JP2024098582A - CONTROL DEVICE FOR TRANSPORT SYSTEM AND TRANSPORT SYSTEM - Google Patents

Abstract

To provide a control device of a conveyance system and the conveyance system capable of executing control of a conveyance device for bringing the conveyance device close to a conveyance object in a mode in which the conveyance object is easily connected to the conveyance device.SOLUTION: A traction side control device and a coupling side control device are used in a conveyance system for conveying a truck 11 to a predetermined conveyance place. The transport system comprises a towing vehicle 12 and a coupling device 13. The coupling device 13 comprises a rocking portion 26 capable of following the truck 11 when changing a course of the towing vehicle 12. In these control devices, when the truck 11 is coupled to the coupling device 13, control for moving the towing vehicle 12 in a direction opposite to a direction toward the truck 11, control for ending movement in the opposite direction based on detection of a linear state of a towing device 10, and control for moving the towing vehicle 12 in a direction toward the truck 11 in order to couple the truck 11 to the coupling device 13 are performed.SELECTED DRAWING: Figure 6

Description

The present invention relates to a control device for a transport system and a transport system.

In factories and warehouses, etc., conveying systems are used to transport materials, parts, finished products, and other items to their destinations. Conveying systems include conveying devices with drive wheels and a control device that controls the conveying devices. Examples of conveying devices include conveying devices that are equipped with a platform on which items are placed and that transport items independently, conveying devices that transport items such as carts loaded with items to their destinations while pushing them, and conveying devices that transport items such as carts loaded with items to their destinations while towing them (see, for example, Patent Document 1).

As a transport device for transporting an object to a destination, there is known a device that is equipped with a coupling device for connecting the object to the transport device. With such a transport device, maneuverability becomes an issue when changing course while the object is connected. In response to this, a coupling device is known that has a rotating part that can rotate around a vertical connecting axis to improve the maneuverability of the transport device.

JP 2019-51915 A

However, when using a connecting device with a rotating part, there is a problem that even if the transport device is brought close to the transport target, the transport target may not be connected to the transport device depending on the rotation position of the rotating part. As such, there is still room for improvement in the control device of the transport system and the transport system that executes control to bring the transport device close to the transport target and connect the transport target to the transport device.

The present invention has been made in consideration of the above-mentioned circumstances, and aims to provide a control device for a transport system and a transport system that can control the transport device so that the transport device approaches the object to be transported in a manner that makes it easy to connect the object to the transport device.

In order to solve the above problem, the present invention provides a control device for a transport system used in a transport system for transporting an object to a predetermined transport location, comprising:
The transport system includes:
A transport device having a drive means and transporting the transport object to the predetermined transport location by a driving force of the drive means;
A connecting means for connecting the object to be transported to the transport device;
Equipped with
the connecting means includes a rotating part that is rotatable about a vertical rotation axis so as to enable the object to follow when the traveling direction of the transport device is changed,
The control device includes:
a preparation control means for executing a preparation control so as to move the transport device in a direction opposite to a direction toward the object to be transported when the object to be transported is to be coupled to the coupling means in a state in which the coupling means is coupled to the transport device;
a termination control means for executing a termination control to terminate the movement in the reverse direction based on the occurrence of a predetermined termination trigger in a situation in which the transport device is moving in a direction opposite to the direction toward the transport target as a result of the execution of the preparation control;
a connection control means for executing a connection control to move the transport device in a direction toward the transport object in order to connect the transport object to the connection means after the termination control is executed;
The present invention is characterized in that it is provided with:

To solve the above problem, the invention described in claim 10 is a transport system for transporting an object to be transported to a predetermined transport location, characterized in that it is equipped with the connecting means and the control device described in claim 1.

The present invention makes it possible to provide a control device for a transport system and a transport system that can control the transport device so that the transport device is in a state where the transport object is close to the transport object in a manner that makes it easy to connect the transport object to the transport device.

FIG. 2A is a side view of the towing device and the bogie in the first embodiment, FIG. 2B is a plan view of the bogie as viewed from above, and FIG. 2C is a plan view of the towing vehicle as viewed from above. FIG. 2 is a top perspective view of the coupling device. FIG. 4 is a perspective view of the coupling device as seen from below. (a) is a plan view of the connection part of the coupling device as viewed from above, (b) is a plan view of the second coupling frame with various parts removed as viewed from above, and (c) is an explanatory diagram for explaining how the hook engages with the trolley. FIG. 2 is a block diagram showing the electrical configuration of the towing device. 11A to 11C are explanatory diagrams for explaining the operation of the traction device for connecting the bogie. 13 is a flowchart showing a travel control process in a towing side CPU. 13 is a flowchart showing an abnormality handling process in a towing side CPU. 13 is a flowchart showing a process during a connection operation in a towing side CPU. 13 is a flowchart showing a connecting side process in a connecting side CPU. 13A is a flowchart showing processing during forward movement for connection in the connecting side CPU, and FIG. 13B is a flowchart showing processing during reverse movement for connection in the connecting side CPU. 13A to 13H are time charts showing how the bogie connecting operation is performed. 4A to 4J are time charts showing how an abnormal stop of the traction device is performed.

First Embodiment
DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS A first embodiment of the present invention will now be described in detail with reference to the accompanying drawings. FIG 1(a) is a side view of a towing device 10 and a bogie 11 to be towed by the towing device 10 ....

As shown in FIG. 1(a), the towing device 10 includes a towing vehicle 12 capable of autonomous driving, and a coupling device 13 for coupling the cart 11 to the towing vehicle 12. In this embodiment, for convenience, the front side in the traveling direction when the towing vehicle 12 travels forward is defined as the "front side", and the rear side in the traveling direction is defined as the "rear side". In addition, the right side in the traveling direction when the towing vehicle 12 travels forward is defined as the "right side", and the left side in the traveling direction is defined as the "left side".

Figure 1(b) is a plan view of the cart 11 as seen from above. As shown in Figure 1(b), the cart 11 has a rectangular bottom plate portion 14 and four casters 15a to 15d provided on the bottom surface of the bottom plate portion 14. Transported items (not shown) such as materials, parts, and finished products are placed on top of the bottom plate portion 14. The casters 15a to 15d are wheels that can be oriented freely, and are located at the four corners of the bottom plate portion 14.

The bottom plate portion 14 is provided with a pair of left and right bottom plate through holes 14a, 14b that extend in the front-rear direction. The bottom plate through holes 14a, 14b are formed by penetrating the bottom plate portion 14 in the plate thickness direction. In the bottom plate portion 14, a front frame portion 14c exists in front of the bottom plate through holes 14a, 14b. Of the rear end portion of the front frame portion 14c, the front edge portion 14d of the left bottom plate through hole 14a and the front edge portion 14e of the right bottom plate through hole 14b can be engaged with the connecting device 13.

The configuration of the dolly 11 is not limited to the configuration shown in Fig. 1(a) and Fig. 1(b). For example, the front part of the bottom plate part 14 may have a protrusion protruding downward from the bottom surface of the bottom plate part 14, and the coupling device 13 may be engaged with the protrusion. Also, like a so-called six-wheel dolly, a pair of fixed wheels that are oriented in the front-rear direction and fixed so that their orientation cannot be changed may be provided on the bottom surface of the bottom plate part 14 between a pair of front casters 15a, 15c and a pair of rear casters 15b, 15d. Furthermore, a side frame part that restricts the horizontal movement of the item loaded on the dolly 11 may be provided on the top of the bottom plate part 14.

As shown in FIG. 1(a), the towing vehicle 12 includes a substantially rectangular parallelepiped body 16, a pair of left and right front wheels 17 (one of which is not shown) provided on the front bottom side of the body 16, a pair of left and right rear wheels 18 (one of which is not shown) provided on the rear bottom side of the body 16, a speaker 19 provided on the body 16, a forward detection sensor 21 provided on the front upper part of the body 16, and a front bumper 22 provided on the front lower part of the body 16. The towing vehicle 12 also includes a rear wheel drive unit 23 and a towing side control device 30 inside the body 16.

The pair of rear wheels 18 are drive wheels, and the pair of front wheels 17 are driven wheels. Each of the left and right rear wheels 18 is provided with a motor (not shown) capable of forward and reverse rotation, and each of the pair of rear wheels 18 can be individually controlled for forward and reverse rotation. The towing side control device 30 uses the rear wheel drive unit 23 to control the rotation speed and direction of the pair of rear wheels 18, thereby controlling the steering of the towing vehicle 12.

The forward detection sensor 21 is an ultrasonic sensor that detects obstacles or workers (hereinafter referred to as "obstacles, etc." in this specification) that are present within a detection range set in front of the towing vehicle 12 (specifically, within a 1 m radius in front) without contact. Note that the sensor used as the forward detection sensor 21 is not limited to an ultrasonic sensor, and various sensors that can detect obstacles, etc. without contact, such as optical sensors, can be used.

When the towing vehicle 12 is traveling forward and an obstacle or the like is detected by the forward detection sensor 21, the traveling speed of the towing vehicle 12 is switched from a forward traveling speed (specifically, 15 cm per second) to a decelerated forward traveling speed (specifically, 7.5 cm per second). The speaker 19 can output an abnormality notification sound that notifies the operator that the towing device 10 is in an abnormal stop state, and a warning sound that notifies the operator that an obstacle or the like is detected by the forward detection sensor 21.

Figure 1(c) is a plan view of the towing vehicle 12 seen from above. As shown in Figure 1(c), the front bumper 22 extends along the vehicle body 16 from the front of the left side surface 16a of the vehicle body 16, through the front surface 16b of the vehicle body 16, to the front of the right side surface 16c of the vehicle body 16. When the towing vehicle 12 comes into contact with an obstacle or the like present in front of it (including the left front and right front), the front bumper 22 comes into contact with the obstacle or the like before the vehicle body 16 does, making it possible to soften the impact applied to the vehicle body 16. A front contact detection sensor 24 is connected to the front bumper 22, which detects when the front bumper 22 comes into contact with an obstacle or the like and is pushed.

Next, the coupling device 13 will be described. As shown in FIG. 1(a), the coupling device 13 has a connection part 25 fixed to the rear of the towing vehicle 12, and a swinging part 26 that is movable relative to the connection part 25. Details will be described later, but the swinging part 26 is provided with an engagement unit 27 for connecting the carriage 11, and a flow-stop carriage part 28 for facilitating linear forward or reverse travel of the towing device 10. FIG. 2 is a perspective view of the coupling device 13 as viewed from above, and FIG. 3 is a perspective view of the coupling device 13 as viewed from below.

As shown in FIG. 2, the connection portion 25 includes a rectangular plate-shaped fixed frame 41 that is fixed to the underside of the rear surface 16d (FIG. 1(c)) of the vehicle body 16, and a first connecting frame 42 that extends rearward from the rear plate surface 41a of the fixed frame 41. The fixed frame 41 and the first connecting frame 42 are made of metal and are integrally formed.

As shown in FIG. 3, the first connecting frame 42 includes an upper plate portion 43 and a lower frame portion 44 formed by protruding downward from the peripheral portion of the bottom surface 43a of the upper plate portion 43. As shown in FIG. 2, a rotating shaft 29 is fixed to the rear portion of the upper plate portion 43, and the swinging portion 26 is supported by the rotating shaft 29. The swinging portion 26 includes a metal second connecting frame 46 that is connected to the first connecting frame 42 via the rotating shaft 29. The second connecting frame 46 includes a lower plate portion 47 and an upper frame portion 48 that protrudes upward from the peripheral portion of the upper flat surface 47a of the lower plate portion 47.

4(a) is a plan view of the connection portion 25 seen from above, and FIG. 4(b) is a plan view of the second connecting frame 46 seen from above with various parts removed. Note that in FIG. 4(b), screw holes of various parts are omitted. As shown in FIG. 4(a), the upper plate portion 43 has a rectangular front plate portion 43b located on the front side (the towing vehicle 12 side) and a rear plate portion 43c located on the rear side (the bogie 11 side) of the front plate portion 43b. A first connecting hole 43d is provided on the rear side of the front plate portion 43b, through which the rotating shaft 29 (FIG. 3) can be inserted. The first connecting hole 43d is provided in the center of the width direction (left-right direction) of the upper plate portion 43. Also, as shown in FIG. 4(b), a second connecting hole 47b is provided on the front side of the lower plate portion 47, through which the rotating shaft 29 can be inserted. The second connection hole 47b is provided in the center of the width direction (left-right direction) of the lower plate portion 47. The first connection hole 43d and the second connection hole 47b are formed so that the diameters of these connection holes 43d, 47b are larger than the diameter of the rotation shaft 29.

The first connecting hole 43d and the second connecting hole 47b are connected to each other so that they are on the same axis, and when the front part of the second connecting frame 46 is disposed on the rear part of the first connecting frame 42 as shown in FIG. 2, the pivot shaft 29 is inserted through these connecting holes 43d and 47b. This allows the second connecting frame 46 to rotate around the pivot shaft 29, and the swinging part 26 to rotate around the pivot shaft 29. When the towing device 10 is used on a horizontal floor surface, the pivot shaft 29 extends vertically (in the height direction of the towing device 10), and the swinging part 26 can swing within a horizontal plane perpendicular to the pivot shaft 29. The swinging part 26 can swing left and right relative to the forward or backward direction of the towing device 10.

As shown in FIG. 3, the lower part of the rotating shaft 29 is fixed to the first connecting frame 42 from below the first connecting frame 42 by the lower shaft fixing member 45. This prevents the rotating shaft 29 from falling out of the connecting holes 43d and 47b. Also, as shown in FIG. 2, a disk-shaped stopper 49 is fixed to the upper part of the rotating shaft 29, and a coil spring 51 is present between the stopper 49 and the lower plate portion 47. The coil spring 51 is arranged so as to be on the same axis as the rotating shaft 29. The stopper 49 is larger than the outer circumference of the coil spring 51, and is fixed by a pin fastening so as not to come off the rotating shaft 29. This restricts the upward movement of the second connecting frame 46, and prevents the rotating shaft 29 from falling out of the second connecting hole 47b (FIG. 4(b)).

