b so as to be rotatable around a rotation axis Lb parallel to the Z-axis direction. These twist lock pins 14a are formed in a shape that tapers downward. Further, these twist lock pins 14a are formed in such a shape that the horizontal width before rotation and the horizontal width after rotation change by rotating about the rotation axis Lb. Such a twist lock pin 14a rotates around the rotation axis Lb, thereby changing its posture between the unlocked posture and the locked posture.

Further, the twist lock device 14 (that is, the spreader unit 11) includes a twist lock pin driving portion 14b, as shown in FIG. The twist lock pin driving portion 14b generates power for rotationally driving the twist lock pin 14a and transmits the generated power to the two twist lock pins 14a. Such a twist lock pin driving portion 14b includes, for example, an induction motor or a servomotor, and a transmission mechanism for transmitting the power of the induction motor or the servomotor.

As shown in FIG. 3, the container transfer device 400 of the present embodiment includes a transfer device control unit 20, an upper seating sensor 21, a torque sensor 22, a track position detection sensor 23, a position measurement unit 24, A display device 25 and an input device 26 are provided.

As shown in FIG. 3 , the transfer device control section 20 includes a travel drive section 2 b of the travel unit 2 , a travel drive section 3 b of the travel unit 3 , an elevation drive section 5 b of the elevation unit 5 , and a traversing unit 6 of the traversing unit 6 . A driving portion 6b, a turning driving portion 7c of the turning unit 7, a toggle mechanism driving portion 9d of the rocking fixing device 9, a toggle mechanism driving portion 10d of the rocking fixing device 10, and a moving frame driving portion 11c of the spreader unit 11. , a twist lock pin drive section 13b of the spreader unit 11, a twist lock pin drive section 14b of the spreader unit 11, an upper seating sensor 21, a torque sensor 22, a track position detection sensor 23, a position measurement section 24, It is electrically connected to the display device 25 and the input device 26 .

The transfer device control unit 20 includes a storage unit 20a that stores programs for performing various arithmetic processing and various data, and an arithmetic control unit 20b that performs arithmetic processing and controls various devices. Such a transfer device control unit 20 is configured by, for example, a computer device. For example, the transfer device control section 20 performs arithmetic processing based on input signals from the upper seating sensor 21 , the torque sensor 22 or the track position detection sensor 23 . Further, the transfer device control section 20 controls the travel drive section 2b of the travel unit 2, the travel drive section 3b of the travel unit 3, the elevation drive section 5b of the elevation unit 5, the traverse drive of the traverse unit 6, and the travel drive section 2b of the travel unit 2. section 6b, turning driving section 7c of turning unit 7, toggle mechanism driving section 9d of rocking fixing device 9, toggle mechanism driving section 10d of rocking fixing device 10, moving frame driving section 11c of spreader unit 11, spreader unit 11 It controls the twist lock pin drive section 13b or the twist lock pin drive section 14b of the spreader unit 11.

Further, the transfer device control unit 20 stores in advance the stop reference position of the container transport truck T in the truck stop area R1. Further, the transfer device control unit 20 stores in advance an allowable positional deviation amount between the container transport truck T and the spreader unit 11 when the container C is delivered.

The upper seating sensor 21 is a sensor that detects that the spreader unit 11 has come into contact with the upper portion of the container C. As shown in FIG. Such an upper seating sensor 21 is provided at the tip of the moving frame 11b of the spreader unit 11, for example. For example, a pressure sensor or the like can be used as the upper seating sensor 21 .

The torque sensor 22 is a sensor that detects torque acting on the elevation drive section 5b, and is connected to, for example, the output shaft of the servo motor of the elevation drive section 5b. When the container C supported by the spreader unit 11 is placed on the container transport truck T or the carriage 301, the torque acting on the elevation driving section 5b changes. Therefore, based on the detection result of the torque sensor 22, it can be determined whether or not the container C supported by the spreader unit 11 has been placed on the container transport truck T or the truck 301. FIG.

The truck position detection sensor 23 is a sensor for detecting the stop position of the container transport truck T in the truck stop area R1. Such a track position detection sensor 23 is installed, for example, in the track stop area R1. As the track position detection sensor 23, for example, a laser sensor or an imaging camera can be used.

The position measuring unit 24 measures the position of the loading platform of the container transport truck T or the position of the container C loaded on the container transport truck T. FIG. Further, the position measuring unit 24 can precisely measure the positions of the container fixing metal fittings provided on the loading platform of the container transport truck T and the fixing metal fittings C1 of the container C. As shown in FIG. LIDAR (Light Detection and Ranging), for example, can be used as such a position measurement unit 24 .

In addition, the position measurement unit 24 measures the position of the truck 301 of the loading/unloading device 300 or the position of the container C loaded on the truck 301 as necessary. In such a case, the position measurement unit 24 can precisely measure the positions of the container fixing metal fittings provided on the carriage 301 and the fixing metal fittings C1 of the container C. FIG.

The display device 25 visualizes instructions to the driver of the container transport truck T from the transfer device control unit 20 . A display can be used as the display device 25 . The input device 26 is a device for inputting a driver's instruction, and can use, for example, a button switch or a touch panel.

Next, the operation (container transfer method) of the container transfer apparatus 400 of this embodiment will be described with reference to FIGS. 6 to 8. FIG. In the following description, unless otherwise specified, the transfer device control section 20 is the subject of the operation.

FIG. 6 is a flow chart for explaining the operation of the guiding process for guiding the container transport truck T to the truck stop area R1. As shown in FIG. 6, the transfer device control section 20 detects the track position (step S11). Here, the transfer device control section 20 detects the position of the container transport truck T stopped in the truck stop area R1 based on the input signal from the truck position detection sensor 23 .

Subsequently, the transfer device control section 20 calculates the amount of deviation (step S12). Here, when the truck position calculated in step S11 is displaced with respect to the stop reference position stored in advance, the transfer device control unit 20 calculates the amount of displacement of the container transport truck T from the stop reference position as the deviation amount. Calculate as

Subsequently, the transfer device control section 20 determines whether or not the deviation amount is within the allowable range (step S13). Here, the transfer device control section 20 compares the amount of deviation calculated in step S12 with the permissible value of the amount of deviation stored in advance, and determines whether or not the amount of deviation is within the permissible range.

When it is determined in step S12 that the amount of deviation is not within the allowable range, the transfer device control section 20 instructs the amount of movement (step S14). Here, the transfer device control unit 20 calculates the movement direction and the movement distance of the container transport truck T based on the amount of deviation calculated in step S13, and displays information including these as the movement amount on the display device 25. display. When step S14 is completed, the transfer device control section 20 performs step S11 again.

