JP2018111593A - Transport device - Google Patents

Abstract

PROBLEM TO BE SOLVED: To enhance safety in a transport device operated by an operator.SOLUTION: A device 1 comprises a first conveyor 9, a travel part 3, a first operation device 49A and a second operation device 49B, and a control part 31. The travel part 3 moves the first conveyor 9. The first operation device 49A and the second operation device 49B are provided to operate the travel part 3 by operators S1 and S2, and provided at positions where they cannot be operated simultaneously. The control part 31 controls the operation of the travel part 3 which cannot be operated by only one of the first operation device 49A and the second operation device 49B so as to operate when it is simultaneously operated by the first operation device 49A and the second operation device 49B.SELECTED DRAWING: Figure 12

Description

  The present invention relates to a transport apparatus, and more particularly, to a transport apparatus that performs an operation of transporting a load by an operator.

2. Description of the Related Art Conventionally, there is a transport device that transports a package, in which an operator performs an operation using an operation unit provided in the transport device. As such an apparatus, there is an apparatus for picking up an article from a truck, a shelf, or the like (see, for example, Patent Document 1).
In this apparatus, a pickup device is provided on the conveyor, and an operator instructs the pickup device to move back and forth and to the left and right by an operation lever of the operation unit.

JP 2001-163407 A

In the pickup device described in Patent Document 1, one operator can perform all operations in one place. Therefore, if there is a part that cannot be seen by the operator or a part that has been overlooked, there is a possibility that an object may be unexpectedly contacted when the apparatus is moved.
In particular, when the device is re-moved by a forced operation after the device has been urgently stopped, it is generally considered that the safety of one operator is not sufficient.
An object of the present invention is to improve safety in a transport device that is operated by an operator.

  Hereinafter, a plurality of modes will be described as means for solving the problems. These aspects can be arbitrarily combined as necessary.

A conveying apparatus according to an aspect of the present invention includes a conveying unit, a moving unit, at least two operation units, and a controller.
The moving unit moves the transport unit.
The at least two operation units are for operating the moving unit by an operator, and are provided at positions where they cannot be operated simultaneously. “It is provided at a position where at least two operation units cannot be operated at the same time” means that, depending on the positional relationship between at least two devices, other operation units are operated when an operator operates one operation unit. Means that you cannot operate.
The controller controls the operation of the moving unit that cannot be operated by one of the two operation units when the operation unit is operated simultaneously by the two operation units. In addition, the case where it operates simultaneously includes the case where a button is pressed at the same timing, the case where the other button is pressed while one side is pressing the button, etc.
In this apparatus, when the transport device cannot be operated by one worker, the two workers can operate each operation unit at the same time, so that an operation that cannot be performed by one worker can be performed. That is, two operators will operate at a fixed and safe position without movement, and as a result, the transport device can be moved safely.

The transport apparatus may further include an abnormality grasping means for grasping an abnormality of the transport apparatus.
When the abnormality is detected by the abnormality grasping means, the controller controls the moving unit not to operate by operation from one of the two operation units, and is operated simultaneously by the two operation units. In some cases, the moving unit may be controlled to operate.
In this apparatus, when the abnormality of the transfer apparatus is grasped, a single worker cannot operate the moving unit. Then, when the two operators operate each operation unit, the moving unit can be operated.

The abnormality grasping means may be an obstacle detector that detects obstacles around the transport device.
When an obstacle is detected by the obstacle detector, the controller controls so that the moving unit does not operate by an operation from one operation unit. When the controller is operated simultaneously by two operation units, the controller You may perform control which can operate a moving part with the state detected.

When an obstacle is detected by the obstacle detector, the controller may perform control capable of moving the transport unit in a direction in which the obstacle is present when the obstacle is operated simultaneously by two operation units.
In this device, when an obstacle is detected and the transport unit cannot be moved, the two operators move the transport unit in the direction of the obstacle by operating each operation unit. To be able to. That is, the transport unit is moved while ensuring safety.