As shown in FIG. 3, a pair of connecting side casters 52a, 52b are provided on the bottom surface 47c of the lower plate portion 47. The connecting side casters 52a, 52b are wheels that can change direction freely. This allows the towing device 10 to have better steerability than when the connecting side casters 52a, 52b are fixed wheels. In addition, by providing the connecting side casters 52a, 52b, the swinging part 26 can be rotated around the rotating shaft 29 in a manner that follows the movement of the towing vehicle 12 while the towing vehicle 12 is traveling, and when the bogie 11 is connected to the towing device 10, it is possible to make the bogie 11 follow when the traveling direction of the towing device 10 is changed. The number of connecting side casters 52a, 52b provided on the bottom surface 47c of the lower plate portion 47 is arbitrary, and may be one or three or more.

Next, the configuration for restricting the rotation range of the swinging part 26 will be described. As shown in FIG. 4(a), the rear side plate part 43c of the upper side plate part 43 in the first connecting frame 42 tapers at a constant rate from the base to the tip from both the left and right sides so that a left inclined part 43e and a right inclined part 43f are generated, and the shape is symmetrical with respect to the center line in the front-rear direction. As shown in FIG. 3, the left inclined protrusion part 44a and the right inclined protrusion part 44b are provided as the lower frame part 44 of the rear side plate part 43c (FIG. 4(a)) by protruding downward from each of the left inclined part 43e and the right inclined part 43f. Also, as shown in FIG. 3, a pair of left and right rotation range restricting protrusions 53, 54 are provided by protruding downward from the bottom surface 47c of the lower side plate part 47 in the second connecting frame 46.

When the second connecting frame 46 rotates to the left around the pivot shaft 29, the left rotation range limiting protrusion 53 comes into contact with the left inclined protrusion 44a, preventing further rotation to the left. When the second connecting frame 46 rotates to the right around the pivot shaft 29, the right rotation range limiting protrusion 54 comes into contact with the right inclined protrusion 44b, preventing further rotation to the right. Based on the state in which the widthwise (left-right) center of the first connecting frame 42, the pivot shaft 29, and the widthwise center of the second connecting frame 46 are aligned in a straight line (hereinafter referred to as the "straight line state of the connecting device 13" in this specification), when the amount of leftward rotation of the second connecting frame 46 from the straight line state reaches the left side restriction angle (specifically, 30 degrees), the left side rotation range restriction protrusion 53 comes into contact with the left side inclined protrusion 44a, and when the amount of rightward rotation of the second connecting frame 46 from the straight line state reaches the right side restriction angle (specifically, 30 degrees), the right side rotation range restriction protrusion 54 comes into contact with the right side inclined protrusion 44b.

As shown in FIG. 2, the engagement unit 27 is provided on the other end (rear side) of the swinging part 26 opposite to the one end fixed to the pivot shaft 29. The engagement unit 27 includes a pair of left and right hooks 55, 56, a hook lifting device 57 for moving the hooks 55, 56 up and down, and a pair of left and right outer frames 61, 62 for protecting the hooks 55, 56 from the outside. The hooks 55, 56 and the outer frames 61, 62 are made of metal.

As shown in FIG. 3, the hooks 55, 56 are long plates extending in the front-rear direction, and include inner frame parts 63, 64 with one end fixed to the hook lifting device 57 and the other end located at a position protruding rearward from the second connecting frame 46, and engagement parts 65, 66 fixed to the protruding tip side of the inner frame parts 63, 64 and protruding upward. The left engagement part 65 is fixed to the outside (left side) of the left inner frame part 63 with a screw from the outside (left side) of the left engagement part 65, and the right engagement part 66 is fixed to the outside (right side) of the right inner frame part 64 with a screw from the outside (right side) of the right engagement part 66.

As shown in FIG. 2, the outer frames 61, 62 are formed in a generally L-shape. The outer frames 61, 62 have outer vertical portions 61a, 62a extending vertically, and outer horizontal portions 61b, 62b extending from the lower portions of the outer vertical portions 61a, 62a to a position rearward of the engagement portions 65, 66. The upper portion of the left outer vertical portion 61a is screwed to the left side surface of the upper frame portion 48 from the outside (left side) with a plate-shaped left spacer 58 in between, and the upper portion of the right outer vertical portion 62a is screwed to the right side surface of the upper frame portion 48 from the outside (right side) with a plate-shaped right spacer 59 in between.

The engagement parts 65, 66 are located rearward of the outer vertical parts 61a, 62a of the outer frames 61, 62. The engagement parts 65, 66 have a certain thickness in the horizontal direction, and the upper surfaces are shaped so that they gradually slope downward toward the rear. The engagement surfaces 65a, 66a of the engagement parts 65, 66 that face forward extend vertically. When engaging the trolley 11, these engagement surfaces 65a, 66a come into contact with the front frame part 14c (Fig. 1(b)) of the trolley 11 from behind.

3, the hook lifting device 57 is provided on the rear side of the bottom surface 47c of the lower plate portion 47 of the second connecting frame 46. The hook lifting device 57 includes a fixed portion 57a fixed to the second connecting frame 46 and a movable portion 57b connected to the fixed portion 57a so as to be movable up and down. The fixed portion 57a includes a fixed member 72 with an L-shaped cross section fixed to the bottom surface 47c of the lower plate portion 47, and a pair of left and right racks 73, 74 fixed to the rearward plate surface 72a of the fixed member 72 and extending in the vertical direction (height direction of the towing device 10). The movable portion 57b includes a lifting main body portion 75 having a substantially rectangular parallelepiped shape and a pair of movable members 76, 77 fixed to the front surface of the lifting main body portion 75 and movable up and down along the racks 73, 74. The inner frame portions 63, 64 of the hooks 55, 56 described above are integrally formed on the left and right sides of the lifting main body portion 75.

The racks 73 and 74 are provided with a plurality of teeth (not shown) arranged in the vertical direction. The movable members 76 and 77 are provided with a disk-shaped gear (not shown), and the gear is provided with a plurality of teeth (not shown) arranged in the circumferential direction so as to engage with the teeth of the racks 73 and 74. The lifting main body 75 houses the lifting drive unit 71 (see FIG. 5), and the lifting drive unit 71 is provided with a rotary motor (not shown) for rotating the gears of the movable members 76 and 77. By controlling the drive of the lifting drive unit 71 so that the rotary motor rotates forward, the gears of the movable members 76 and 77 can be rotated forward to move the movable part 57b including the movable members 76 and 77 upward along the racks 73 and 74. By controlling the drive of the lifting drive unit 71 so that the rotary motor rotates backward, the gears of the movable members 76 and 77 can be rotated backward to move the movable part 57b including the movable members 76 and 77 downward along the racks 73 and 74. The configuration of the hook lifting device 57 is not limited to a configuration that uses a combination of racks 73, 74 and gears, and can be any configuration that allows the movable part 57b to move vertically by controlling the drive of the lifting drive part 71.

The hook lifting device 57 can raise the hooks 55, 56 by moving the movable part 57b upward, and can lower the hooks 55, 56 by moving the movable part 57b downward. The state of the coupling device 13 shown in FIG. 2 is a raised state in which the hooks 55, 56 have risen to their upper ends. When the hooks 55, 56 are in this raised state, the upper ends of the engagement parts 65, 66 protrude above the upper ends of the outer horizontal parts 61b, 62b of the outer frames 61, 62, and become able to engage with the trolley 11.

4(c) is an explanatory diagram for explaining the state in which the hook 56 engages with the trolley 11. The lifting drive unit 71 is controlled to be in the first drive state, and the gears of the movable members 76, 77 rotate forward, causing the hooks 55, 56 to rise. Then, as shown by the solid line in FIG. 4(c), the engagement surface 66a of the right-side engagement unit 66 faces the rear surface of the front frame portion 14c of the trolley 11 at a rear position, and when the towing device 10 travels forward in this state, the engagement surface 66a of the right-side engagement unit 66 abuts against the front edge portion 14e of the right-side bottom plate through hole 14b of the trolley 11 from behind, and the right-side engagement unit 66 engages with the trolley 11. Similarly, although not shown in the figure, the engagement surface 65a of the left engagement part 65 also faces the rear surface of the front frame part 14c of the trolley 11 at a rear position, and when the towing device 10 moves forward in this state, the engagement surface 65a of the left engagement part 65 abuts against the front edge part 14d of the left bottom plate through hole 14a of the trolley 11 from behind, and the left engagement part 65 engages with the trolley 11.

The lifting drive unit 71 is controlled to the second drive state, and the gears of the movable members 76, 77 rotate in the reverse direction, causing the hooks 55, 56 to descend. In the descending state in which the hooks 55, 56 are lowered to their lower ends, as shown by the two-dot chain line in FIG. 4(c), the upper end of the right-side engagement unit 66 is positioned below the bottom plate 14 of the trolley 11, so that the right-side engagement unit 66 does not engage with the trolley 11. Similarly, although not shown, the upper end of the left-side engagement unit 65 is positioned below the bottom plate 14 of the trolley 11, so that the left-side engagement unit 65 does not engage with the trolley 11. The state of the coupling device 13 shown in FIG. 3 is the descending state in which the hooks 55, 56 are lowered to their lower ends. When the hooks 55, 56 are in this lowered state, the upper ends of the engagement parts 65, 66 are lower than the upper ends of the outer horizontal parts 61b, 62b, and the hooks 55, 56 are guarded by the outer frames 61, 62 to prevent them from coming into contact with obstacles, etc.

As shown in FIG. 3, a bogie detection device 81 is provided on the bottom surface 47c of the lower plate portion 47 of the second connecting frame 46, behind the hook lifting device 57. The bogie detection device 81 includes a bogie detection main body portion 81a, a bogie detection pivot shaft 81b along the vertical direction (height direction of the towing device 10), and a bogie contact portion 81c that can rotate around the bogie detection pivot shaft 81b. A bogie detection sensor 82 (see FIG. 5) is housed in the bogie detection main body portion 81a. The rear portion of the bogie contact portion 81c protrudes rearward beyond the rear end of the second connecting frame 46 and can come into contact with the bogie 11. The bogie contact portion 81c comes into contact with the bogie 11 and rotates around the bogie detection pivot shaft 81b, allowing the bogie detection sensor 82 to detect the bogie 11.

As shown in FIG. 3, the flow-stopping trolley section 28 includes a pair of left and right flow-stopping frames 83, 84, a wheel fixing frame 85, and a pair of left and right flow-stopping side wheels 86, 87. The flow-stopping frames 83, 84 and the wheel fixing frame 85 are made of metal.

As shown in FIG. 2, the left flow stopper frame 83 is fixed to the left outer horizontal portion 61b rearward of the left engaging portion 65 and extends rearward, while the right flow stopper frame 84 is fixed to the right outer horizontal portion 62b rearward of the right engaging portion 66 and extends rearward. A rectangular plate-shaped wheel fixing frame 85 is fixed to the rear of the flow stopper frames 83 and 84. As shown in FIG. 3, flow stopper side wheels 86 and 87 are fixed to the bottom surface of the wheel fixing frame 85. The flow stopper side wheels 86 and 87 are fixed wheels whose orientation is set in the front-rear direction and whose orientation cannot be changed. This makes it easier to move the towing device 10 forward or backward in a straight line compared to a configuration in which the flow stopper side wheels 86 and 87 are wheels whose orientation can be freely changed.

As already explained, the coupling device 13 is in a straight line state when the widthwise (left-right) center of the first connecting frame 42, the pivot shaft 29, and the widthwise center of the second connecting frame 46 are aligned in a straight line. Hereinafter, in this specification, the state in which the widthwise (left-right) center of the towing vehicle 12, the pivot shaft 29, and the widthwise center of the second connecting frame 46 are aligned in a straight line is referred to as the "straight line state of the towing device 10" (see FIG. 6(b)). When the coupling device 13 is fixed to the towing vehicle 12, the coupling device 13 is in a straight line state, and the towing device 10 is in a straight line state.

As shown in FIG. 2, a linear locking device 88 that can maintain the linear state of the coupling device 13 is provided behind the rotating shaft 29 (on the bogie 11 side). The linear locking device 88 includes a hollow cylindrical cylinder portion 88a extending upward from the upper flat surface 47a of the lower plate portion 47, a movable rod 88b (see FIG. 3) that is disposed inside the cylinder portion 88a and extends vertically, and a fixing body portion 88c. A columnar first support member 91 is provided behind the linear locking device 88, standing upward from the upper flat surface 47a of the lower plate portion 47, and the upper portion of the fixing body portion 88c is fixed to the first support member 91. The fixing body portion 88c is provided above the cylinder portion 88a, and the fixing body portion 88c houses a fixing drive portion 89 (see FIG. 5) for moving the movable rod 88b up and down inside the cylinder portion 88a.

As shown in FIG. 4(b), the lower plate portion 47 of the second connecting frame 46 is provided below the cylinder portion 88a (FIG. 3) with a second locking through-hole 47d through which the lower portion of the movable rod 88b can be inserted. The second locking through-hole 47d is provided in the center of the width direction (left-right direction) of the lower plate portion 47. The second locking through-hole 47d is larger than the outer circumference of the movable rod 88b and exists on the same axis as the movable rod 88b. Also, as shown in FIG. 4(a), the rear plate portion 43c of the upper plate portion 43 of the first connecting frame 42 is provided with a first locking through-hole 43g. The first locking through-hole 43g is provided in the center of the width direction (left-right direction) of the upper plate portion 43. When the connecting device 13 is in a straight state, the first locking through-hole 43g, the second locking through-hole 47d, and the movable rod 88b exist on the same axis.