On the other hand, when it is determined in step S12 that the deviation amount is within the allowable range, the transfer device control section 20 issues a stop instruction (step S15). Here, the transfer device control unit 20 causes the display device 25 to display the information for instructing the stop of the vehicle as the aforementioned stop instruction.

After that, the transfer device control unit 20 confirms the stop completion input (step S16) and ends the guidance process of the container transport truck T. FIG. Here, the transfer device control unit 20 confirms the stop completion input by the driver inputting information indicating the stop of the vehicle to the input device 26 .

FIG. 7 is a flow chart for explaining the operation of the loading process for placing the container C supported by the spreader unit 11 on the container transport truck T. As shown in FIG. Note that the load placement process is performed after the above-described guidance process is completed. Further, when starting the cargo placement process, the spreader unit 11 is in a locked state in which movement in the horizontal direction and the vertical direction with respect to the revolving unit 7 is restricted by the rocking fixing device 9 and the rocking fixing device 10. there is

As shown in FIG. 7, when the cargo placement process is started, the transfer device control unit 20 measures the cargo placement position (step S21). Here, the transfer device control unit 20 uses the position measurement unit 24 to measure the position of the bed (placement position) of the container transport truck T, and sets the position of the bed as the placement position.

Subsequently, the transfer device control section 20 horizontally moves the spreader unit 11 to above the loading position (step S22). Here, the transfer device control section 20 controls the travel drive section 2b of the travel unit 2 and the travel drive section 3b of the travel unit 3 to move the travel unit 2 and the travel unit 3 along the rail 1 in the Y-axis direction. move to This causes the spreader unit 11 to move in the Y-axis direction. The transfer device control section 20 also moves the traversing unit 6 in the X-axis direction by controlling the traversing driving section 6b of the traversing unit 6 . This causes the spreader unit 11 to move in the X-axis direction.

Further, in step S22, the spreader unit 11 is turned around the turning axis La by the turning unit 7 as necessary. Here, the transfer device control section 20 turns the turning frame 7a by controlling the turning driving section 7c of the turning unit 7. As shown in FIG. As a result, the spreader unit 11 is rotated about the rotation axis La.

Subsequently, the transfer device control section 20 lowers the spreader unit 11 (step S23). Here, the transfer device control section 20 lowers the lifting frame 5a by controlling the lifting driving section 5b of the lifting unit 5. FIG. This causes the spreader unit 11 to descend.

Subsequently, the transfer device control section 20 determines whether or not the lower end of the container C has descended to the precise measurement position (step S24). The precise measurement position indicates a height position at which position measurement is performed more precisely than the measurement performed in step S21. That is, in the present embodiment, the position measurement is performed more precisely than in step S21 when the container C is close to the loading position. Here, the transfer device control unit 20 uses the position measurement unit 24 to determine whether or not the lower end of the container C has descended to the precise measurement position.

When determining in step S24 that the lower end of the container C has not descended to the precise measurement position, the transfer device control section 20 returns to step S23. On the other hand, when it is determined in step S24 that the lower end of the container C has descended to the precise measurement position, the transfer device control section 20 stops descending of the spreader unit 11 (step S25).

Subsequently, the transfer device control section 20 performs precise measurement (step S26). Here, the transfer device control unit 20 uses the position measurement unit 24 to perform precise measurement of the load placement position. Further, the transfer device control unit 20 performs precise measurement of the position of the container C. FIG.

Subsequently, the transfer device control unit 20 determines whether or not the position of the container C with respect to the cargo placement position is within the allowable range (step S27). Here, if the amount of displacement of the position of the container C with respect to the cargo placement position measured in step S26 is within the permissible value stored in advance, the transfer device control unit 20 determines the position of the container C relative to the cargo placement position. is within the allowable range. On the other hand, if the amount of displacement of the position of the container C with respect to the cargo placement position measured in step S26 does not fall within the pre-stored allowable value, the transfer device control unit 20 changes the position of the container C relative to the cargo placement position. is not within the allowable range.

When it is determined in step S27 that the position of the container C with respect to the loading position is not within the allowable range, the transfer device control section 20 corrects the position of the spreader unit 11 (step S28). Here, based on the amount of displacement of the position of the container C with respect to the loading position, the transfer device control section 20 calculates the amount of movement of the spreader unit 11 for keeping the amount of displacement within the allowable range. Further, the transfer device control section 20 moves the spreader unit 11 according to the calculated movement amount.

Specifically, the transfer device control section 20 controls the travel drive section 2b of the travel unit 2 and the travel drive section 3b of the travel unit 3 to move the travel unit 2 and the travel unit 3 along the rail 1 to the Y direction. Move axially. The transfer device control section 20 also moves the traversing unit 6 in the X-axis direction by controlling the traversing driving section 6b of the traversing unit 6 . Further, the transfer device control section 20 controls the turning driving section 7c of the turning unit 7 to turn the turning frame 7a.

When step S28 is completed, the transfer device control section 20 performs step S26 again. On the other hand, when it is determined in step S27 that the position of the container C with respect to the loading position is within the allowable range, the transfer device control section 20 unlocks the spreader unit 11 (step S29). Here, the transfer device control section 20 controls the toggle mechanism driving section 9d of the rocking fixing device 9 to change the posture of the rotating piece 9b from the locking posture to the accommodation posture. Further, the transfer device control section 20 controls the toggle mechanism driving section 9d of the rocking fixing device 10 to change the posture of the rotating piece 10b from the locking posture to the accommodation posture. This allows the spreader unit 11 to move horizontally and vertically with respect to the swivel unit 7 .

Subsequently, the transfer device control section 20 lowers the spreader unit 11 at a low speed (step S30). Here, the transfer device control section 20 lowers the lifting frame 5a at a lower speed than in step S23 by controlling the lifting drive section 5b of the lifting unit 5. FIG. As a result, the spreader unit 11 is lowered at low speed.

When the spreader unit 11 is lowered at low speed in this way, the lower end of the container C abuts on the platform of the container transport truck T. As shown in FIG. In this case, since the spreader unit 11 is allowed to move horizontally, it is possible to guide the container C by a guide installed on the loading platform or the like. Therefore, in this embodiment, the alignment accuracy in step S27 can be relaxed compared to the case where horizontal movement of the spreader unit 11 is not permitted.