The abnormality grasping means may be an area sensor that detects the lower part of the transport unit.
The transport unit may have a lifter for an operator to get on.
Two operation units may be arranged above the lifter.
When the area sensor detects that the lifter has been lowered, the controller controls so that the moving unit does not operate when operated from one operating unit, and operates the moving unit when operated simultaneously by two operating units. Then, the control may be performed so as to raise and lower the lifter.
In this apparatus, by providing an area sensor, for example, the risk of an object being caught between lifters can be reduced. When the area sensor detects the lifter, one worker cannot operate the lifter. Then, when two workers operate each operation unit, the moving unit can be operated to lower the lifter. That is, the transport unit is moved while ensuring safety.

Each of the two operation units may have a plurality of input means for inputting operation details.
The controller may include a storage unit that stores a plurality of combinations of the input units of the two operation units and the operation of the moving unit defined for each combination.
In this apparatus, when a new function is introduced, a new function can be added by a combination of existing input means. As a result, the number of parts can be reduced.

  In the transport apparatus according to the present invention, safety is improved.

1 is a perspective view of a vanning / devanning apparatus according to a first embodiment of the present invention. The side view of a vanning and a debanning apparatus. Top view of vanning and devanning. The perspective view of a vanning and a debanning apparatus. The perspective view of a vanning and a debanning apparatus. The perspective view of a vanning and a debanning apparatus. The top view of a vanning and a debanning apparatus. The block diagram which shows the control structure of a vanning and a debanning apparatus. The flowchart which shows abnormality generation | occurrence | production response control. The flowchart which shows the operation control in abnormal mode. The flowchart which shows the obstruction detection control at the time of forward running operation | movement of a vanning / devanning apparatus. The schematic plan view which shows one state at the time of forward running operation | movement of a vanning and a debanning apparatus. The flowchart which shows the obstacle detection corresponding control at the time of the descent | fall operation | movement of a work table. The schematic side view which shows one state at the time of the descent | fall operation | movement of a worktable.

1. First Embodiment (1) Mechanism Configuration of Vanning / Devanning Device A vanning / devanning device 1 (hereinafter referred to as “device 1”) of the first embodiment will be described with reference to FIGS. FIG. 1 is a perspective view of a vanning / devanning apparatus according to a first embodiment of the present invention. FIG. 2 is a side view of the vanning and devanning apparatus. FIG. 3 is a top view of the vanning and devanning.
The device 1 is used to execute, for example, unloading a load W from a container (devanning) or loading a load W into a container (vanning), for example. As shown in FIG. 2, the worker S1 loads the load W into the apparatus 1 from, for example, a container. Then, the apparatus 1 moves the load W by a predetermined distance by the conveyor 5 (described later). Thereafter, the worker S2 unloads the load from the conveyor 5. The worker S2 loads the cargo W onto another conveyor or loads it on a pallet.

  The device 1 has a traveling unit 3. The traveling unit 3 is a known technique, and includes a traveling unit body, traveling wheels, a traveling motor, and a power transmission unit. Thereby, the traveling unit 3 can turn forward, backward, and right and left. Further, the traveling unit 3 can travel at a low speed and a high speed.

The device 1 has a conveyor 5. The conveyor 5 is a device that conveys the load W from the load input portion to the load discharge portion with the load W placed on the upper surface.
The conveyor 5 is composed of a plurality of conveyors that can operate independently. Specifically, the conveyor 5 includes a first conveyor 9, a second conveyor 11, a third conveyor 13, a fourth conveyor 15, and a fifth conveyor 17. The first to fourth conveyors 9, 11, 13, 15 are driven by separate motors. The fifth conveyor 17 is a free roller. However, the fifth conveyor 17 may be driven by a motor. Moreover, the 4th conveyor 15 may be a free roller similarly to the 5th conveyor 17, and a motor drive may be sufficient as it.

The first conveyor 9 realizes a luggage input unit for the worker S1 to place the luggage W. In this embodiment, the first conveyor 9 is a belt conveyor. The first conveyor 9 is disposed, for example, inside a container or a truck when performing vanning or devanning.
The second conveyor 11 is continuous from the first conveyor 9 and has a relatively long configuration. In this embodiment, the second conveyor 11 is a belt conveyor.