The movable rod 88b moves downward when the fixing drive unit 89 is switched from a non-driven state to a driven state, and moves upward due to the restoring force of the biasing means (not shown) when the fixing drive unit 89 is switched from a driven state to a non-driven state. When the fixing drive unit 89 is in a non-driven state, the lower end of the movable rod 88b is inserted into the second locking through hole 47d, that is, the lower end of the movable rod 88b is at a height position between the upper flat surface 47a (FIG. 2) and the bottom surface 47c (FIG. 3) of the lower plate portion 47. When the connecting device 13 is in a straight state, the fixing drive unit 89 is switched from a non-driven state to a driven state, so that the movable rod 88b is inserted into the first locking through hole 43g and the second locking through hole 47d, and the rotation of the second connecting frame 46 around the rotation axis 29 is restricted, resulting in a straight lock state in which the straight state of the connecting device 13 is maintained. In addition, when the fixing drive unit 89 is switched from a driven state to a non-driven state in the linear lock state, the lower end of the movable rod 88b comes out of the first lock through hole 43g and enters the second lock through hole 47d, and the linear lock state is released.

The first locking through hole 43g is formed to be one size larger than the second locking through hole 47d. This reduces the possibility that the movable rod 88b will come into contact with the edge of the second locking through hole 47d when the fixing drive unit 89 is in the driving state and the movable rod 88b moves downward. Even in the linear lock state, the second connecting frame 46 is allowed to rotate slightly left and right with respect to the backward movement direction of the towing device 10. The slight left and right rotation of the second connecting frame 46 provides play that allows the swinging part 26, which comes into contact with the cart 11 when connecting the cart 11 to the coupling device 13, to rotate slightly left and right. The first locking through hole 43g may be larger than the outer circumference of the movable rod 88b and may be the same size as the second locking through hole 47d.

As shown in FIG. 2, a plate-shaped sensor fixing member 92 is attached to the cylinder portion 88a, and a linear detection sensor 93 is fixed to the plate surface on one side (the right side) of the sensor fixing member 92. The linear detection sensor 93 has a light-emitting portion (not shown) that emits light downward, and a light-receiving portion (not shown) that receives the light that is reflected back after being emitted.

As shown in FIG. 4(a), a reflector 94 used to detect the linear state of the connecting device 13 is provided on the upper plate 43. The reflector 94 is disposed near the first lock through-hole 43g. Also, as shown in FIG. 4(b), a linear detection through-hole 47e is formed on the lower plate 47. When the connecting device 13 is in a linear state, the linear detection through-hole 47e faces the reflector 94 (FIG. 4(a)) provided on the first connecting frame 42 from above. In this state, the light emitted from the light-emitting portion of the linear detection sensor 93 (FIG. 2) passes through the linear detection through-hole 47e and reaches the reflector 94. Then, the light is reflected by the reflector 94 and passes through the linear detection through-hole 47e to reach the light-receiving portion of the linear detection sensor 93. On the other hand, when the connecting device 13 is not in a straight line, the light emitted from the light projecting portion of the straight line detection sensor 93 hits the lower plate portion 47, is scattered, and does not reach the light receiving portion. This makes it possible for the straight line detection sensor 93 to detect the straight line state of the connecting device 13.

As shown in FIG. 2, a connecting side bumper device 95 is provided above the rear of the second connecting frame 46. The connecting side bumper device 95 includes a bumper main body 96. The bumper main body 96 extends in the width direction (left-right direction) of the second connecting frame 46. A left side surface 96a (FIG. 3) of the bumper main body 96 protrudes leftward beyond the left end of the second connecting frame 46, and a right side surface 96b of the bumper main body 96 protrudes rightward beyond the right end of the second connecting frame 46.

As shown by the dashed line in Figure 2, a left connecting side contact detection sensor 97 (see Figure 5) is housed in the left part of the bumper main body 96, and a right connecting side contact detection sensor 98 (see Figure 5) is housed in the right part of the bumper main body 96. A rod-shaped left bumper contact portion 99 is connected to the left connecting side contact detection sensor 97, and a rod-shaped right bumper contact portion 101 is connected to the right connecting side contact detection sensor 98. A left bumper through hole 96c (Figure 3) is formed in the left side surface 96a of the bumper main body 96, through which the left bumper contact portion 99 can be inserted, and the left bumper contact portion 99 protrudes leftward from the left side surface 96a of the bumper main body 96 through the left bumper through hole 96c. In addition, a right side bumper through hole 96d is formed on the right side surface 96b of the bumper body 96, through which the right side bumper contact portion 101 can be inserted, and the right side bumper contact portion 101 protrudes to the right from the right side surface 96b of the bumper body 96 through the right side bumper through hole 96d.

The left bumper contact portion 99 has a left straight portion 99a extending leftward from the left side surface 96a of the bumper body portion 96, and a left curved portion 99b continuing from the left end of the left straight portion 99a and curving backward toward the left. The right bumper contact portion 101 has a right straight portion 101a extending rightward from the right side surface 96b of the bumper body portion 96, and a right curved portion 101b continuing from the right end of the right straight portion 101a and curving backward toward the right. This makes it possible to position the bumper contact portions 99, 101 in a position that does not contact the trolley 11. The connecting side contact detection sensors 97, 98 detect the deformation of the bumper contact portions 99, 101 to detect that the bumper contact portions 99, 101 have come into contact with an obstacle or the like.

As shown in FIG. 2, the coupling side control device 110 is provided behind the first support member 91 (on the bogie 11 side). The coupling side control device 110 has a case body 111. The second support member 102 is provided below the case body 111, standing upward from the upper flat surface 47a of the lower plate portion 47. The lower part of the case body 111 is fixed to the upper part of the second support member 102, and the upper part of the case body 111 is fixed to the upper part of the first support member 91. A coupling side control antenna 113 is provided protruding upward from the upper part of the case body 111 to enable wireless communication (specifically, communication between the coupling side control device 110 and the towing side control device 30). A coupling side control board 112 (see FIG. 5) is housed inside the case body 111.

In the towing device 10 configured as described above, the second connecting frame 46 is fixed so as to be rotatable, which allows for good steering when the towing device 10 is turned while towing the carriage 11. In addition, the rotation range of the second connecting frame 46 is restricted by the rotation range restricting protrusions 53, 54, which reduces the possibility of the carriage 11 coming into contact with an obstacle or the like during turning.

By providing the forward detection sensor 21, the traveling speed of the towing vehicle 12 can be reduced if an obstacle or the like is detected in front of the towing device 10. This reduces the possibility of the towing vehicle 12 coming into contact with an obstacle or the like. In addition, by providing the front bumper 22, it is possible to detect contact when the front of the towing vehicle 12 comes into contact with an obstacle or the like, and it becomes possible to bring the towing vehicle 12 to an emergency stop in response to contact with an obstacle or the like.

Figure 5 is a block diagram showing the electrical configuration of the towing device 10.

The towing vehicle 12 is equipped with a towing side control device 30 that controls the towing vehicle 12. The towing side control device 30 is equipped with a towing side control board 31. The towing side control board 31 is equipped with a towing side CPU 32, a towing side ROM 33 that stores various control programs and fixed value data executed by the towing side CPU 32, and a towing side RAM 34 that is a memory for temporarily storing various data when the control programs stored in the towing side ROM 33 are executed.

The towing side control board 31 is provided with an input port and an output port (not shown). The input side of the towing side control device 30 is connected to the forward detection sensor 21 and the front contact detection sensor 24. The output side of the towing side control device 30 is connected to the speaker 19 and the rear wheel drive unit 23. The operating power of the towing side control device 30 and the rear wheel drive unit 23 is supplied from a towing side power supply unit (not shown) provided inside the towing vehicle 12.

The towing side control device 30 is provided with a towing side communication unit (not shown) that enables data (including various signals) to be transmitted and received between the towing side control device 30 and the coupling side control device 110, and the coupling side control device 110 is provided with a coupling side communication unit (not shown) that enables data (including various signals) to be transmitted and received between the towing side control device 30 and the coupling side control device 110. Communication between the towing side control device 30 and the coupling side control device 110 is performed wirelessly. The towing side communication unit can receive data (delivery destination data and return destination data, described later) transmitted wirelessly to the towing side control device 30 based on the operation of a smartphone, tablet terminal, or laptop computer on which a towing vehicle management app for managing the towing vehicle 12 is installed. In addition, the coupling side communication unit can receive data (connection instruction signal, described later) transmitted wirelessly to the coupling side control device 110 based on the operation of a smartphone, tablet terminal, or laptop computer on which a coupling device management app for managing the coupling device 13 is installed. Note that communication between the towing side control device 30 and the coupling side control device 110 may be performed by wire.

The coupling device 13 is equipped with a coupling side control device 110 that controls the towing vehicle 12 and the coupling device 13. The coupling side control device 110 is equipped with a coupling side control board 112. The coupling side control board 112 is equipped with a coupling side CPU 114, a coupling side ROM 115 that stores various control programs and fixed value data executed by the coupling side CPU 114, and a coupling side RAM 116 that is a memory for temporarily storing various data, etc. when the control programs stored in the coupling side ROM 115 are executed.

The coupling side control board 112 is provided with an input port and an output port (not shown). The input side of the coupling side control device 110 is connected to the cart detection sensor 82, the linear detection sensor 93, and the coupling side contact detection sensors 97, 98. The output side of the coupling side control device 110 is connected to the lifting drive unit 71 of the hook lifting device 57 and the fixing drive unit 89 of the linear locking device 88. The operating power of the coupling side control device 110, the operating power of the hook lifting device 57, and the operating power of the linear locking device 88 are supplied from a coupling side power supply unit (not shown) built into the coupling side control device 110.

Before describing the various processes executed by the towing side CPU 32, we will next describe the bogie connection operation performed to connect the bogie 11 to the towing device 10.

6(a) to 6(c) are explanatory diagrams for explaining the bogie connection operation. The bogie connection operation is started in a state where the linear lock is released and the hooks 55, 56 are lowered to the bottom end. As shown in FIG. 6(a), the operator performs the operation to start the bogie connection operation after the rear part of the towing vehicle 12 is substantially directly facing the front part of the bogie 11. The operator wirelessly transmits a connection instruction signal to the coupling side control device 110 by operating a smartphone or the like on which the above-mentioned coupling device management application is installed. Note that the connection instruction signal may be transmitted to the coupling side control device 110 based on the operation of a controller capable of transmitting a connection instruction signal to the coupling side control device 110 by wire or wirelessly, or the connection instruction signal may be input to the coupling side control device 110 by operating an operation button or an operation screen provided on the coupling device 13 or the towing vehicle 12.

When the operation to start the cart connection operation is performed, a process is executed to make the towing vehicle 12 travel forward. As already explained, since the second connecting frame 46 is provided with the connecting side casters 52a, 52b (see FIG. 3), when the towing vehicle 12 starts traveling forward in a situation where the second connecting frame 46 is rotated to the right from the straight state of the coupling device 13, the rotating shaft 29 moves forward during the forward traveling, causing the second connecting frame 46 to rotate to the left and approach the straight state of the coupling device 13. Also, although not shown, when the towing vehicle 12 starts traveling forward in a situation where the second connecting frame 46 is rotated to the left from the straight state of the coupling device 13, the rotating shaft 29 moves forward during the forward traveling, causing the second connecting frame 46 to rotate to the right and approach the straight state of the coupling device 13.

After that, as shown in FIG. 6(b), when the straight line detection sensor 93 detects that the coupling device 13 is in a straight line state, the fixing drive unit 89 of the straight line locking device 88 is driven to set the coupling device 13 in a straight line lock state. This prevents the swinging unit 26 from swinging left and right when the towing device 10 is traveling backward toward the bogie 11. By performing straight line locking based on the detection of the straight line state of the coupling device 13 by the straight line detection sensor 93, it is possible to prevent the coupling device 13 from not maintaining a straight line state despite the straight line lock operation. The towing device 10 starts traveling forward with the rear of the towing device 10 approximately facing the front of the bogie 11, and the towing device 10 is set in a straight line state, so that the towing vehicle 12, the rotating shaft 29, and the bogie 11 are aligned in a line.

After that, a process is executed to cause the towing device 10 to travel backwards toward the bogie 11 until the bogie contact portion 81c comes into contact with the bogie 11 and the bogie 11 is detected by the bogie detection sensor 82. When the towing device 10 is traveling backwards toward the bogie 11, the bogie detection sensor 82 detects the bogie 11, and the coupling side control device 110 can determine that the hooks 55, 56 are ready to engage with the bogie 11.

After the dolly 11 is detected by the dolly detection sensor 82, the drive control of the lifting drive unit 71 in the hook lifting device 57 is performed so that the hooks 55, 56 are raised to the upper end, and as shown in FIG. 6(c), the left engaging part 65 can be engaged with the front edge 14d of the left bottom plate through hole 14a in the bottom plate part 14, and the right engaging part 66 can be engaged with the front edge 14e of the right bottom plate through hole 14b in the bottom plate part 14. Since the hooks 55, 56 are raised while the linear lock of the connecting device 13 is performed, it is possible to prevent a state in which only one of the left and right engaging parts 65, 66 is engaged with the front edge parts 14d, 14d, or a state in which both the left and right engaging parts 65, 66 are not normally engaged with the front edge parts 14d, 14d.

When the bogie 11 is towed by the towing device 10, the free end of the left bumper contact portion 99 protrudes leftward from the left end of the towing vehicle 12 and the left end of the bogie 11, and the free end of the right bumper contact portion 101 protrudes rightward from the right end of the towing vehicle 12 and the right end of the bogie 11. By providing the connecting side bumper device 95, if the bumper contact portions 99, 101 come into contact with an obstacle or the like when the towing device 10 is moving backward toward the bogie 11, the contact can be detected, and the detection of the contact can be used as a trigger to abnormally stop the towing vehicle 12. In addition, if an obstacle or the like gets between the towing vehicle 12 and the bogie 11 and comes into contact with the bumper contact portions 99, 101 when the towing device 10 is turning while towing the bogie 11, the contact can be detected, and the detection of the contact can be used as a trigger to abnormally stop the towing vehicle 12.