Subsequently, the transfer device control unit 20 determines whether or not the seating of the container C and the pressing of the container C to the loading position are detected (step S31). For example, a seating sensor is installed in the truck stop area R1, and the transfer device control unit 20 determines that the seating of the container C is detected when a detection signal is input from the seating sensor. It is also possible to detect seating of the container C using the position measuring unit 24 .

Further, the transfer device control section 20 detects pressing of the container C to the loading position based on the input signal from the torque sensor 22 . As the weight of the container C is supported by the container transport truck T, the torque value detected by the torque sensor 22 decreases. Therefore, using the detected value of the torque sensor 22, it is possible to detect the pressing of the container C to the loading position.

In this embodiment, in step S31, it is determined whether or not both the seating of the container C and the pressing of the container C to the loading position are detected. However, the present invention is not limited to this, and in step S31, only either the seating of the container C or the pressing of the container C to the loading position may be detected.

If it is determined in step S31 that the container C is not seated and that the container C is pressed against the loading position, the transfer device control unit 20 returns to step S30 again. On the other hand, when the seating of the container C and the pressing of the container C to the loading position are detected in step S31, the transfer device control unit 20 causes the twist lock device 13 and the twist lock device 14 to move the container. C is unlocked (step S32). Here, the transfer device control section 20 controls the twist lock pin drive section 13b to rotate the twist lock pin 13a to change the posture from the locked posture to the unlocked posture. Further, the transfer device control section 20 controls the twist lock pin drive section 14b to rotate the twist lock pin 14a to change the posture from the locked posture to the unlocked posture. This disconnects the spreader unit 11 from the container C. FIG.

Thereafter, the transfer device control section 20 raises the spreader unit 11 and places the spreader unit 11 in a locked state in which horizontal movement is restricted (step S33). Here, the transfer device control section 20 controls the elevation driving section 5b of the elevation unit 5 to raise the elevation frame 5a. This raises the spreader unit 11 . Further, the transfer device control section 20 controls the toggle mechanism driving section 9d of the rocking fixing device 9 to change the posture of the rotating piece 9b from the accommodation posture to the locking posture. Further, the transfer device control section 20 controls the toggle mechanism driving section 9d of the rocking fixing device 10 to change the posture of the rotating piece 10b from the accommodation posture to the locking posture. This restricts the horizontal and vertical movement of the spreader unit 11 with respect to the swivel unit 7 .

In this way, the process of placing the container C supported by the spreader unit 11 onto the container transport truck T is completed. When the container C supported by the spreader unit 11 is transferred to the carriage 301 of the loading/unloading device 300, the container transport truck described above is used except that the loading position of the container C is changed to the carriage 301 (placement location). It is the same as the loading process to T. Therefore, a detailed description of the process of placing the cargo on the truck 301 is omitted.

FIG. 8 is a flow chart for explaining the operation of the cargo receiving process in which the spreader unit 11 receives the container C loaded on the container transport truck T. As shown in FIG. Note that the pick-up process is performed after the above-described guidance process is completed. Further, when starting the pick-up process, the spreader unit 11 is placed in a locked state in which movement in the horizontal direction and the vertical direction with respect to the revolving unit 7 is restricted by the rocking fixing device 9 and the rocking fixing device 10. there is

As shown in FIG. 8, when the pickup process is started, the transfer device control unit 20 measures the position of the container (step S41). Here, the transfer device control section 20 measures the position of the container C using the position measurement section 24 .

Subsequently, the transfer device control section 20 horizontally moves the spreader unit 11 above the container C (step S42). Here, the transfer device control section 20 controls the travel drive section 2b of the travel unit 2 and the travel drive section 3b of the travel unit 3 to move the travel unit 2 and the travel unit 3 along the rail 1 in the Y-axis direction. move to This causes the spreader unit 11 to move in the Y-axis direction. The transfer device control section 20 also moves the traversing unit 6 in the X-axis direction by controlling the traversing driving section 6b of the traversing unit 6 . This causes the spreader unit 11 to move in the X-axis direction. The transfer device control section 20 can adjust the position of the moving frame 11b (that is, the length of the spreader unit 11) by controlling the moving frame driving section 11c of the spreader unit 11. FIG. The position of the moving frame 11b can be adjusted in accordance with the operation timing of the traveling unit 2 or the traversing unit 6. FIG. Further, the position of the moving frame 11b may be adjusted before the traveling unit 2 or the traversing unit 6 operates. The position of the moving frame 11b is adjusted based on pre-registered upper data (container data to be transferred). In step S41, it is possible to confirm whether or not the upper data and the measured position of the container match.

Further, in step S42, the spreader unit 11 is turned around the turning axis La by the turning unit 7 as necessary. Here, the transfer device control section 20 turns the turning frame 7a by controlling the turning driving section 7c of the turning unit 7. As shown in FIG. As a result, the spreader unit 11 is rotated about the rotation axis La.

Subsequently, the transfer device control section 20 measures the position of the fixture C1 on the top of the container C (step S43). Here, the transfer device control section 20 uses the position measurement section 24 to perform precise measurement of the position of the fixture C1.

Subsequently, the transfer device control section 20 determines whether or not the position of the spreader unit 11 with respect to the position of the fixture C1 of the container C is within the allowable range (step S44). Here, if the amount of displacement of the position of the spreader unit 11 with respect to the position of the fixture C1 of the container C measured in step S43 is within the permissible value stored in advance, the transfer device control unit 20 determines that the container C It is determined that the position of the spreader unit 11 with respect to the position of the fixture C1 is within the allowable range. On the other hand, if the amount of displacement of the position of the spreader unit 11 with respect to the position of the fixture C1 of the container C measured in step S43 does not fall within the permissible value stored in advance, the transfer device control unit 20 It is determined that the position of the spreader unit 11 with respect to the position of the fixture C1 is not within the allowable range.

If it is determined in step S44 that the position of the spreader unit 11 relative to the position of the fixture C1 of the container C is not within the allowable range, the transfer device control section 20 corrects the position of the spreader unit 11 (step S45). ). Here, based on the amount of displacement of the position of the container C with respect to the loading position, the transfer device control section 20 calculates the amount of movement of the spreader unit 11 for keeping the amount of displacement within the allowable range. Further, the transfer device control section 20 moves the spreader unit 11 according to the calculated movement amount.