The third conveyor 13 is continuous from the second conveyor 11 and has a relatively short configuration. In this embodiment, the third conveyor 13 is a roller conveyor.
The 4th conveyor 15 is following the 3rd conveyor 13, and is a comparatively short structure. In this embodiment, the fourth conveyor 15 is a roller conveyor. In addition, the 4th conveyor 15 may become long depending on the container length or the waiting position of worker S2.
The fifth conveyor 17 is continuous from the fourth conveyor 15 and has a relatively short configuration. In this embodiment, the fifth conveyor 17 is a roller conveyor. The fifth conveyor 17 realizes a luggage discharge unit for the operator S2 to take out the luggage W.

The apparatus 1 has a work table 7 (an example of a lifter) on which an operator gets. The work table 7 is disposed below the first conveyor 9. When the worker S1 gets on the work table 7, the load W can be placed on the first conveyor 9.
The work table 7 extends in the left-right direction. Therefore, when the first conveyor 9 is near the center position in the left-right direction of the work table 7, the workers S1 and S2 (see FIG. 12) are on both sides of the first conveyor 9. Can stand in.

The first conveyor 9 needs to be movable in the vertical direction according to the position of the load when the worker S1 loads the load W on the conveyor 5. As a structure for this purpose, the base end of the second conveyor 11 is attached to the traveling unit 3 so as to be rotatable about a rotation axis extending in the left-right direction. Furthermore, the conveyor raising / lowering part 8 which rotates the base end of the 2nd conveyor 11 is provided. The conveyor lifting / lowering unit 8 is a known technique for driving the first conveyor 9 up and down, and includes a lifting / lowering motor, a rotation driving unit including a plurality of gears, and the like. Thereby, worker S1 can move the 1st conveyor 9 to the up-and-down desired position.
FIG. 4 shows a state where the first conveyor 9 is disposed above, and FIGS. 5 and 6 illustrate a state where the first conveyor 9 is disposed below. 4 to 6 are perspective views of the vanning and devanning apparatus.

The first conveyor 9 needs to be movable in the left-right direction according to the position of the load when the worker S1 loads the load W on the conveyor 5. As a structure for this purpose, the base end of the second conveyor 11 is attached to the traveling unit 3 so as to be rotatable about a rotation axis extending in the vertical direction. More specifically, the various structures of the conveyor elevating unit 8 described above are rotatable with respect to the traveling unit 3. Thereby, worker S1 can move the 1st conveyor 9 to the left and right desired positions manually, for example.
FIG. 7 shows a state in which the first conveyor 9 is moved to one side in the left-right direction. FIG. 7 is a top view of the vanning and devanning apparatus.

The work table 7 needs to be movable in the vertical direction according to the position of the first conveyor 9 when the worker S1 loads the cargo W onto the conveyor 5. As a structure for that purpose, the work table 7 is connected to the traveling unit 3 by a work table elevating unit 10. The work table elevating unit 10 is a known technique for moving the work table 7 up and down, and includes a cylinder, a drive direction conversion mechanism, and the like. Thereby, worker S1 can move work table 7 to a desired position up and down.
The device 1 includes a first operating device 49A and a second operating device 49B. The first operating device 49A and the second operating device 49B are devices for inputting an operation signal for the worker S1 to operate the device 1, and are mechanical button devices. However, the operation device may be another input device such as a touch panel.

In this embodiment, the first operating device 49 </ b> A and the second operating device 49 </ b> B are provided in the vicinity of the first conveyor 9 and above the work table 7. Specifically, the first operating device 49 </ b> A and the second operating device 49 </ b> B are arranged on the left and right sides of the first conveyor 9. Accordingly, the first operating device 49A and the second operating device 49B cannot be operated simultaneously by one operator. In other words, since the distance between the first operating device 49A and the second operating device 49B is long, the operator cannot operate the other operating device from the position where one operating device is operated. As another example, an operation restriction structure such as a shielding plate may be provided between the two operation devices so that the operator cannot operate the other operation device from a position where one operation device is operated.
It should be noted that the first operating device 49A and the second operating device 49B are depicted in the drawings having only the configuration shown in FIGS. 1 to 3, and are omitted in FIGS.