Next, the driving control process executed by the towing side CPU 32 will be described with reference to the flowchart in FIG. 7. The driving control process is executed after the supply of operating power to the towing side control device 30 starts.

First, the transport setting process is executed (step S101). The worker wirelessly transmits the transport destination data and the return destination data to the towing side control device 30 by operating a smartphone or the like on which the towing vehicle management application described above is installed. In the transport setting process (step S101), when the transport destination data and the return destination data are received, a process is executed to set the transport destination designation information and the return destination designation information after the transport is completed in the towing side RAM 34 based on the received data. Note that the transport destination data and the return destination data may be transmitted to the towing side control device 30 by the worker operating a controller capable of transmitting data to the towing side control device 30 by wire or wirelessly, or the transport destination data and the return destination data may be input to the towing side control device 30 by the worker operating an operation button or an operation screen provided on the towing vehicle 12.

Then, it is determined whether or not a connection start signal has been received from the coupling side CPU 114 (step S102). The connection start signal is transmitted when the coupling side CPU 114 receives a connection instruction signal transmitted based on an operation of a smartphone or the like on which the above-mentioned coupling device management app is installed (the above-mentioned operation to start the trolley connection operation). The towing device 10 is positioned in front of the trolley 11 by the worker. The worker performs the operation to start the trolley connection operation after the rear of the towing vehicle 12 is approximately directly facing the front of the trolley 11.

If the connection start signal has not been received (step S102: NO), the determination process of step S102 is repeated. Then, if the connection start signal has been received (step S102: YES), a connection operation in progress process is executed (step S103). In the connection operation in progress process, a process for performing a cart connection operation is executed while communicating with the connecting side CPU 114. The connection operation in progress process will be described in detail later.

Then, the in-transport process is executed (step S104). In the in-transport process, a process is executed to control the travel of the towing vehicle 12 so that the towing device 10 reaches the destination while towing the cart 11 based on the destination designation information set in the transport setting process (step S101). The in-transport process ends when the towing device 10 arrives at the destination. The towing device 10 automatically travels to the destination according to a program preset in the towing side ROM 33. Note that the towing device 10 may be configured to travel along rails installed on the floor surface, or may be configured to travel while detecting indicators installed in facilities such as factories and warehouses.

After the in-transport process (step S104) is executed, the transport end process is executed (step S105). In the transport end process, a hook lowering signal is sent to the connecting side CPU 114. When the connecting side CPU 114 receives the hook lowering signal, it controls the drive of the hook lifting device 57 so that the hooks 55 and 56 are lowered. This allows the cart 11 to be separated from the towing device 10 at the transport destination.

After that, a return travel process is executed (step S106). In the return travel process, a process is executed to control the travel of the towing vehicle 12 so that the towing device 10 reaches the return destination based on the return destination designation information set in the transport setting process (step S101). After that, a return travel end process is executed (step S107). In the return travel end process, a process is executed to clear the transport destination information and the return destination information. Then, the process proceeds to step S101.

Next, the abnormality response process executed by the towing side CPU 32 will be described with reference to the flowchart in FIG. 8. The abnormality response process is executed in an interrupt process that is periodically started, for example, at a cycle of 4 milliseconds, while the above-mentioned driving control process (FIG. 7) is being executed.

First, it is determined whether the abnormal stop flag 34a (see FIG. 5) provided in the towing side RAM 34 is set to "1" (step S201). The abnormal stop flag 34a is a flag that enables the towing side CPU 32 to grasp that the towing device 10 is in an abnormal stop state based on the front contact detection sensor 24 detecting contact with an obstacle or the like, or the receipt of an abnormality occurrence signal described below from the coupling side CPU 114. If the abnormal stop flag 34a is set to "1" (step S201: YES), abnormal stop processing is executed (step S202).

In the abnormal stop processing (step S202), it is determined whether or not an abnormality reset operation has been performed by operating an abnormality reset button (not shown) provided on the body 16 of the towing vehicle 12. If an abnormality reset operation has been performed, the output of the abnormality alarm sound output from the speaker 19 during the abnormal stop state is stopped, and an abnormality reset signal is sent to the coupling side CPU 114. The output of the abnormality alarm sound is started by executing an abnormal stop start process in step S208, which will be described later. The abnormality reset signal is a signal that allows the coupling side CPU 114 to know that the abnormal stop state has been released. After the abnormality reset signal has been sent, the abnormal stop flag 34a is cleared to "0". This results in a state in which a positive determination is not made in step S201, and the abnormal stop state is released.

If the abnormal stop flag 34a is not set to "1" (step S201: NO), it is determined whether the forward travel flag 34b (see FIG. 5) provided in the towing side RAM 34 is set to "1" (step S203). The forward travel flag 34b is a flag that allows the towing side CPU 32 to know that the towing vehicle 12 is traveling forward. The forward travel flag 34b is set to "1" when the towing vehicle 12 starts traveling forward.

If the towing vehicle 12 is traveling forward (step S203: YES), it is determined whether or not the forward detection sensor 21 is detecting an obstacle (step S204), and if an obstacle is being detected (step S204: YES), a deceleration forward travel process is executed (step S205). In the deceleration forward travel process, the traveling speed of the towing vehicle 12 is set to a deceleration travel speed (specifically, 7.5 cm per second), and a warning sound is output from the speaker 19 to notify that an obstacle is being detected by the forward detection sensor 21. This makes it possible to notify surrounding workers that there is an obstacle in front of the towing vehicle 12 or that a worker is in front of the towing vehicle 12. The output of the warning sound ends when the forward detection sensor 21 is no longer detecting an obstacle. In addition, in the deceleration forward travel process (step S205), a deceleration travel signal is sent to the coupling side CPU 114. The deceleration signal is a signal that allows the connection side CPU 114 to know that the vehicle is decelerating.

In this way, if an obstacle or the like is detected by the forward detection sensor 21 while traveling forward, the vehicle will decelerate and a warning sound will be output. This provides an opportunity to remove the obstacle before the towing device 10 comes into contact with it, or to provide an opportunity for an operator in front of the towing device 10 to take action to avoid the towing device 10, thereby reducing the possibility of the towing device 10 coming into contact with an obstacle or the like. In addition, compared to a configuration in which the towing device 10 immediately makes an abnormal stop when an obstacle or the like is detected by the forward detection sensor 21, the frequency with which the towing device 10 makes an abnormal stop can be reduced.

The abnormality response process (Figure 8) is a process that is executed in all of the following situations: when the trolley connection operation is being performed, when the towing device 10 is towing the trolley 11 to the destination, and when the towing device 10 is traveling to the return destination. Therefore, in all of these situations, if the forward detection sensor 21 detects an obstacle or the like while the towing device 10 is traveling forward, the towing device 10 can switch to decelerated forward traveling and output an alarm sound.

When a negative judgment is made in step S203, when a negative judgment is made in step S204, or when the process of step S205 is performed, it is judged whether or not contact with an obstacle or the like is detected by the front contact detection sensor 24 (step S206). Also, when contact with an obstacle or the like is not detected by the front contact detection sensor 24 (step S206: NO), it is judged whether or not an abnormality occurrence signal is received from the coupling side CPU 114 (step S207). The abnormality occurrence signal is transmitted from the coupling side CPU 114 when contact with an obstacle or the like is detected by the coupling side contact detection sensors 97, 98, when the linear state of the coupling device 13 is not detected by the linear detection sensor 93 even if the vehicle moves forward by a predetermined forward reference distance (specifically, 50 cm) or more in the vehicle connection operation, or when the vehicle detection sensor 82 does not detect the vehicle 11 even if the vehicle moves backward by a predetermined backward reference distance (specifically, 100 cm) or more in the vehicle connection operation.

If an obstacle or the like is detected by the front contact detection sensor 24 (step S206: YES), or if an abnormality occurrence signal is received (step S207: YES), an abnormality stop start process is executed (step S208). In the abnormality stop start process, the towing vehicle 12 is stopped from traveling, and the speaker 19 is caused to start outputting an abnormality stop warning sound. This makes it possible to notify the operator that the towing device 10 is in an abnormal stop state.

Then, an abnormal stop signal is sent to the coupling side CPU 114 (step S209). The abnormal stop signal is a signal that enables the coupling side CPU 114 to recognize that an abnormal stop state has begun. Then, the abnormal stop flag 34a in the towing side RAM 34 is set to "1" (step S210). As a result, a positive determination is made in step S201, and the abnormal stop processing (step S202) is executed.

The abnormality response process (Figure 8) is executed in all of the following situations: when the cart connection operation is being performed, when the towing device 10 is towing the cart 11 to the destination, and when the towing device 10 is traveling to the return destination. Therefore, in all of these situations, the towing device 10 can be switched to an abnormal stop state and an abnormal stop warning sound can be output based on the front contact detection sensor 24 detecting an obstacle or the like, or the reception of an abnormality occurrence signal from the connection side CPU 114.

Next, the connection operation processing executed by the towing side CPU 32 will be described with reference to the flowchart in FIG. 9. As already explained, the connection operation processing is executed in step S103 of the driving control processing (FIG. 7).

First, a forward travel start process is executed (step S301). In the forward travel start process, the towing vehicle 12 is caused to start traveling forward. Then, the forward travel flag 34b in the towing side RAM 34 is set to "1" (step S302). This allows the towing side CPU 32 to recognize that forward travel is in progress. Then, a forward connection signal is transmitted to the coupling side CPU 114 (step S303). The forward connection signal is a signal that allows the coupling side CPU 114 to recognize that the towing vehicle 12 is traveling forward during the bogie connection operation.

Then, it is determined whether or not a straight line lock start signal has been received from the coupling side CPU 114 (step S304). The straight line lock start signal is a signal that is transmitted when the coupling side CPU 114 executes processing to start straight line locking of the coupling device 13. If the straight line lock start signal has not been received (step S304: NO), the determination processing of step S304 is repeated. Then, if the straight line lock start signal has been received (step S304: YES), forward travel stop processing is executed (step S305). In the forward travel stop processing, the forward travel of the towing vehicle 12 is stopped. Then, the forward travel flag 34b of the towing side RAM 34 is cleared to "0" (step S306).

Then, it is determined whether or not a straight lock end signal has been received from the coupling side CPU 114 (step S307). The straight lock end signal is transmitted when a lock waiting period (specifically, one second) has elapsed after the coupling side CPU 114 has executed a process to start the straight lock of the coupling device 13. If the straight lock end signal has not been received (step S307: NO), the determination process of step S307 is repeated. Then, if the straight lock end signal has been received (step S307: YES), a reverse travel start process is executed (step S308). In the reverse travel start process, a process is executed to start reverse travel of the towing vehicle 12 at a predetermined speed (specifically, 15 cm per second).

In this way, by configuring the vehicle not to start reverse running until the lock wait period has elapsed, reverse running can be started after the straight lock operation has ended and the straight state of the coupling device 13 has been fixed. This makes it possible to prevent reverse running from starting in the middle of the straight lock operation.

Then, it is determined whether or not a bogie detection signal has been received from the coupling side CPU 114 (step S309). The bogie detection signal is transmitted when the bogie 11 is detected by the bogie detection sensor 82. If a bogie detection signal has not been received (step S309: NO), the determination process of step S309 is repeated. Then, if a bogie detection signal has been received (step S309: YES), a reverse travel stop process is executed (step S310). In the reverse travel stop process, a process is executed to stop the reverse travel of the towing vehicle 12.

Then, it is determined whether or not a hook lift end signal has been received from the connecting side CPU 114 (step S311). The hook lift end signal is transmitted when the lift wait period (specifically, 2 seconds) has ended after the connecting side CPU 114 has executed a process to start the lift operation of the hooks 55, 56. If the hook lift end signal has not been received (step S311: NO), the determination process of step S311 is repeated. Then, if the hook lift end signal has been received (step S311: YES), this connection operation in progress process is terminated. As already explained, in the travel control process (FIG. 7), the transport in progress process (step S104) is executed after the connection operation in progress process (step S103) is terminated.

In this way, by configuring the system so that the in-transport process (step S104) is not started until the waiting period for lifting has elapsed, the lifting operation of the hooks 55 and 56 is completed, and the transport travel can be started when the connection of the cart 11 to the coupling device 13 is completed. This makes it possible to prevent the transport travel from starting in the middle of the lifting operation of the hooks 55 and 56.

Next, the connection side process executed by the connection side CPU 114 will be described with reference to the flowchart in FIG. 10. The connection side process is executed periodically, for example, at a cycle of 4 milliseconds.

First, it is determined whether an abnormal stop signal has been received from the towing side CPU 32 (step S401). As already explained, the abnormal stop signal is transmitted from the towing side CPU 32 when an abnormal stop state is initiated. If an abnormal stop signal has been received (step S401: YES), the abnormal stop flag 116a (see FIG. 5) provided in the coupling side RAM 116 is set to "1" (step S402). The abnormal stop flag 116a is a flag that allows the coupling side CPU 114 to grasp that an abnormal stop state is occurring.

If an abnormal stop signal has not been received (step S401: NO), it is determined whether the abnormal stop flag 116a is set to "1" (step S403), and if the abnormal stop flag 116a is set to "1" (step S403: YES), it is determined whether an abnormality release signal has been received from the towing side CPU 32 (step S404). As already explained, the abnormality release signal is transmitted from the towing side CPU 32 when the abnormal stop state is to be ended. If an abnormality release signal has been received (step S404: YES), the abnormality stop flag 116a is cleared to "0" (step S405).