Specifically, the transfer device control section 20 adjusts the position of the moving frame 11b (that is, the length of the spreader unit 11) by controlling the moving frame driving section 11c of the spreader unit 11. FIG. The transfer device control section 20 moves the traveling unit 2 and the traveling unit 3 along the rail 1 in the Y-axis direction by controlling the traveling driving section 2b of the traveling unit 2 and the traveling driving section 3b of the traveling unit 3. . The transfer device control section 20 also moves the traversing unit 6 in the X-axis direction by controlling the traversing driving section 6b of the traversing unit 6 . Further, the transfer device control section 20 controls the turning driving section 7c of the turning unit 7 to turn the turning frame 7a.

When step S45 is completed, the transfer device control section 20 performs step S43 again. On the other hand, if it is determined in step S44 that the position of the spreader unit 11 with respect to the position of the fixture C1 of the container C is within the allowable range, the transfer device control section 20 unlocks the spreader unit 11 ( step S46). Here, the transfer device control section 20 controls the toggle mechanism driving section 9d of the rocking fixing device 9 to change the posture of the rotating piece 9b from the locking posture to the accommodation posture. Further, the transfer device control section 20 controls the toggle mechanism driving section 9d of the rocking fixing device 10 to change the posture of the rotating piece 10b from the locking posture to the accommodation posture. This allows the spreader unit 11 to move horizontally and vertically with respect to the swivel unit 7 .

Subsequently, the transfer device control section 20 lowers the spreader unit 11 at a low speed (step S47). Here, the transfer device control section 20 lowers the spreader unit 11 at a low speed similar to that in step S30 by controlling the elevation driving section 5b of the elevation unit 5. FIG. As a result, the spreader unit 11 is lowered at low speed.

When the spreader unit 11 is lowered at low speed in this manner, the spreader unit 11 comes into contact with the container C. As shown in FIG. In this case, since the spreader unit 11 is allowed to move horizontally, the spreader unit 11 can be guided by the guides installed in the container C. FIG. Therefore, in the present embodiment, the alignment accuracy in step S44 can be relaxed compared to when horizontal movement of the spreader unit 11 is not permitted.

Subsequently, the transfer device control section 20 determines whether or not seating of the spreader unit 11 and pressing of the spreader unit 11 against the container C are detected (step S48). Here, when a signal indicating that the spreader unit 11 has been seated on the container C is input from the upper seating sensor 21, the transfer device control section 20 determines that seating of the spreader unit 11 has been detected.

Further, the transfer device control section 20 detects pressing of the spreader unit 11 against the container C based on the input signal from the torque sensor 22 . Since the weight of the spreader unit 11 is supported by the container C, the torque value detected by the torque sensor 22 decreases. Therefore, the pressure of the spreader unit 11 against the container C can be detected using the detected value of the torque sensor 22 .

In this embodiment, in step S48, it is determined whether or not both the seating of the spreader unit 11 and the pressing of the spreader unit 11 against the container C are detected. However, the present invention is not limited to this, and in step S48, either seating of the spreader unit 11 or pressing of the spreader unit 11 against the container C may be detected.

If it is determined in step S48 that the spreader unit 11 is not seated and that the spreader unit 11 is pressed against the container C, the transfer device control section 20 returns to step S47 again. On the other hand, when the seating of the spreader unit 11 and the pressing of the spreader unit 11 against the container C are detected in step S48, the transfer device control unit 20 causes the twist lock device 13 and the twist lock device 14 to Lock the container C (step S49). Here, the transfer device control section 20 controls the twist lock pin drive section 13b to rotate the twist lock pin 13a to change the posture from the unlocked posture to the locked posture. Further, the transfer device control section 20 controls the twist lock pin drive section 14b to rotate the twist lock pin 14a to change the posture from the unlocked posture to the locked posture. The spreader unit 11 and the container C are thereby fixed.

Thereafter, the transfer device control section 20 raises the spreader unit 11 and places the spreader unit 11 in a locked state in which horizontal movement is restricted (step S50). Here, the transfer device control section 20 controls the elevation driving section 5b of the elevation unit 5 to raise the elevation frame 5a. This raises the spreader unit 11 . Further, the transfer device control section 20 controls the toggle mechanism driving section 9d of the rocking fixing device 9 to change the posture of the rotating piece 9b from the accommodation posture to the locking posture. Further, the transfer device control section 20 controls the toggle mechanism driving section 9d of the rocking fixing device 10 to change the posture of the rotating piece 10b from the accommodation posture to the locking posture. This restricts the horizontal and vertical movement of the spreader unit 11 with respect to the swivel unit 7 .

In this way, the load handling process in which the spreader unit 11 receives the container C from the container transport truck T is completed. When the spreader unit 11 receives the container C from the carriage 301, the processing for receiving the container C from the container hauling truck T is the same as described above, except that the carriage 301 is replaced by the container hauling truck T. Therefore, a detailed description of the pick-up process from the trolley 301 is omitted.

The container transfer device 400 of this embodiment as described above transfers the container C. As shown in FIG. Further, the container transfer device 400 of this embodiment includes a spreader unit 11 , an elevating unit 5 , and a spreader unit support section 12 . The spreader unit 11 supports the container C. The elevating unit 5 elevates the elevating frame 5a while its movement in the horizontal direction is restricted. The spreader unit support portion 12 is interposed between the spreader unit 11 and the lifting unit 5 .

Further, in the container transfer apparatus 400 of the present embodiment, the spreader unit support section 12 moves horizontally without contacting the container C supported by the spreader unit 11 with respect to the placement position. It regulates the horizontal and vertical movement of the spreader unit 11 with respect to the swivel unit 7 . Further, the spreader unit supporting portion 12 restricts the horizontal and vertical movement of the spreader unit 11 with respect to the turning unit 7 while the spreader unit 11 is moving horizontally without contacting the container C. As shown in FIG. In addition, the spreader unit support section 12 prevents the spreader unit 11 from moving horizontally and vertically with respect to the turning unit 7 while the container C supported by the spreader unit 11 is in contact with the mounting position. allow. Further, the spreader unit supporting portion 12 allows the spreader unit 11 to move horizontally and vertically with respect to the turning unit 7 while the spreader unit 11 not supporting the container C is in contact with the container C.