  On the first operating device 49A, a conveyor up button 51A, a conveyor down button 53A, a work table up button 55A, a work table down button 57A, and a forward travel button 67A (see FIG. 8) are displayed. The second operating device 49B displays a conveyor up button 51B, a conveyor down button 53B, a work table up button 55B, a work table down button 57B, and a forward travel button 67B (see FIG. 8). The operation buttons described above are merely examples, and other buttons are provided as necessary.

(2) Control Configuration of the Vanning / Devanning Device The control configuration of the device 1 will be described with reference to FIG. FIG. 8 is a block diagram showing a control configuration of the vanning / devanning apparatus.
The device 1 includes a control unit 31 (an example of a controller). The control unit 31 includes a processor (eg, CPU), a storage device (eg, ROM, RAM, HDD, SSD, etc.), and various interfaces (eg, A / D converter, D / A converter, communication interface, etc.). It is a computer system. The control unit 31 performs various control operations by executing a program stored in the storage unit (corresponding to a part or all of the storage area of the storage device).

The control unit 31 may be configured by a single processor, but may be configured by a plurality of independent processors for each control.
Some or all of the functions of each element of the control unit 31 may be realized as a program that can be executed by a computer system that configures the control unit 31. In addition, some of the functions of the elements of the control unit 31 may be configured by a custom IC.

The controller 31 is connected to the conveyor raising button 51A, the conveyor lowering button 53A, the work table raising button 55A, the forward traveling button 67A, and the work table lowering button 57A of the first operating device 49A. The control unit 31 is connected to the conveyor raising button 51B, the conveyor lowering button 53B, the work table raising button 55B, the forward traveling button 67B, and the work table lowering button 57B of the second operating device 49B. Although not shown, a reverse travel button, a travel stop button, and the like are also provided.
While the conveyor raising button 51A or 51B is being pressed, the first conveyor 9 is raised. While the conveyor lowering button 53A or 53B is being pressed, the first conveyor 9 is lowered. While the work table raising button 55A or 55B is being pressed, the work table 7 is raised. While the work platform lowering button 57A or 57B is being pressed, the work platform 7 is lowered.
While the forward travel button 67A or 67B is being pressed, the device 1 travels forward.

Furthermore, a conveyor vertical position sensor 12 and a work table vertical position sensor 14 are connected to the control unit 31. The conveyor vertical position sensor 12 and the work table vertical position sensor 14 are encoders, for example.
Further, an angle sensor 61 is connected to the control unit 31. The angle sensor 61 is a sensor for detecting the rotation angle (rotation angle in the horizontal plane) around the vertical axis of the second conveyor 11 and is, for example, an encoder.

A laser scanner 77 is connected to the control unit 31. The laser scanner 77 is an obstacle detector that detects the presence and position of peripheral objects existing around the device 1 (specifically, the first conveyor 9 and the lower part of the periphery) (for detecting abnormalities in the device 1). An example of abnormality grasping means).
The laser scanner 77 is a non-contact type distance measuring device. As shown in FIG. 3, the laser scanner 77 is attached to the front part of the traveling unit 3 and detects the presence of an object within a scan angle (detection area). More specifically, the laser scanner 77 is disposed near the rear of the work table 7.
The laser scanner 77 is, for example, a light projecting mirror and a light receiving mirror that face in the same direction and are simultaneously rotated by a motor, a light projecting element that irradiates a detection object with high-frequency pulsed light through the light projecting mirror, and a reflection thereof. The light receiving element is configured to receive light through a light receiving mirror.

The principle of distance detection of the laser scanner 77 is as follows. The light projecting mirror and the light receiving mirror are rotated by a motor. At every predetermined pitch, the phase delay of the pulsed light emitted from the light projecting element, reflected by the detection object and returned to the light receiving element is measured.
The control unit 31 registers a plurality of detection area patterns within the measurement range of the laser scanner 77. As will be described later, the control unit 31 selects and sets a pattern to be used from among a plurality of detection area patterns in accordance with the rotation angle in the horizontal plane of the first conveyor 9 (that is, the detection area pattern is determined). Switched). The control unit 31 determines that the object has been detected when the distance to the detected object is within the pattern of the selected detection area. In this way, object detection by an appropriate detection area is possible for each rotation angle in the horizontal plane of the first conveyor 9.