If the abnormal stop flag 116a is not set to "1" (step S403: NO), it is determined whether or not the connecting side contact detection sensors 97, 98 have detected contact with an obstacle or the like (step S406). If the connecting side contact detection sensors 97, 98 have detected contact with an obstacle or the like (step S406: YES), an abnormality occurrence process is executed (step S407). In the abnormality occurrence process, an abnormality occurrence signal is sent to the towing side CPU 32. This allows the towing device 10 to be in an abnormal stop state. In addition, in the abnormality occurrence process (step S407), a process is performed to switch the fixing drive unit 89 to a non-driven state. This starts the upward movement of the movable rod 88b. When the lower end of the movable rod 88b passes through the first lock through hole 43g and is in the second lock through hole 47d, the linear lock state of the connecting device 13 is released, and the second connecting frame 46 becomes rotatable.

When the towing device 10 is traveling backward during the bogie connection operation, if the coupling side contact detection sensors 97, 98 detect contact with an obstacle or the like, an abnormality occurrence process is executed and the straight lock state of the coupling device 13 is released. The operator can remove the obstacle or the like without performing any operation to release the straight lock state, correct the position of the towing device 10 so that the rear of the towing vehicle 12 is approximately directly facing the front of the bogie 11, and then start the bogie connection operation again.

If no obstacle or the like is detected by the coupling side contact detection sensors 97, 98 (step S406: NO), it is determined whether or not a connection instruction signal has been received from an operation terminal such as a tablet operated by the worker (step S408), and if a connection instruction signal has been received (step S408: YES), a connection start signal is sent to the towing side CPU 32 (step S409). This allows the towing side CPU 32 to execute the connection operation in progress process (step S103).

If a negative determination is made in step S408, it is determined whether or not a forward connection signal has been received from the towing side CPU 32 (step S410). If a forward connection signal has been received (step S410: YES), the forward connection flag 116b (see FIG. 5) provided in the connecting side RAM 116 is set to "1" and the distance counter 116c provided in the connecting side RAM 116 is cleared to "0" (step S411). The forward connection flag 116b is a flag that allows the connecting side CPU 114 to grasp that the towing device 10 is traveling forward in the bogie connection operation. The distance counter 116c is a counter that allows the connecting side CPU 114 to grasp the forward distance or reverse distance in the bogie connection operation. By clearing the distance counter 116c to "0" in step S411, it is possible to start measuring the forward distance in the bogie connection operation.

If a negative determination is made in step S410, it is determined whether the forward movement flag for connection 116b is set to "1" (step S412), and if the forward movement flag for connection 116b is set to "1" (step S412: YES), a forward movement process for connection is executed (step S413). Figure 11(a) is a flowchart showing the forward movement process for connection.

In the forward movement process for connection, if the straight line detection sensor 93 detects that the coupling device 13 is in a straight line state (step S501: YES), the straight line lock start process is executed (step S502). In the straight line lock start process, the drive control of the fixing drive unit 89 is performed so that the movable rod 88b descends. Then, a lock wait time (specifically, 1 second) is set in a timer circuit (not shown) provided on the coupling side control board 112 (step S503). The numerical information set in the timer circuit is periodically updated, and when the set lock wait period has elapsed, the timer circuit is set to "0". By setting the lock wait period in the timer circuit in step S503, measurement of the lock wait period is started. Then, a straight line lock start signal is sent to the towing side CPU 32 (step S504). This allows the towing side CPU 32 to execute the forward travel stop process (step S305).

Then, the forward connection flag 116b in the connection side RAM 116 is cleared to "0," and the lock wait flag 116d (see FIG. 5) provided in the connection side RAM 116 is set to "1" (step S505). By clearing the forward connection flag 116b to "0," the connection side CPU 114 can determine that forward travel has ended. The lock wait flag 116d is a flag that allows the connection side CPU 114 to determine that the lock wait period is in progress.

If a negative determination is made in step S501, a forward distance update process is executed (step S506). In the forward distance update process, if the vehicle is traveling forward, "2" is added to the value of the distance counter 116c in the connection side RAM 116, and if the vehicle is traveling decelerating forward, "1" is added to the value of the distance counter 116c. In this way, when the vehicle is traveling decelerating forward and the traveling speed is half that of forward traveling, the value added to the distance counter 116c is half the value of forward traveling. Then, based on the value of the distance counter 116c, it is determined whether the forward distance is 50 cm or more (step S507). In step S507, a positive determination is made if the value of the distance counter 116c is equal to or greater than the value corresponding to 50 cm (specifically, equal to or greater than "1667").

If the forward distance is 50 cm or more (step S507: YES), an abnormality occurrence signal is sent to the towing side CPU 32 (step S508). This allows the towing side CPU 32 to perform abnormal stop start processing (step S208). After that, the connection forward flag 116b is cleared to "0" (step S509).

In this way, when the forward distance during the bogie connection operation is 50 cm or more, a process is executed to bring the towing device 10 into an abnormal stop state. This makes it possible to prevent the towing device 10 from continuing to travel forward beyond the distance expected by the operator. By configuring to perform a process (step S508) to transmit an abnormality occurrence signal based on the forward distance being 50 cm or more, it is possible to prevent the towing device 10 from being in an abnormal stop state until the forward distance is 50 cm or more, even if the forward travel is temporarily switched to decelerated forward travel during forward travel. Note that the process (step S508) may also be configured to transmit an abnormality occurrence signal based on the period during which the towing device 10 is traveling forward during the bogie connection operation being a predetermined forward reference period (e.g., 4 seconds) or more.

Returning to the explanation of the coupling side processing (FIG. 10), if a negative judgment is made in step S412, it is judged whether the lock standby flag 116d is set to "1" (step S414), and if the lock standby flag 116d is set to "1" (step S414: YES), it is judged whether the lock standby period has elapsed (step S415). If the lock standby period has elapsed (step S415: YES), the lock standby flag 116d and the distance counter 116c are cleared to "0", and the connection reverse flag 116e (see FIG. 5) provided in the coupling side RAM 116 is set to "1" (step S416). By clearing the lock standby flag 116d to "0", the coupling side CPU 114 can grasp that the lock standby period has ended. In addition, by clearing the distance counter 116c to "0", it is possible to start measuring the reverse distance in the bogie connection operation. The connection reverse flag 116e is a flag that allows the connection side CPU 114 to determine that the towing device 10 is traveling in reverse during the bogie connection operation.

Then, a straight lock end signal is sent to the towing side CPU 32 (step S417). This allows the towing side CPU 32 to execute the reverse travel start process (step S308). In this way, by configuring the straight lock end signal not to be sent until the lock wait period has elapsed, it is possible to prevent the towing device 10 from starting reverse travel while the straight lock operation is being performed.

If a negative determination is made in step S414, it is determined whether or not the connection reverse flag 116e is set to "1" (step S418), and if the connection reverse flag 116e is set to "1" (step S418: YES), connection reverse processing is executed (step S419). Figure 11 (b) is a flowchart showing the connection reverse processing.

In the reverse travel processing for connection, if the carriage 11 is detected by the carriage detection sensor 82 (step S601: YES), a carriage detection signal is sent to the towing side CPU 32 (step S602). This allows the towing side CPU 32 to execute reverse travel stop processing (step S310). Then, hook ascent start processing is executed (step S603). In the hook ascent start processing, drive control of the hook lifting device 57 is started so that the operation for lifting the hooks 55 and 56 is started.

Then, the timer circuit of the coupling side control board 112 is set to a rising waiting time (specifically, 2 seconds) (step S604). The numerical information set in the timer circuit is updated periodically, and the timer circuit is set to "0" when the set rising waiting period has elapsed. By setting the rising waiting period in the timer circuit in step S604, measurement of the rising waiting period is started. Then, the reverse connection flag 116e in the coupling side RAM 116 is cleared to "0," and the hook rising flag 116f (see FIG. 5) provided in the coupling side RAM 116 is set to "1" (step S605). By clearing the reverse connection flag 116e to "0," the coupling side CPU 114 can grasp that the reverse travel of the towing device 10 in the cart connection operation has ended. The hook rising flag 116f is a flag that allows the coupling side CPU 114 to grasp that the operation of raising the hooks 55 and 56 is being performed.

If a negative determination is made in step S601, a process for updating the reverse distance is executed (step S606). In the process for updating the reverse distance, the value of the distance counter 116c is incremented by "2". Then, based on the value of the distance counter 116c, it is determined whether the reverse distance is equal to or greater than 100 cm (step S607). In step S607, a positive determination is made if the value of the distance counter 116c is equal to or greater than the value corresponding to 100 cm (specifically, equal to or greater than "3334").

If the reverse distance is 100 cm or more (step S607: YES), an abnormality occurrence process is executed (step S608) in the same manner as step S407 of the already described connection side process (FIG. 10). In the abnormality occurrence process, an abnormality occurrence signal is sent to the towing side CPU 32. This allows the towing device 10 to be in an abnormal stop state. In addition, in the abnormality occurrence process (step S608), a process is performed to switch the fixing drive unit 89 to a non-driven state. This starts the upward movement of the movable rod 88b. When the lower end of the movable rod 88b passes through the first lock through hole 43g and is in the second lock through hole 47d, the linear lock state of the coupling device 13 is released and the second connection frame 46 is in a rotatable state. The operator can correct the position of the towing device 10 so that the rear of the towing vehicle 12 is approximately directly facing the front of the dolly 11 without performing any operation to release the linear lock state, and then start the dolly connection operation again. After executing the abnormality occurrence processing in step S608, the connection reverse flag 116e is cleared to "0" (step S609).

In this way, when the reverse distance in the trolley connection operation is 100 cm or more, a process is executed to bring the traction device 10 into an abnormal stop state. This prevents the traction device 10 from continuing to reverse beyond the distance expected by the operator. In addition, a distance (100 cm) longer than the predetermined forward reference distance (50 cm) is set as the predetermined reverse reference distance. This makes it possible to reverse the traction device 10 in a manner that does not cause an abnormal stop based on the reverse reference distance from the point where the trolley connection operation was started up to at least the difference between these reference distances (specifically, 50 cm obtained by subtracting the predetermined forward reference distance from the predetermined reverse reference distance) when the forward travel of the trolley device 10 ends in a manner that does not cause an abnormal stop based on the reverse reference distance.

Returning to the explanation of the connection side process (FIG. 10), if the connection reverse flag 116e is not set to "1" (step S418: NO), it is determined whether the hook ascending flag 116f is set to "1" (step S420). Then, if the hook ascending flag 116f is set to "1" (step S420: YES), it is determined whether the ascending waiting period has elapsed (step S421).

If the rise waiting period has elapsed (step S421: YES), the hook rise flag 116f is cleared to "0" (step S422), and the linear lock release process is executed (step S423). In the linear lock release process, the linear lock device 88 is driven and controlled so that the movable bar 88b rises. This releases the linear lock state of the coupling device 13, and the second coupling frame 46 becomes rotatable. After that, a hook rise end signal is sent to the towing side CPU 32 (step S424). This allows the towing side CPU 32 to execute the transport process (step S104).

In this way, by configuring the device not to send a hook lift end signal until the lift wait period has elapsed, it is possible to prevent the start of transport travel while the operation of lifting the hooks 55, 56 is being performed. When the operation of lifting the hooks 55, 56 is performed and the towing device 10 and the cart 11 are connected, the second connecting frame 46 becomes rotatable. This allows the towing device 10 to have good maneuverability when traveling for transport.

In a configuration in which a lock wait period is set when a straight lock operation is performed based on the straight state of the towing device 10 being detected by the straight line detection sensor 93, but when an operation to release the straight lock state is performed based on the elapse of the lift wait period, no wait period is set. This shortens the period from when the cart 11 is connected to the towing device 10 until the towing device 10 starts traveling toward the transport destination.

If the hook rising flag 116f is not set to "1" (step S420: NO), the transport end response process is executed (step S425), and this connection side process is terminated. In the transport end response process (step S425), when a hook lowering signal is received from the towing side CPU 32, the hook lifting device 57 is driven and controlled so that the hooks 55, 56 are lowered. This allows the cart 11 to be separated from the towing device 10 at the transport destination.

Next, the manner in which the operation for connecting the bogies is performed will be described with reference to the time chart in FIG. 12. FIG. 12(a) shows the period during which the towing device 10 travels forward, FIG. 12(b) shows the period during which the straight line detection sensor 93 detects the straight line state of the coupling device 13, FIG. 12(c) shows the period during which the straight line lock of the coupling device 13 is performed, FIG. 12(d) shows the period during which the towing device 10 travels backward, FIG. 12(e) shows the period during which the bogie 11 is detected by the bogie detection sensor 82, FIG. 12(f) shows the period during which the operation for lifting the hooks 55, 56 is performed, FIG. 12(g) shows the period during which the towing device 10 travels forward at a reduced speed, and FIG. 12(h) shows the period during which the forward detection sensor 21 detects an obstacle or the like.

First, we will explain the case where the forward travel of the towing device 10 ends during the bogie connection operation without detecting an obstacle or the like.

When the operation to start the cart connection operation is performed at the timing of t1, the forward travel of the towing device 10 starts as shown in FIG. 12(a). After that, when the straight state of the coupling device 13 is detected by the straight line detection sensor 93 at the timing of t2 as shown in FIG. 12(b), the forward travel of the towing device 10 ends as shown in FIG. 12(a). Also, at the timing of t2, the fixing drive unit 89 is switched from a non-driven state to a driven state, and the operation of lowering the movable bar 88b starts. After that, at the timing of t3, the straight line lock state is reached as shown in FIG. 12(c). After that, at the timing of t4 when the lock waiting period (1 second) has elapsed, the reverse travel of the towing device 10 starts as shown in FIG. 12(d).