According to the container transfer device 400 of the present embodiment, the spreader unit 11 can move horizontally and vertically with respect to the turning unit 7 in a state where the container C supported by the spreader unit 11 is not in contact with the placement position. Movement is restricted, and the spreader unit 11 is permitted to move horizontally and vertically with respect to the revolving unit 7 while the container C is in contact with the placement location. Note that the turning unit 7 can be fixed to the lifting unit 5 . That is, according to the container transfer apparatus 400 of the present embodiment, the spreader unit 11 moves horizontally and vertically with respect to the lifting unit 5 in a state in which the container C supported by the spreader unit 11 is not in contact with the placement location. movement of the spreader unit 11 is restricted, and the movement of the spreader unit 11 in the horizontal direction and the vertical direction with respect to the lifting unit 5 is permitted while the container C is in contact with the placement position. According to the container transfer apparatus 400 of the present embodiment, the spreader unit 11 is horizontally moved by a large amount when the container C supported by the spreader unit 11 is not in contact with the placement location. Also, the swinging of the spreader unit 11 can be suppressed. On the other hand, if the container C is in contact with the placement location, the spreader unit 11 will not swing. According to the container transfer device 400 of the present embodiment, the spreader unit 11 can move horizontally and vertically with respect to the turning unit 7 while the container C is in contact with the placement location. , the spreader unit 11 can move along. Therefore, according to the container transfer apparatus 400 of the present embodiment, when the container C is transferred, the spreader unit 11 can be moved horizontally and vertically, and the spreader unit 11 can move horizontally. can be suppressed.

The following movement means that when the spreader unit 11 moves up and down while the container C supported by the spreader unit 11 is in contact with the placement location, it follows the shape of the placement location in the horizontal direction with respect to the turning unit 7 . and moving up and down. In addition, the following movement means that when the spreader unit 11 that does not support the container C is lifted while being in contact with the container C, it moves horizontally and vertically with respect to the turning unit 7 following the shape of the container C. It is a meaning that includes moving.

Further, in the container transfer device 400 of the present embodiment, the spreader unit support section 12 includes the suspension chain 8 that suspends and supports the spreader unit 11 so as to be able to swing in the horizontal direction, and the rotation unit 7 of the spreader unit 11. A swing fixing device (swing fixing device 9 and swing fixing device 10) that can restrict or allow movement in the horizontal direction and the vertical direction is provided.

According to the container transfer device 400 of the present embodiment, by controlling the rocking fixing device 10, the movement of the spreader unit 11 in the horizontal direction and the vertical direction with respect to the turning unit 7 is restricted; It is possible to reliably switch between the state in which the spreader unit 11 is allowed to move in the horizontal direction and the vertical direction with respect to the turning unit 7 .

Further, the container transfer device 400 of the present embodiment is provided with a facing frame arranged to face the spreader unit 11 from above and to which the upper ends of the suspension chains 8 are connected. Further, the rocking fixing device (swinging fixing device 9 and swinging fixing device 10) is fixed to the opposing frame, and by coming into contact with the spreader unit 11, the spreader unit 11 moves horizontally and vertically with respect to the swivel unit 7. movement of the spreader unit 11 is restricted, and the movement of the spreader unit 11 in the horizontal direction and the vertical direction with respect to the revolving unit 7 is permitted.

According to the container transfer device 400 of this embodiment, the movement of the spreader unit 11 in the horizontal direction and the vertical direction with respect to the turning unit 7 is restricted by the abutment of the rocking fixing device 9 and the rocking fixing device 10 . Therefore, it is possible to reliably prevent the spreader unit 11 from swinging in the horizontal direction.

Further, in the container transfer device 400 of the present embodiment, a plurality of rocking fixing devices (rocking fixing device 9 and rocking fixing device 10) are provided. Therefore, the swinging motion of the spreader unit 11 can be restricted at a plurality of locations, and the swinging motion of the spreader unit 11 can be stably suppressed.

Moreover, the container transfer method of this embodiment is a method of transferring the container C. FIG. In the container transfer method of the present embodiment, while the container C supported by the spreader unit 11 is moving horizontally without coming into contact with the placement location, the spreader unit 11 moves in the horizontal direction with respect to the turning unit 7 . and restricts movement in the vertical direction. Further, the spreader unit supporting portion 12 restricts the horizontal and vertical movement of the spreader unit 11 with respect to the turning unit 7 while the spreader unit 11 is moving horizontally without contacting the container C. As shown in FIG. In addition, the spreader unit support section 12 prevents the spreader unit 11 from moving horizontally and vertically with respect to the turning unit 7 while the container C supported by the spreader unit 11 is in contact with the mounting position. allow. Further, the spreader unit supporting portion 12 allows the spreader unit 11 to move horizontally and vertically with respect to the turning unit 7 while the spreader unit 11 not supporting the container C is in contact with the container C.

According to the container transfer device 400 of the present embodiment, the spreader unit 11 can move horizontally and vertically with respect to the turning unit 7 in a state where the container C supported by the spreader unit 11 is not in contact with the placement position. Movement is restricted, and the spreader unit 11 is permitted to move horizontally and vertically with respect to the revolving unit 7 while the container C is in contact with the placement location. Therefore, according to the container transfer device 400 of the present embodiment, if the container C supported by the spreader unit 11 is not in contact with the placement position, the spreader unit 11 can be horizontally moved by a large amount. Swinging of the spreader unit 11 can be suppressed. On the other hand, if the container C is in contact with the placement location, the spreader unit 11 will not swing. According to the container transfer device 400 of the present embodiment, the spreader unit 11 can move horizontally and vertically with respect to the turning unit 7 while the container C is in contact with the placement location. It becomes possible for the unit 11 to copy and move. Therefore, according to the container transfer apparatus 400 of the present embodiment, when the container C is transferred, the spreader unit 11 can be moved horizontally and vertically, and the spreader unit 11 can move horizontally. can be suppressed.

(Second embodiment)
Next, a second embodiment of the invention will be described. In the description of the present embodiment, the description of the same parts as those of the first embodiment will be omitted or simplified.

9A and 9B are schematic enlarged views including the turning unit 7 and the spreader unit 11 provided in the container transfer apparatus of this embodiment, where (a) is a plan view and (b) is a side view. As shown in FIG. 9, in this embodiment, a spreader unit support portion 15 interposed between the turning unit 7 (that is, the lifting unit 5) and the spreader unit 11 is provided.

The spreader unit support section 15 includes a plurality of slanted suspension chains 16 (slanted cord-like members). Each inclined suspension chain 16 is inclined with respect to the Z-axis (vertical axis). Each inclined suspension chain 16 has an upper end fixed to the swing frame 7 a of the swing unit 7 and a lower end fixed to the fixed frame 11 a of the spreader unit 11 .