After that, at time t5, when the bogie 11 is detected by the bogie detection sensor 82 as shown in FIG. 12(e), the reverse travel of the towing device 10 is stopped as shown in FIG. 12(d), and the raising operation of the hooks 55, 56 is started as shown in FIG. 12(f). After that, at time t6, the raising operation of the hooks 55, 56 is completed as shown in FIG. 12(f). After that, at time t7 after the elapse of the waiting period for raising (2 seconds), the straight lock state of the coupling device 13 is released as shown in FIG. 12(c).

Next, we will explain what happens when the forward detection sensor 21 detects an obstacle or the like while the towing device 10 is traveling forward.

When the operation to start the cart connection operation is performed at the timing of t8, the towing device 10 starts moving forward as shown in FIG. 12(a). After that, when the forward detection sensor 21 detects an obstacle or the like at the timing of t9 as shown in FIG. 12(h), the towing device 10 starts moving forward at a reduced speed as shown in FIG. 12(a) and FIG. 12(g). After that, when the forward detection sensor 21 detects an obstacle or the like at the timing of t10 as shown in FIG. 12(h), the towing device 10 starts moving forward as shown in FIG. 12(a) and FIG. 12(g). After that, from the timing of t11 to the timing of t16, the same operation as that already described for the timing of t2 to the timing of t7 is performed.

In this way, in the trolley connection operation, if the forward detection sensor 21 temporarily detects an obstacle or the like while the towing device 10 is traveling forward, the towing device 10 decelerates and travels forward instead of traveling forward. If the coupling device 13 detects a straight state before the forward distance reaches 50 cm or more, the trolley connection operation continues without entering an abnormal stop state. This reduces the frequency with which the towing device 10 enters an abnormal stop state, compared to a configuration in which an abnormal stop state occurs when the forward detection sensor 21 detects an obstacle or the like.

Next, we will explain how an abnormal stop of the traction device 10 is performed with reference to the time chart in Figure 13. FIG. 13(a) shows the period during which the towing device 10 is in an abnormal stop state, FIG. 13(b) shows the timing when the forward distance of the towing device 10 in the bogie connection operation is 50 cm or more, FIG. 13(c) shows the timing when the backward distance of the towing device 10 in the bogie connection operation is 100 cm or more, FIG. 13(d) shows the period during which the towing device 10 is traveling forward, FIG. 13(e) shows the period during which the straight state of the coupling device 13 is detected by the straight line detection sensor 93, FIG. 13(f) shows the period during which the coupling device 13 is in a straight line lock state, FIG. 13(g) shows the period during which the towing device 10 is traveling backward, FIG. 13(h) shows the timing when an obstacle is detected by the front contact detection sensor 24, FIG. 13(i) shows the timing when an obstacle or the like is detected by the coupling side contact detection sensors 97, 98, and FIG. 13(j) shows the period during which the towing device 10 is traveling forward at a reduced speed.

First, we will explain the case where the front contact detection sensor 24 detects contact with an obstacle or the like while the trolley connection operation is being performed.

When the operation to start the cart connection operation is performed at the timing of t1, the forward travel of the towing device 10 starts as shown in FIG. 13(d). After that, when an obstacle or the like is detected by the forward detection sensor 21 at the timing of t2, the towing device 10 goes into a state of decelerated forward travel instead of forward travel as shown in FIG. 13(d) and FIG. 13(j). After that, when contact with an obstacle or the like is detected by the front contact detection sensor 24 at the timing of t3 as shown in FIG. 13(h), the decelerated forward travel of the towing device 10 is stopped as shown in FIG. 13(j), and the towing device 10 goes into an abnormal stop state as shown in FIG. 13(a). In this way, the configuration in which the travel speed of the towing device 10 is decelerated before the towing device 10 comes into contact with an obstacle or the like can reduce the impact when the towing device 10 comes into contact with an obstacle or the like.

Next, we will explain the case where the forward movement distance of the traction device 10 during the trolley connection operation is 50 cm or more.

When the operation to start the cart connection operation is performed at the timing of t4, the forward travel of the towing device 10 starts as shown in FIG. 13(d). After that, when the forward travel distance of the towing device 10 reaches 50 cm or more at the timing of t5 as shown in FIG. 13(b), the forward travel of the towing device 10 is stopped as shown in FIG. 13(d) and the towing device 10 enters an abnormal stop state as shown in FIG. 13(a). This prevents the towing device 10 from continuing to travel forward for a long distance that the operator does not expect, even if a factor that prevents the coupling device 13 from being in a straight line state (for example, a factor that prevents the swinging part 26 from turning around the turning shaft 29 due to a small object being caught between the rotation range limiting protrusions 53, 54 and the inclined protrusions 44a, 44b) or a factor that prevents the detection of the straight line state (for example, a broken wire, etc.) occurs.

In this manner, in a configuration in which the towing device 10 is brought to an abnormal stop state based on the front contact detection sensor 24 detecting contact with an obstacle or the like while the towing device 10 is traveling forward, if the forward travel distance of the towing device 10 during the bogie connection operation is 50 cm or more, the towing device 10 will be brought to an abnormal stop state even if the towing device 10 does not come into contact with an obstacle or the like. This makes it possible to prevent the towing device 10 from coming into contact with an obstacle or the like in a situation that the operator does not anticipate.

Next, we will explain what happens when the connecting side contact detection sensors 97, 98 detect contact with an obstacle, etc.

After the operation to start the bogie connection operation is performed, while the towing device 10 is traveling forward, at timing t6, when the straight line detection sensor 93 detects the straight line state of the coupling device 13 as shown in FIG. 13(e), the forward travel of the towing device 10 is stopped as shown in FIG. 13(d), and the fixing drive unit 89 is switched from a non-driven state to a driven state to start the operation of lowering the movable bar 88b. After that, at timing t7, the straight line lock state is reached as shown in FIG. 13(f).

Then, at time t8 when the lock waiting period (1 second) has elapsed, the towing device 10 starts moving backward as shown in FIG. 13(g). Then, at time t9, when the coupling side contact detection sensors 97, 98 detect contact with an obstacle or the like as shown in FIG. 13(i), the towing device 10 stops moving backward as shown in FIG. 13(g). Also, at this time t9, the towing device 10 enters an abnormal stop state as shown in FIG. 13(a). Then, at time t10, the straight lock state of the coupling device 13 is released as shown in FIG. 13(f).

Next, we will explain the case where the reversing distance of the traction device 10 during the bogie connection operation is 100 cm or more.

After the operation to start the bogie connection operation is performed, while the towing device 10 is traveling forward, at timing t11, when the straight line detection sensor 93 detects the straight line state of the coupling device 13 as shown in FIG. 13(e), the forward travel of the towing device 10 is stopped as shown in FIG. 13(d), and the fixing drive unit 89 is switched from a non-driven state to a driven state to start the operation of lowering the movable rod 88b. After that, at timing t12, the straight line lock state is reached as shown in FIG. 13(f).

After that, at the timing of t13 when the lock waiting period (1 second) has elapsed, the towing device 10 starts to move backward as shown in FIG. 13(g). After that, at the timing of t14, when the backward travel distance of the towing device 10 becomes 100 cm or more as shown in FIG. 13(c), the towing device 10 stops moving backward as shown in FIG. 13(g). Also, at the timing of t14, the towing device 10 enters an abnormal stop state as shown in FIG. 13(a). This prevents the towing device 10 from moving backward over a long distance that the operator does not expect, even if a factor that prevents the carriage contact portion 81c from contacting the carriage 11 (for example, an obstacle or the like is present between the towing device 10 and the carriage 11 at a position that does not contact the bumper contact portions 99 and 101, preventing the carriage contact portion 81c from contacting the carriage 11) occurs, or a factor that prevents the carriage detection sensor 82 from detecting the carriage 11 (for example, a broken wire, etc.) occurs. After that, at timing t15, the linear lock state of the coupling device 13 is released, as shown in FIG. 13(f).

In this manner, in a configuration in which the towing device 10 is brought into an abnormal stop state based on the detection of contact with an obstacle or the like by the coupling side contact detection sensors 97, 98 while the towing device 10 is traveling in reverse, if the reverse travel distance of the towing device 10 during the bogie connection operation is 100 cm or more, the towing device 10 will be brought into an abnormal stop state even if the towing device 10 does not come into contact with an obstacle or the like. This makes it possible to prevent the towing device 10 from coming into contact with an obstacle or the like in a situation that the operator does not anticipate.

<Other embodiments>
The present invention is not limited to the above-described embodiment, and various modifications and improvements are possible without departing from the spirit of the present invention. For example, the following modifications may be made. The following configurations of the other embodiments may be applied individually or in combination to the configuration of the first embodiment.

(1) In the first embodiment, the lower end of the movable rod 88b is inserted into the second locking through-hole 47d when the fixing drive unit 89 is in a non-driven state, but the present invention is not limited to this. The lower end of the movable rod 88b may be located above the second connecting frame 46 and not in the second locking through-hole 47d when the fixing drive unit 89 is in a non-driven state. Even in this configuration, the fixing drive unit 89 is driven and the movable rod 88b moves downward and is inserted into the first locking through-hole 43g and the second locking through-hole 47d, thereby restricting the rotation of the second connecting frame 46 around the rotation axis 29, and the linear lock state in which the connecting device 13 is maintained can be achieved.

(2) In the first embodiment, the towing device 10 is placed in front of the dolly 11 by the operator, but the present invention is not limited to this. The driving control of the towing device 10 to make the rear of the towing vehicle 12 face the front of the dolly 11 may be performed by the coupling side control device 110 and the towing side control device 30. Specifically, the towing device 10 is provided with a dolly recognition device (e.g., a camera capable of photographing the front of the dolly 11) capable of recognizing the front of the dolly 11. When the dolly connection start operation is performed in a state in which the towing device 10 is placed in a position where the front of the dolly 11 can be recognized by the dolly recognition device, the towing side CPU 32 controls the driving of the towing vehicle 12 so that the information of the front of the dolly 11 recognized by the dolly recognition device matches the information set in advance. As a result, the rear of the towing vehicle 12 faces the front of the dolly 11 in a substantially direct state, and the distance between the dolly 11 and the towing vehicle 12 becomes a preset distance. Thereafter, similarly to the first embodiment, processing is executed to perform the bogie connection operation (the processing of step S103 in the towing side CPU 32 and the processing of steps S410 to S425 in the coupling side CPU 114). This makes it possible to omit the work of the operator positioning the towing device 10 in front of the bogie 11 so that the rear of the towing vehicle 12 is substantially directly facing the front of the bogie 11 before starting the bogie connection operation.

(3) In the first embodiment, a process for abnormally stopping the towing device 10 may be executed based on the fact that the traction side CPU 32 is performing the in-transport process (step S104) and the traction side CPU 32 is not detecting the traction side 11. Specifically, in a state in which the towing side CPU 32 is performing the in-transport process (step S104), the connection side CPU 114 periodically (for example, at a period of 4 milliseconds) performs a determination process to determine whether the detection signal received from the traction side sensor 82 is at a HI level (a level corresponding to a state in which the traction side 11 is detected). If a negative determination is made in the determination process, that is, if the detection signal received from the traction side sensor 82 is at a LOW level (a level corresponding to a state in which the traction side 11 is not detected), an abnormality occurrence process is executed in the same manner as step S407 of the connection side process (FIG. 10) and step S608 of the connection update process. This allows the operator to be notified that the hooks 55, 56 are no longer engaged with the cart 11, and prevents the towing device 10 from continuing to travel after this situation has occurred.

(4) In the first embodiment, the waiting period is not set when the operation to release the linear lock state is performed based on the lapse of the rising waiting period, but the present invention is not limited to this. The unlocking waiting period (specifically, 1 second) may be set in the timer circuit of the connecting side control board 112 based on the lapse of the rising waiting period. When the unlocking waiting period has elapsed, the connecting side CPU 114 transmits an unlocking end signal to the towing side CPU 32. When the towing side CPU 32 receives the unlocking end signal, it ends the connection operation process (FIG. 9) and starts the transport process (step S104). This allows the lower end of the movable rod 88b to come out of the first locking through hole 43g and be in the second locking through hole 47d before the towing device 10 starts traveling to the transport destination. This reduces the possibility that the movable rod 88b and the second connecting frame 46 will come into contact with each other during the process of the movable rod 88b moving upward.

(5) In the first embodiment, the process for terminating the forward travel of the towing device 10 is executed based on the fact that the straight line state of the towing device 10 is detected by the straight line detection sensor 93 during the bogie connection operation, but this is not limited to the above, and the straight line detection sensor 93 may be omitted. Even in this case, it is possible to bring the towing device 10 closer to a straight line state by having the towing device 10 travel forward before traveling backward toward the bogie 11.

(6) The coupling side CPU 114 or the towing side CPU 32 may be configured to execute a process for terminating the forward travel of the towing device 10 in the dolly connecting operation and to execute a process for driving the fixing drive unit 89 based on the reception of a signal from outside the towing device 10. Specifically, the transport system includes a camera that photographs the towing device 10 from above and a management computer that determines whether the towing device 10 is in a straight line state based on the photographed image. When the management computer determines that the towing device 10 is in a straight line state based on the photographed image in a situation in which the towing device 10 is traveling forward in the dolly connecting operation, it transmits a straight line detection signal to the coupling side CPU 114 or the towing side CPU 32. As a result, it becomes possible to execute a process for terminating the forward travel in the coupling side CPU 114 or the towing side CPU 32 when the towing device 10 is in a straight line state, even though the towing device 10 is configured not to have a straight line detection sensor 93. In addition, the configuration may be such that, upon confirming that the towing device 10 has entered a straight line, the operator operates a smartphone or the like to send a signal to end the forward travel.

(7) In the first embodiment, the linear lock device 88 is used to maintain the linear state of the towing device 10, but the present invention is not limited to this. A rotation restriction device may be used to maintain the state in which the rotation of the second connecting frame 46 around the rotation axis 29 is restricted within a predetermined restriction angle range. Specifically, the rotation restriction device includes a pair of left and right restriction movable rods and a restriction drive unit for moving the restriction movable rods up and down. A pair of left and right restriction through holes through which the restriction movable rods can be inserted is formed in the lower plate portion 47 of the second connecting frame 46. The restriction through holes are provided closer to the center in the width direction of the second connecting frame 46 than the rotation range restriction protrusions 53 and 54. When the restriction drive unit is in a non-driven state, the lower end of the restriction movable rod is present in the restriction through hole and does not protrude below the lower plate portion 47. When the restriction drive unit is in a driven state, the restriction movable rod is inserted into the restriction through hole and protrudes below the lower plate portion 47, resulting in a rotation restriction execution state. In the rotation restriction execution state, the lower part of the left-side restriction movable bar comes into contact with the left-side inclined protrusion 44a when the amount of rotation of the second connecting frame 46 to the left from the straight state of the connecting device 13 about the rotation shaft 29 reaches a predetermined restriction angle (e.g., 5 degrees) on the left side. This makes the second connecting frame 46 unable to rotate further to the left. In addition, in the rotation restriction execution state, the lower part of the right-side restriction movable bar comes into contact with the right-side inclined protrusion 44b when the amount of rotation of the second connecting frame 46 to the right from the straight state of the connecting device 13 about the rotation shaft 29 reaches a predetermined restriction angle (e.g., 5 degrees) on the right side. This makes the second connecting frame 46 unable to rotate further to the right. In this way, by using the rotation restriction device, the towing device 10 can be made to travel backward toward the bogie 11 in a state in which the rotation of the second connecting frame 46 around the rotation shaft 29 is restricted to a predetermined restriction angle range. This makes it possible to bring the traction device 10 close to the traction vehicle 11 in a manner that makes it easy to connect the traction device 10 to the traction vehicle 11.

(8) In the configuration of (7) above, instead of the linear detection sensor 93, a detection sensor that detects that the amount of rotation of the second connecting frame 46 around the rotation axis 29 is within a predetermined restricted angle range may be provided in the connecting device 13. When the towing device 10 is traveling forward in the cart connection operation, the connecting side CPU 114 executes processing to terminate the forward traveling of the towing device 10 based on the detection of the amount of rotation of the second connecting frame 46 around the rotation axis 29 being within the predetermined restricted angle range by the detection sensor. In this way, after it is detected that the amount of rotation of the second connecting frame 46 around the rotation axis 29 is within the predetermined restricted angle range, processing to set the rotation restriction execution state can be executed.

(9) In the first embodiment, the linear locking device 88 is used to fix the linear state of the towing device 10 during the bogie connection operation, but this is not limited to this. The linear locking device 88 may not be provided, and the forward travel of the towing device 10 may be terminated and the reverse travel of the towing device 10 may be started based on the linear detection sensor 93 detecting the linear state of the towing device 10 while the towing device 10 is traveling forward during the bogie connection operation.

(10) In the first embodiment, the first connecting frame 42 and the pivot shaft 29 are provided on the coupling device 13, but this is not limited thereto. The first connecting frame 42 may be provided on the towing vehicle 12, or both the first connecting frame 42 and the pivot shaft 29 may be provided on the towing vehicle 12. Even in this configuration, the second connecting frame 46 of the coupling device 13 can be made to pivot around the pivot shaft 29. In addition, the linear lock device 88 provided on the coupling device 13 can be used to maintain the linear state of the towing device 10.

(11) In the first embodiment, the trolley 11 is connected to the towing device 10 by raising the hooks 55 and 56, but this is not limited thereto. The trolley 11 may be connected to the towing device 10 by rotating a hook provided on the rear side of the coupling device 13 so as to be rotatable about an axis in the width direction from bottom to top, or the trolley 11 may be connected to the towing device 10 by rotating a hook provided on the rear side of the coupling device 13 so as to be rotatable about an axis in the width direction from top to bottom. Even in these configurations, the traction device 10 can be reversed toward the trolley 11 while maintaining the straight state of the traction device 10, thereby preventing the hook from not properly engaging with the trolley 11.

(12) In the first embodiment, a contact-type connecting side bumper device 95 is provided on the rear side of the second connecting frame 46 of the connecting device 13. However, instead of or in addition to this, a non-contact type rear detection sensor that detects obstacles, etc. present within a detection range (specifically, within a radius of 1 m) set behind the connecting device 13 may be provided. When the towing device 10 is traveling backwards, a process to reduce the traveling speed of the backward traveling or a process to stop the backward traveling is executed based on the detection of an obstacle, etc. by the rear detection sensor. This can reduce the possibility of the towing device 10 coming into contact with an obstacle, etc. present behind it.

(13) A distance measuring sensor may be provided to grasp the forward distance of the towing device 10 during the bogie connection operation. The coupling side CPU 114 can grasp the distance to the bogie 11 by the distance measuring sensor provided at the rear of the coupling device 13. The forward distance of the towing device 10 is grasped based on the information of the distance to the bogie 11 acquired when the towing device 10 starts to travel forward and the information of the distance to the bogie 11 acquired during forward travel. This allows the coupling side CPU 114 to grasp whether the forward distance of the towing device 10 during the bogie connection operation has reached or exceeded a predetermined forward reference distance based on the distance information measured using the distance measuring sensor. Then, it becomes possible to abnormally stop the towing device 10 based on the fact that the forward distance has reached or exceeded the predetermined forward reference distance.

(14) In the first embodiment, the towing device 10 is placed in an abnormal stop state when the reverse distance of the towing device 10 in the bogie connection operation becomes equal to or greater than a predetermined reverse reference distance (100 cm). However, the present invention is not limited to this, and a process for placing the towing device 10 in an abnormal stop state may be executed when the reverse running time of the towing device 10 becomes equal to or greater than a predetermined reverse reference period (e.g., 8 seconds) in the bogie connection operation. Also, a reverse end reference line such as a white line may be provided on the floor surface on which the towing device 10 runs, and a process for placing the towing device 10 in an abnormal stop state may be executed when the towing device 10 reverses to the reverse end reference line without detecting the bogie 11 in the bogie connection operation. This can prevent the towing device 10 from moving backward beyond the reverse end reference line in the bogie connection operation.

(15) In the first embodiment, the towing device 10 is configured to have the towing device 10 placed in an abnormal stop state when the forward distance during the cart connection operation of the towing device 10 becomes equal to or greater than a predetermined forward reference distance (50 cm). However, the present invention is not limited to this, and the transport device may be configured to have the transport device move forward until it detects the destination and stops, and the transport device may be configured to have the transport device move forward when the forward distance of the transport device becomes equal to or greater than a specific forward reference distance (for example, 50 m) without detecting the destination. Specifically, after the destination position information is set in the transport device, the transport device starts moving forward. A plurality of current location recognition information that allows the transport device to recognize its current location is set on the floor surface of the travel path of the transport device. The transport device checks the set destination position information and the current location recognition information read from the floor surface, and ends the forward travel for transport based on the match between these position information. After the transport device starts moving forward, if the location information set as the transport destination does not match the current location recognition information read from the floor surface and the transport device's forward distance exceeds a specific forward reference distance (50 m), a process is executed to put the transport device into an abnormal stop state even if the transport destination has not been reached. This prevents the transport device from moving forward beyond the distance planned by the operator.

(16) In the configuration of (15) above, instead of or in addition to the configuration in which the transport device travels forward to the transport destination, the transport device may be configured to travel backward to the return destination. Specifically, after the return destination information is set and the transport device starts traveling backward, if the position information set as the return destination does not match the current location recognition information read from the floor surface and the backward travel distance of the transport device exceeds a specific backward travel reference distance (e.g., 50 m), a process is executed to put the transport device into an abnormal stop state even if the transport device has not arrived at the return destination. This makes it possible to prevent the transport device from traveling backward beyond the distance planned by the operator.

<Inventions extracted from the above embodiments>
The following describes the features of the inventions extracted from the above-described embodiments, while indicating, as necessary, their effects, etc. In the following, for ease of understanding, the corresponding configurations in the above-described embodiments are appropriately indicated in parentheses, but the present invention is not limited to the specific configurations indicated in parentheses.

<Features Group A>
Feature A1. In a control device (tow side control device 30, coupling side control device 110) of a conveyance system used in a conveyance system for conveying a conveyance object (carriage 11) to a predetermined conveyance location,
The transport system includes:
A transport device (tow vehicle 12) having a drive means (rear wheel drive unit 23) and transporting the transport object to the predetermined transport location by the driving force of the drive means;
A coupling means (coupling device 13) for coupling the object to be transported to the transport device;
Equipped with
the coupling means includes a rotating part (swinging part 26) that is rotatable about a vertical rotating shaft (rotating shaft 29) so as to enable the transport object to follow when the travel direction of the transport device is changed,
The control device includes:
a preparatory control means for executing preparatory control (control for causing the towing device 10 to travel forward in a carriage connecting operation) for moving the transport device in a direction opposite to a direction toward the transport target when the transport target is to be connected to the connecting means in a state in which the connecting means is connected to the transport device (a function for executing the processing of steps S102 to S103 in the towing side CPU 32, a function for executing the processing of steps S301 to S303, and a function for executing the processing of steps S408 to S413 in the connecting side CPU 114);
a termination control means (a function for executing the processes of steps S304 to S306 in the towing-side CPU 32 and a function for executing the processes of steps S501 to S505 in the connection-side CPU 114) for executing termination control for terminating the movement in the reverse direction (control for terminating the forward travel of the towing device 10) based on the occurrence of a predetermined termination trigger (detection of the linear state of the towing device 10 by the linear detection sensor 93) in a situation in which the transport device is moving in a direction opposite to the direction toward the transport target as a result of the execution of the preparation control;
a coupling control means (a function for executing the processing of steps S307 to S308 in the towing side CPU 32, and a function for executing the processing of steps S418 to S419 in the coupling side CPU 114) for executing coupling control (control for causing the towing device 10 to travel backward in the carriage connecting operation) for moving the transport device in a direction toward the transport object in order to couple the transport object to the coupling means after the termination control has been executed;
A control device for a transport system comprising:

According to feature A1, the connection means is configured to include a rotating part that is rotatable around a rotating shaft, thereby improving the steerability of the transport device when the transport target is connected. In addition, the rotating part can be rotated to follow the transport device. In this configuration, by performing preparatory control prior to connection control, the transport device, the rotating shaft, and the rotating part can be aligned in a straight line or in a state close to that state. Then, by performing connection control after executing preparatory control and termination control, the transport device, the rotating shaft, and the rotating part can be started to move in a direction toward the transport target from a state in which the transport device, the rotating shaft, and the rotating part are aligned in a straight line or in a state close to that state. This makes it possible to bring the transport device close to the transport target in a manner that makes it easy to connect the transport target to the transport device.

Feature A2. The conveying system includes a predetermined detection means (straight line detection sensor 93) that detects that the rotation position of the rotation part has reached a predetermined position (a position where the towing device 10 is in a straight line state),
The control device for a conveying system according to feature A1, wherein the predetermined end trigger occurs when the predetermined detection means detects that the rotation position of the rotation part has reached the predetermined position.

According to feature A2, in a situation where the transport device is moving in a direction opposite to the direction toward the transport target due to the execution of the preparation control, the termination control can be performed and the coupling control can be started based on the fact that the rotation position of the rotating part has actually reached a predetermined position detected by a predetermined detection means. This makes it possible to prevent the coupling control from being started in a state where the rotation position of the rotating part is not at the predetermined position.

Feature A3. The conveying system includes a restricting means (linear locking device 88) that restricts the rotation of the rotating part when the rotating position of the rotating part is at the predetermined position,
The control device of the conveying system described in feature A2 is characterized in that it is equipped with a regulation control means (a function of executing the processing of steps S501 to S505 in the connecting side CPU 114) that executes regulation control (control to switch the fixing drive unit 89 to a driven state) so that the rotation of the rotating part is regulated by the regulating means when the specified detection means detects that the rotation position of the rotating part has reached the specified position.

According to feature A3, by performing the restriction control when the rotation position of the rotating part is in a predetermined position, it is possible to perform the connection control while restricting the rotation of the rotating part from that state. This makes it possible to bring the transport device close to the transport target in a manner that makes it easy to connect the transport target to the transport device.

Feature A4. The control device for the conveying system described in Feature A2 or A3, characterized in that the predetermined position is a rotational position of the rotating part where the conveying device, the connecting means, and the conveying object are aligned in a line (a rotational position where the traction device 10 is in a straight line).

According to feature A4, the connection control can be started after it is detected that the transport device, the connection means, and the transport object are aligned in a line. This makes it possible to bring the transport device close to the transport object in a manner that makes it easy to connect the transport object to the transport device.

In particular, when the configuration described in feature A3 above is provided, by performing the restriction control in a state where the conveying device, the connecting means, and the conveying object are aligned in a row, it becomes possible to perform the connection control while restricting the rotation of the rotating part from that state.

Feature A5. The control device for the transport system described in Feature A1 is characterized in that the control device is provided with a means (a function for executing the processing of steps S207 to S210 in the towing side CPU 32, and a function for executing the processing of steps S506 to S509 in the connection side CPU 114) for executing a specific end control (control for abnormally stopping the towing device 10 when the forward distance becomes equal to or greater than a predetermined forward reference distance) for ending the movement in the reverse direction even if the predetermined end trigger does not occur based on the occurrence of a specific end trigger (when the forward distance becomes equal to or greater than a predetermined forward reference distance) in a situation where the transport device is moving in a direction opposite to the direction toward the transport object due to the execution of the preparation control.