In this embodiment, a total of eight inclined suspension chains 16 are provided. Two inclined suspension chains 16 are provided, the upper end of which is located in the +X direction with respect to the lower end. Also, two inclined suspension chains 16 are provided, the upper end of which is located in the -X direction with respect to the lower end. Two inclined suspension chains 16 are provided, the upper end of which is positioned in the +Y direction with respect to the lower end. Also, two inclined suspension chains 16 are provided whose upper ends are located in the -Y direction with respect to their lower ends.

Furthermore, one of the inclined suspension chains 16 whose upper end is located in the +X direction with respect to the lower end and one of the inclined suspension chains 16 whose upper end is located in the -X direction with respect to the lower end are arranged along the X-axis direction so as to be close to each other. These inclined suspension chains 16 are arranged so as to be symmetrical with respect to an axis of symmetry that passes through the turning axis La and is parallel to the Y-axis direction. Furthermore, these inclined suspension chains 16 are arranged on the +Y direction side of the turning axis La.

The other inclined suspension chain 16 whose upper end is located in the +X direction with respect to the lower end and the other inclined suspension chain 16 whose upper end is located in the -X direction with respect to the lower end are arranged along the X-axis direction so as to be close to each other. These inclined suspension chains 16 are arranged so as to be symmetrical with respect to an axis of symmetry that passes through the turning axis La and is parallel to the Y-axis direction. Further, these inclined suspension chains 16 are arranged on the -Y direction side of the turning axis La.

One of the inclined suspension chains 16 whose upper end is positioned in the +Y direction with respect to the lower end and one of the inclined suspension chains 16 whose upper end is positioned in the -Y direction with respect to the lower end are arranged such that the upper ends are closer to each other than the lower ends. are arranged along the Y-axis direction so that they are also close to each other. These inclined suspension chains 16 are arranged so as to be symmetrical with respect to an axis of symmetry that passes through the turning axis La and is parallel to the X-axis direction. Furthermore, these inclined suspension chains 16 are arranged on the +X direction side of the turning axis La.

The other inclined suspension chain 16 whose upper end is located in the +Y direction with respect to the lower end and the other inclined suspension chain 16 whose upper end is located in the -Y direction with respect to the lower end are arranged such that the upper ends are closer to each other than the lower ends. are arranged along the Y-axis direction so that they are also close to each other. These inclined suspension chains 16 are arranged so as to be symmetrical with respect to an axis of symmetry that passes through the turning axis La and is parallel to the X-axis direction. Further, these inclined suspension chains 16 are arranged on the -X direction side of the pivot axis La.

Thus, the spreader unit support section 15 in this embodiment includes a plurality of inclined suspension chains 16 that are inclined in different directions with respect to the Z axis. Therefore, the weight of the spreader unit 11 and the container C acts on the inclined suspension chain 16, causing the spreader unit 11 to be pulled from various directions in the horizontal direction. The movement of the spreader unit 11 in the horizontal direction is restricted by balancing the tensile forces from various horizontal directions. That is, the spreader unit support portion 15 in this embodiment restricts the horizontal movement of the spreader unit 11 by the tension acting on the plurality of inclined suspension chains 16 .

In this embodiment, two inclined suspension chains 16 whose upper ends are positioned in the +X direction with respect to the lower ends and two inclined suspension chains 16 whose upper ends are positioned in the -X direction with respect to the lower ends, spreader unit 11 movement in the X-axis direction is restricted. In addition, two inclined suspension chains 16 whose upper ends are located in the +Y direction with respect to the lower ends and two inclined suspension chains 16 whose upper ends are located in the -Y direction with respect to the lower ends allow the spreader unit 11 to extend along the Y axis. Directional movement is restricted.

On the other hand, when the tension acting on the inclined suspension chain 16 is relaxed, the spreader unit 11 is allowed to move horizontally and vertically with respect to the swivel unit 7 . That is, when the container C supported by the spreader unit 11 is placed on the placement location and the weight of the container C and the spreader unit 11 is supported by the placement location, the tension of the inclined suspension chain 16 is loosened and the spreader unit 11 is placed. Horizontal and vertical movement of the unit 11 with respect to the swivel unit 7 is allowed. Similarly, when the spreader unit 11 that does not support the container C abuts the container C placed on the placement location from above, the tension of the inclined suspension chain 16 is loosened, and the spreader unit 11 is lifted. Horizontal and vertical movement with respect to the swivel unit 7 is permitted.

As described above, in the present embodiment, the spreader unit 11 is horizontally moved by using the tension acting on the inclined suspension chain 16 in a state where the container C supported by the spreader unit 11 is not in contact with the mounting position. Regulate directional movement. Further, in this embodiment, the horizontal movement of the spreader unit 11 is restricted by using the tension acting on the inclined suspension chain 16 when the spreader unit 11 that does not support the container C is not in contact with the container C. .

Next, the operation (container transfer method) of the container transfer apparatus of this embodiment will be described with reference to FIGS. 10 and 11. FIG. In the following description, unless otherwise specified, the transfer device control section 20 is the subject of the operation.

FIG. 10 is a flow chart for explaining the operation of the loading process for placing the container C supported by the spreader unit 11 on the container transport truck T. As shown in FIG.

As shown in FIG. 10, when the cargo placement process is started, the transfer device control unit 20 measures the cargo placement position (step S61), as in step S21 of the first embodiment. Subsequently, the transfer device control section 20 horizontally moves the spreader unit 11 to above the loading position (step S62), as in step S22 of the first embodiment. Subsequently, the transfer device control section 20 lowers the spreader unit 11 (step S63), as in step S23 of the first embodiment.

Subsequently, the transfer device control section 20 determines whether or not the lower end of the container C has descended to the precise measurement position (step S64), as in step S24 of the first embodiment. If it is determined in step S64 that the lower end of the container C has not descended to the precise measurement position, the transfer device control section 20 returns to step S63. On the other hand, when it is determined in step S64 that the lower end of the container C has descended to the precise measurement position, the transfer device control section 20 causes the spreader unit 11 to descend as in step S25 of the first embodiment. is stopped (step S65).

Subsequently, the transfer device control unit 20 performs precise measurement (step S66), as in step S26 of the first embodiment. Subsequently, the transfer device control section 20 determines whether or not the position of the container C with respect to the loading position is within the allowable range (step S67), as in step S27 of the first embodiment. If it is determined in step S67 that the position of the container C with respect to the load placement position is not within the allowable range, the transfer device control section 20 controls the position of the spreader unit 11 as in step S28 of the first embodiment. Correction is performed (step S68).

When step S68 is completed, the transfer device control section 20 performs step S66 again. On the other hand, if it is determined in step S67 that the position of the container C with respect to the cargo placement position is within the allowable range, the transfer device control section 20 moves the spreader unit 11 to is lowered at a low speed (step S69). In this embodiment, the rocking fixing device 9 and the rocking fixing device 10 of the first embodiment are not provided. Therefore, in this embodiment, it is not necessary to control the toggle mechanism driving section 9d of the rocking fixing device 9 as in step S29 of the first embodiment.

When the spreader unit 11 is lowered at low speed in this way, the lower end of the container C abuts on the platform of the container transport truck T. As shown in FIG. In this case, the spreader unit 11 is allowed to move horizontally by loosening the inclined suspension chain 16 . As a result, the container C can be guided by a guide installed on the loading platform or the like. Therefore, in this embodiment, the positioning accuracy in step S67 can be relaxed compared to the case where horizontal movement of the spreader unit 11 is not permitted.

Subsequently, similarly to step S31 of the first embodiment, the transfer device control unit 20 determines whether or not the seating of the container C and the pressing of the container C to the loading position are detected (step S70). If it is determined in step S70 that the container C is not seated and that the container C is pressed against the load placement position, the transfer device control section 20 returns to step S69 again. On the other hand, in step S70, when the seating of the container C and the pressing of the container C to the loading position are detected, the transfer device control unit 20 performs the same operation as in step S32 of the first embodiment. , the lock of the container C by the twist lock device 13 and the twist lock device 14 is released (step S71).

After that, the transfer device control section 20 raises the spreader unit 11 (step S72). Here, the transfer device control section 20 controls the elevation driving section 5b of the elevation unit 5 to raise the elevation frame 5a. This raises the spreader unit 11 . When the spreader unit 11 rises, the load of the spreader unit 11 stretches the inclined suspension chain 16 . This restricts the movement of the spreader unit 11 in the horizontal direction.

In this way, the process of placing the container C supported by the spreader unit 11 onto the container transport truck T is completed. When the container C supported by the spreader unit 11 is transferred to the carriage 301 of the loading/unloading device 300, the loading position of the container C is changed to that of the carriage 301. Similar to processing. Therefore, a detailed description of the process of placing the cargo on the truck 301 is omitted.

FIG. 11 is a flow chart for explaining the operation of the cargo receiving process in which the spreader unit 11 receives the container C loaded on the container transport truck T. As shown in FIG.

As shown in FIG. 11, when the pick-up process is started, the transfer device control unit 20 measures the position of the container (step S81) as in step S41 of the first embodiment. Subsequently, the transfer device control section 20 horizontally moves the spreader unit 11 above the container C (step S82), as in step S42 of the first embodiment. Subsequently, the transfer device control unit 20 measures the position of the fixture C1 on the top of the container C (step S83), as in step S43 of the first embodiment.

Subsequently, the transfer device control section 20 determines whether or not the position of the spreader unit 11 with respect to the position of the fixture C1 of the container C is within the allowable range, as in step S44 of the first embodiment. (Step S84). In step S84, when it is determined that the position of the spreader unit 11 with respect to the position of the fixture C1 of the container C is not within the allowable range, the transfer device control section 20 performs the same operation as in step S45 of the first embodiment. , the position of the spreader unit 11 is corrected (step S85).

When step S85 is completed, the transfer device control section 20 performs step S83 again. On the other hand, when it is determined in step S84 that the position of the spreader unit 11 with respect to the position of the fixture C1 of the container C is within the allowable range, the transfer device control section 20 performs step S47 of the first embodiment. Similarly, the spreader unit 11 is lowered at a low speed (step S86). In this embodiment, the rocking fixing device 9 and the rocking fixing device 10 of the first embodiment are not provided. Therefore, in this embodiment, it is not necessary to control the toggle mechanism driving section 9d of the rocking fixing device 9 as in step S46 of the first embodiment.

When the spreader unit 11 is lowered at low speed in this manner, the spreader unit 11 comes into contact with the container C. As shown in FIG. In this case, the spreader unit 11 is allowed to move horizontally by loosening the inclined suspension chain 16 . Therefore, the spreader unit 11 can be guided by a guide installed on the container C. As shown in FIG. Therefore, in this embodiment, the positioning accuracy in step S84 can be relaxed compared to the case where horizontal movement of the spreader unit 11 is not permitted.

Subsequently, similarly to step S48 of the first embodiment, the transfer device control unit 20 determines whether or not seating of the spreader unit 11 and pressing of the spreader unit 11 against the container C are detected ( step S87). If it is determined in step S87 that the spreader unit 11 is not seated and that the spreader unit 11 is pressed against the container C, the transfer device control section 20 returns to step S86 again. On the other hand, when the seating of the spreader unit 11 and the pressing of the spreader unit 11 against the container C are detected in step S87, the transfer device control section 20 performs the same operation as in step S49 of the first embodiment. Then, the container C is locked by the twist lock device 13 and the twist lock device 14 (step S88).

After that, the transfer device control section 20 raises the spreader unit 11 (step S89). Here, the transfer device control section 20 controls the elevation driving section 5b of the elevation unit 5 to raise the elevation frame 5a. This raises the spreader unit 11 . When the spreader unit 11 rises, the load of the spreader unit 11 and the container C tensions the inclined suspension chain 16 . This restricts the movement of the spreader unit 11 in the horizontal direction.

In this way, the load handling process in which the spreader unit 11 receives the container C from the container transport truck T is completed. When the spreader unit 11 receives the container C from the carriage 301, the processing for receiving the container C from the container hauling truck T is the same as described above, except that the carriage 301 is replaced by the container hauling truck T. Therefore, a detailed description of the pick-up process from the trolley 301 is omitted.

In such a container transfer apparatus of this embodiment, the spreader unit support section 15 is configured such that the container C supported by the spreader unit 11 moves horizontally without contacting the placement position. It regulates the horizontal movement of the spreader unit 11 with respect to the turning unit 7 . Further, the spreader unit support portion 15 restricts the horizontal movement of the spreader unit 11 with respect to the turning unit 7 in a state in which the spreader unit 11 moves horizontally without contacting the container C. As shown in FIG. In addition, the spreader unit supporting portion 15 prevents the spreader unit 11 from moving horizontally and vertically with respect to the turning unit 7 in a state where the container C supported by the spreader unit 11 is in contact with the placement position. allow. Further, the spreader unit supporting portion 15 allows the spreader unit 11 to move horizontally and vertically with respect to the turning unit 7 while the spreader unit 11 not supporting the container C is in contact with the container C.