According to feature A5, in a configuration having the configuration of feature A1 and in which termination control is executed based on the occurrence of a predetermined termination trigger, even if the predetermined termination trigger has not occurred, if a specific termination trigger occurs, the specific termination control can be executed so that movement of the conveying device in the opposite direction to the direction toward the conveying target is terminated. This makes it possible to prevent the movement in the opposite direction from continuing even after the specific termination trigger occurs, even if the predetermined termination trigger has not occurred. This makes it possible to prevent the conveying device from coming into contact with an obstacle or the like in a situation that the operator does not anticipate.

Feature A6. The control device for a conveying system described in Feature A5, characterized in that the specific end trigger occurs when, in a situation where the conveying device is moving in a direction opposite to the direction toward the conveying target as a result of the preparation control being executed, the amount of movement of the conveying device reaches a predetermined amount of movement (a predetermined forward reference distance of 50 cm) or when, in a situation where the conveying device is moving in a direction opposite to the direction toward the conveying target as a result of the preparation control being executed, the period during which the conveying device is moving in a direction opposite to the direction toward the conveying target reaches a predetermined period of time (a predetermined forward reference period of 4 seconds).

According to feature A6, when the preparatory control is executed, it is possible to prevent the conveying device from continuing to move in the opposite direction to the direction toward the conveying target until the amount of movement of the conveying device reaches a predetermined amount, or to prevent the conveying device from continuing to move in the opposite direction until the period during which the conveying device has been moving in the opposite direction reaches a predetermined period. This makes it possible to prevent the conveying device from moving beyond the predetermined amount or period by the preparatory control, even when a predetermined termination trigger has not occurred. This makes it possible to prevent the conveying device from coming into contact with an obstacle or the like in a situation that the operator has not anticipated.

Feature A7. The transport system includes a connection possible detection means (cart detection sensor 82) that detects that the transport device is in a state where the transport object can be connected to the connection means by moving in a direction toward the transport object as a result of the connection control being executed,
The control device is characterized in that it includes a connection movement end control means (a function of executing the processing of steps S309 to S310 in the towing side CPU 32, and a function of executing the processing of steps S601 to S605 in the connecting side CPU 114) that executes a connection movement end control (control to end the backward travel of the towing device 10 in the cart connecting operation) to end the movement of the transport device in the direction toward the transport target based on the detection by the connection possibility detection means that the transport device is in a state where it is possible to connect the transport target to the connecting means when the connection control is executed and the transport device is moving in the direction toward the transport target.

According to feature A7, in a situation where the transport device is moving in a direction toward the transport target as a result of the execution of the connection control, the connection movement end control can be executed based on the connection possibility detection means detecting that the transport target can actually be connected to the connection means. This makes it possible to prevent the connection movement end control from being executed in a state where the transport target cannot be connected to the connection means.

Feature A8. The control device for the transport system described in Feature A7 is characterized in that it is provided with a means (a function for executing the processing of steps S601 to S605 in the connection side CPU 114) for executing a control for connecting the transport object to the connection means (a control for raising the hooks 55, 56 by placing the lifting drive unit 71 in the first drive state) when the movement of the transport device in the direction toward the transport object is terminated by executing the connection movement end control.

According to feature A8, the configuration of feature A7 is included, and the connection movement end control is executed based on the connection possibility detection means detecting that the transport object can be connected to the connection means, so that it is possible to detect that the transport object can actually be connected to the connection means, and control is executed to connect the transport object to the connection means after the connection movement end control is executed based on the detection. This makes it possible to reduce the possibility of a situation occurring in which the transport object is not normally connected to the connection means despite the control being executed to connect the transport object to the connection means.

Feature A9. The control device for the transport system described in Feature A7 or A8, which includes a means for executing control (a function for executing the processing of steps S207 to S210 in the towing side CPU 32, and a function for executing the processing of steps S606 to S609 in the connecting side CPU 114) to terminate the movement of the transport device in the direction toward the transport target (control for abnormally stopping the towing device 10) based on the occurrence of a movement end trigger (the backward movement distance of the towing device 10 in the cart connecting operation becoming equal to or greater than a predetermined backward movement reference distance) in a situation where the transport device is moving in the direction toward the transport target by executing the connection control, even if the connection possibility detection means does not detect that the transport target is in a state where it is possible to connect to the connecting means.

According to feature A9, in a configuration having the configuration of feature A7 and in which the connection movement end control is executed based on the connection possibility detection means detecting that the transport object can be connected to the connection means when the transport device is moving in the direction toward the transport object by executing the connection control, even if the connection possibility detection means does not detect that the transport object can be connected to the connection means, when a movement end trigger occurs, control for ending the movement of the transport device in the direction toward the transport object can be executed to end the movement of the transport device. This makes it possible to prevent the transport device from continuing to move after the movement end trigger occurs, even if a factor occurs that prevents the transport object from being connected to the connection means or that prevents the detection of the state. Therefore, it is possible to prevent the transport device from coming into contact with an obstacle or the like in a situation that the operator does not anticipate.

Feature A10. A conveying system comprising the connection means and the control device described in Feature A1.

Feature A10 makes it possible to provide a conveying system having the effects already described in Feature A1.

The invention relating to the above feature group A can solve the following problems.

In factories and warehouses, etc., conveying systems are used to transport materials, parts, finished products, and other items to their destinations. Conveying systems include conveying devices with drive wheels and a control device that controls the conveying devices. Conveying devices include conveying devices that are equipped with a platform on which items are placed and that transport items independently, conveying devices that transport items such as carts loaded with items to their destinations while pushing them, and conveying devices that transport items such as carts loaded with items to their destinations while towing them.

As a transport device for transporting an object to a destination, there is known a device that is equipped with a coupling device for connecting the object to the transport device. With such a transport device, maneuverability becomes an issue when changing course while the object is connected. In response to this, a coupling device is known that has a rotating part that can rotate around a vertical connecting axis to improve the maneuverability of the transport device.

However, when using a connecting device with a rotating part, there is a problem that even if the transport device is brought close to the transport target, the transport target may not be connected to the transport device depending on the rotation position of the rotating part. As such, there is still room for improvement in the control device of the transport system and the transport system that executes control to bring the transport device close to the transport target and connect the transport target to the transport device.

<Characteristics Group B>
Feature B1. In a control device (tow side control device 30, coupling side control device 110) of a conveyance system used in a conveyance system having a conveyance device for conveying a conveyance object (carriage 11) to a predetermined conveyance location,
a predetermined control means for executing predetermined control (control for causing the towing device 10 to travel forward in the bogie connecting operation, and control for causing the towing device 10 to travel backward in the bogie connecting operation) for moving the transport device to a predetermined state (a state in which the straight line state of the towing device 10 is detected by the straight line detection sensor 93, and a state in which the bogie 11 is detected by the bogie detection sensor 82) (a function for executing the processing of steps S102 to S103 in the towing side CPU 32, a function for executing the processing of steps S301 to S303 and steps S307 to S308, and a function for executing the processing of steps S408 to S413 and steps S418 to S419 in the connection side CPU 114);
specific end control means (a function for executing the processing of steps S207 to S210 in the towing side CPU 32, a function for executing the processing of steps S506 to S509 in the connection side CPU 114, and a function for executing the processing of steps S606 to S609) for executing specific end control (control for abnormally stopping the towing device 10) for ending the movement of the transport device even if the specific state is not reached, based on the fact that the amount of movement of the transport device has reached a specific amount of movement (a specific forward reference distance, a specific backward reference distance) or based on the fact that the period during which the transport device is moving has reached a specific period (a specific forward reference period, a specific backward reference period) due to the execution of the specific control in a situation in which the transport device is moving due to the execution of the specific control;
A control device for a transport system comprising:

According to feature B1, a predetermined state can be achieved by executing a predetermined control to move the conveying device. When the amount of movement of the conveying device reaches a predetermined amount while the conveying device is moving as a result of the execution of the predetermined control, or when the period during which the conveying device is moving reaches a predetermined period as a result of the execution of the predetermined control, it is possible to prevent the conveying device from moving beyond the predetermined amount or period until the predetermined state is reached by executing a specific end control even if the predetermined state is not reached. This reduces the possibility of the conveying device coming into contact with an obstacle or the like in a situation not anticipated by the operator, even if a factor occurs that prevents the conveying device from reaching the predetermined state.

The invention relating to the above feature group B can solve the following problems.

In factories and warehouses, etc., conveying systems are used to transport materials, parts, finished products, and other items to their destinations. Conveying systems include conveying devices with drive wheels and a control device that controls the conveying devices. Conveying devices include conveying devices that are equipped with a platform on which items are placed and that transport items independently, conveying devices that transport items such as carts loaded with items to their destinations while pushing them, and conveying devices that transport items such as carts loaded with items to their destinations while towing them.

In the above-mentioned conveying system, control is performed to ensure that the conveying device automatically travels in a predetermined traveling mode, such as traveling straight ahead, so that the conveying device reaches a predetermined state, such as when it has reached the destination or when a predetermined detection object has been detected. With this type of conveying device control, if a factor occurs that prevents the conveying device from reaching the predetermined state, the conveying device may continue traveling beyond the range anticipated by the administrator, causing the conveying device to come into contact with an obstacle or the like. In response to this, a conveying system is known that detects that the conveying device has come into contact with an obstacle or the like and controls the conveying device to stop traveling.

However, in a conveying system in which the above-mentioned control is performed, there is a risk that the conveying device or the obstacle it comes into contact with may be damaged if the conveying device comes into contact with an obstacle in a situation not anticipated by the administrator. In addition, a conveying system that performs control to detect obstacles, etc. present around the conveying device without contact and stop the conveying device before contact occurs is also conceivable, but if an attempt is made to detect all obstacles, etc. present around the conveying device, problems such as increased manufacturing costs for the conveying device arise. Thus, there is still room for improvement in the control device of the conveying system and the conveying system that executes control to ensure that the conveying device automatically travels safely so as to achieve a specified state.

10... towing device, 11... dolly, 12... towing vehicle, 13... coupling device, 23... rear wheel drive unit, 26... swing unit, 29... rotation shaft, 30... towing side control device, 32... towing side CPU, 71... lifting drive unit, 82... dolly detection sensor, 88... linear lock device, 89... fixing drive unit, 93... linear detection sensor, 110... coupling side control device, 114... coupling side CPU.

Claims (10)

A control device for a transport system used in a transport system for transporting an object to be transported to a predetermined transport location,
The transport system includes:
A transport device having a drive means and transporting the transport object to the predetermined transport location by a driving force of the drive means;
A connection means for connecting the object to be transported to the transport device;
Equipped with
the connecting means includes a rotating part that is rotatable about a vertical rotation axis so as to enable the object to follow when the traveling direction of the transport device is changed,
The control device includes:
a preparation control means for executing a preparation control so as to move the transport device in a direction opposite to a direction toward the object to be transported when the object to be transported is to be coupled to the coupling means in a state in which the coupling means is coupled to the transport device;
a termination control means for executing a termination control to terminate the movement in the reverse direction based on the occurrence of a predetermined termination trigger in a situation in which the transport device is moving in a direction opposite to the direction toward the transport target as a result of the execution of the preparation control;
a connection control means for executing a connection control to move the transport device in a direction toward the transport object in order to connect the transport object to the connection means after the termination control is executed;
A control device for a transport system comprising: the conveying system includes a predetermined detection means for detecting that a rotation position of the rotation part has reached a predetermined position,
2. The control device for a conveying system according to claim 1, wherein the predetermined end trigger occurs when the predetermined detection means detects that the rotation position of the rotation part has reached the predetermined position. the conveying system further includes a restricting unit that restricts rotation of the rotating unit when the rotating position of the rotating unit is at the predetermined position;
The control device for a conveying system according to claim 2, characterized in that the control device is provided with a regulation control means that executes regulation control so that the rotation of the rotating part is regulated by the regulating means when the predetermined detection means detects that the rotation position of the rotating part has reached the predetermined position. The control device for a conveying system according to claim 2 or 3, characterized in that the predetermined position is a rotational position of the rotating part where the conveying device, the connecting means, and the conveying object are aligned in a line. The control device of the transport system according to claim 1, characterized in that the control device is provided with means for executing a specific end control to end the movement in the opposite direction even if the predetermined end trigger has not occurred, based on the occurrence of a specific end trigger in a situation in which the transport device is moving in a direction opposite to the direction toward the transport object due to the execution of the preparation control. The control device for a transport system according to claim 5, characterized in that the specific end trigger occurs when the amount of movement of the transport device reaches a predetermined amount in a situation where the transport device is moving in a direction opposite to the direction toward the transport target as a result of the preparation control being executed, or when the period during which the transport device is moving in a direction opposite to the direction toward the transport target as a result of the preparation control being executed reaches a predetermined period. the transport system includes a connection possibility detection means for detecting that the transport device is in a state in which the transport object can be connected to the connection means by moving the transport device in a direction toward the transport object as a result of the connection control being executed,
The control device of the conveying system described in claim 1, characterized in that the control device is provided with a connection movement end control means that executes connection movement end control to end the movement of the conveying device in the direction toward the conveying target based on the detection by the connection possibility detection means that the conveying device is in a state where it is possible to connect the conveying target to the connection means when the conveying device is moving in the direction toward the conveying target due to the execution of the connection control. The control device for the transport system according to claim 7, further comprising a means for executing control so that the transport target is connected to the connecting means when the movement of the transport device in the direction toward the transport target is terminated by executing the connection movement end control. The control device of the transport system according to claim 7 or 8, further comprising a means for executing a control to terminate the movement of the transport device in the direction toward the transport target, even if the connection possibility detection means does not detect that the transport target can be connected to the connection means, based on the occurrence of a movement end trigger in a situation in which the transport device is moving in the direction toward the transport target as a result of the execution of the connection control. A transport system comprising the connection means and the control device according to claim 1.

Images