According to the container transfer apparatus of this embodiment, the movement of the spreader unit 11 in the horizontal direction with respect to the turning unit 7 is restricted in a state where the container C supported by the spreader unit 11 is not in contact with the mounting position. , the spreader unit 11 is permitted to move horizontally and vertically with respect to the revolving unit 7 while the container C is in contact with the placement location. Therefore, according to the container transfer apparatus of the present embodiment, if the container C supported by the spreader unit 11 is not in contact with the placement position, the spreader unit 11 can be moved horizontally even if the spreader unit 11 is largely moved. Swinging of the unit 11 can be suppressed. On the other hand, if the container C is in contact with the placement location, the spreader unit 11 will not swing. According to the container transfer apparatus of the present embodiment, the spreader unit 11 can move horizontally and vertically with respect to the turning unit 7 while the container C is in contact with the placement location. It becomes possible for the spreader unit 11 to follow and move. Therefore, according to the container transfer apparatus of the present embodiment, when the container C is transferred, the spreader unit 11 can be moved horizontally and vertically, and the spreader unit 11 can be moved horizontally. Swinging can be suppressed.

Further, according to the container transfer apparatus of the present embodiment, the spreader unit support section 15 includes a plurality of inclined suspension chains 16 connected to the spreader unit 11 while being inclined with respect to the Z axis. The spreader unit support part 15 restricts the horizontal movement of the spreader unit 11 with respect to the turning unit 7 by using the tension acting on the inclined suspension chain 16 when the container C is not in contact with the mounting position. . According to the container transfer apparatus of this embodiment, the state in which the horizontal movement of the spreader unit 11 with respect to the turning unit 7 is restricted and permitted without using a power source such as a motor. can be switched. Therefore, it is possible to simplify the device configuration.

In addition, in the container transfer apparatus of this embodiment, the spreader unit support section 15 includes a plurality of inclined suspension chains 16 that are inclined in different directions with respect to the Z axis. Therefore, it is possible to restrict the movement of the spreader unit 11 in a plurality of directions on the horizontal plane.

In addition, in the container transfer apparatus of this embodiment, the spreader unit support section 15 includes a plurality of inclined suspension chains 16 inclined in the same direction with respect to the Z-axis. Therefore, the movement of the spreader unit 11 in the same direction on the horizontal plane can be restricted by the plurality of inclined suspension chains 16 . Therefore, it becomes possible to restrict the horizontal movement of the spreader unit 11 more stably.

Although the preferred embodiments of the present invention have been described above with reference to the accompanying drawings, it goes without saying that the present invention is not limited to the above embodiments. The various shapes, combinations, and the like of the constituent members shown in the above-described embodiment are merely examples, and can be variously changed based on design requirements and the like without departing from the gist of the present invention.

For example, in the above embodiment, a configuration including the traversing unit 6 and the turning unit 7 has been described. However, the invention is not limited to this. For example, as long as the spreader unit supporting portion is interposed between the spreader unit and the lifting unit, a configuration without the traversing unit 6 and the turning unit 7 can be employed.

DESCRIPTION OF SYMBOLS 1... Rail, 2... Traveling unit, 3... Traveling unit, 4... Girder frame, 5... Lifting unit, 6... Traversing unit, 7... Turning unit, 7a... Turning frame (facing frame) , 8... Suspension chain (rope-like member), 9... Swing fixing device, 10... Swing fixing device, 11... Spreader unit, 12... Spreader unit support part, 13... Twist lock device, 14 Twist lock device 15 Spreader unit support 16 Inclined suspension chain (inclined rope-like member) 20 Transfer device control unit 21 Upper seating sensor 22 Torque sensor , 23... truck position detection sensor, 24... position measuring unit, 25... display device, 26... input device, 100... container hangar, 200... automatic warehouse, 300... loading/unloading device, 301... Carriage 400 Container transfer device C Container C1 Fixing bracket T Container transport truck

Claims (8)

A container transfer device for transferring containers,
a spreader unit supporting the container;
an elevating unit that elevates the elevating frame while movement in the horizontal direction is restricted;
a spreader unit support inserted between the spreader unit and the lifting unit;
The spreader unit supporting portion is
The spreader unit in a state in which the container supported by the spreader unit moves horizontally without coming into contact with the placement location, or in a state in which the spreader unit moves horizontally without coming into contact with the container. Regulating the horizontal movement of the lifting device,
The raising and lowering of the spreader unit in a state in which the container supported by the spreader unit is in contact with the placement location or in a state in which the spreader unit not supporting the container is in contact with the container. A container transfer device that allows at least horizontal movement with respect to the device. The spreader unit supporting portion is
a cord-like member that suspends and supports the spreader unit so that it can swing horizontally with respect to the lifting device;
2. The container transfer device according to claim 1, further comprising: a rocking fixing device capable of restricting or permitting at least horizontal movement of said spreader unit with respect to said lifting device. an opposing frame arranged to face the spreader unit from above and to which the upper ends of the cord-like members are connected;
The rocking fixing device is fixed to the opposing frame, and restricts horizontal movement of the spreader unit with respect to the lifting device by coming into contact with the spreader unit. 3. The container transfer device according to claim 2, wherein the spreader unit is allowed to move at least horizontally with respect to the lifting device. 4. The container transfer apparatus according to claim 2, wherein a plurality of said rocking fixing devices are provided. The spreader unit supporting portion is
comprising a plurality of slanted cord-like members connected to the spreader unit at an angle to a vertical axis;
Acts on the inclined cord-like member in a state in which the container supported by the spreader unit is not in contact with the placement location or in a state in which the spreader unit not supporting the container is not in contact with the container. 2. The container transfer device according to claim 1, wherein the horizontal movement of the spreader unit with respect to the lifting device is regulated by using a tension applied to the container. 6. The container transfer apparatus according to claim 5, wherein said spreader unit support section comprises a plurality of said inclined cord-like members inclined in different directions with respect to said vertical axis. 7. The container transfer apparatus according to claim 5, wherein said spreader unit support section includes a plurality of said inclined cord-like members inclined in the same direction with respect to said vertical axis. A container transfer method for transferring a container,
When the container supported by the spreader unit moves horizontally without coming into contact with the placement location, or when the spreader unit moves horizontally without coming into contact with the container, the spreader unit moves horizontally. regulates directional movement,
When the container supported by the spreader unit is in contact with the placement location or when the spreader unit not supporting the container is in contact with the container, the spreader unit is at least horizontal. A container transfer method characterized by allowing movement in a direction.

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