Further, an alarm device 79 is connected to the control unit 31. The alarm device 79 is a speaker, a lamp or the like for notifying an operator of an abnormal state.
Further, although not shown, the control unit 31 is connected to sensors and switches for detecting the state of each device, and an information input device.
The control unit 31 is connected to the traveling unit 3, the conveyor elevating unit 8, and the work table elevating unit 10. The control unit 31 transmits a drive signal and a stop signal to the traveling unit 3, the conveyor elevating unit 8, and the work table elevating unit 10.

(3) Control operation when grasping abnormality The control flowchart described below is an example, and each step can be omitted or replaced as necessary. Also, a plurality of steps may be executed simultaneously, or some or all of them may be executed in an overlapping manner.
Furthermore, each block of the control flowchart is not limited to a single control operation, and can be replaced with a plurality of control operations represented by a plurality of blocks.

(3-1) Schematic description of abnormality occurrence response control The abnormality occurrence response control will be schematically described with reference to FIGS. 9 and 10. FIG. 9 is a flowchart showing abnormality occurrence response control. FIG. 10 is a flowchart showing operation control in the abnormal mode.
In step S <b> 1 of FIG. 9, it is determined whether or not an abnormality has occurred in the apparatus 1 while the transport unit is moving. Specifically, the control unit 31 determines whether or not an abnormality has occurred based on the detection signal of any one of the sensors. If an abnormality has occurred, the process proceeds to step S2.
In step S2, the apparatus 1 is set to the abnormal mode. Specifically, the control unit 31 switches the device 1 from the normal mode to the abnormal mode. In the abnormal mode, the movement of the transport unit before the occurrence of the abnormality is stopped, and further, input from only one of the first operating device 49A and the second operating device 49B (an example of two operating units) is invalidated. Is set as follows. That is, in order to forcibly operate in the abnormal mode, simultaneous input from the first operating device 49A and the second operating device 49B is required.

In step S3, it is determined whether or not the abnormal state has been recovered. Specifically, based on the detection signal of any sensor or the input signal of the input device, the control unit 31 determines whether or not there is a recovery from the abnormal state. If recovered, the process proceeds to step S4.
In step S4, the normal mode is set. Specifically, the control unit 31 switches the abnormal mode to the normal mode. In the normal mode, the input from one of the first operating device 49A and the second operating device 49B is set to be valid.

The operation control in the abnormal mode will be described with reference to FIG.
In step S5 of FIG. 10, it is determined whether or not the first operating device 49A and the second operating device 49B are operated simultaneously. Specifically, the control unit 31 makes the above determination based on operation signals from the first operating device 49A and the second operating device 49B. If operated simultaneously, the process moves to step S6. In cases other than simultaneous operation (when only one unit is operated or no operation is performed), the process proceeds to step S8.
In step S6, an operation based on the above-described operation (that is, movement of the transport unit) is executed. Specifically, the control unit 31 transmits a control signal to the target device, and the device executes an operation.

In step S7, it is determined whether or not the abnormal state has been recovered by the forcible operation by the two workers described above. Once recovered, the process ends. If not recovered, the process returns to step S5.
In step S8, the movement of the transport unit described above is stopped. Specifically, the control unit 31 transmits a control signal to the target device, and the device stops operating.
As described above, when one of the workers S1 or S2 cannot operate the device 1, two workers S1 and S2 operate the first operating device 49A and the second operating device 49B simultaneously. By doing so, operations that cannot be performed by one person can be executed. That is, two workers S1 and S2 are operated at a fixed and safe position, and as a result, the apparatus 1 can be moved safely.

  As described above, the override (forced operation) from the emergency stop requires the simultaneous operation of the workers S1 and S2. Therefore, the workers S1 and S2 can confirm that the surrounding area is safe by confirming from the left and right operation locations, thereby eliminating the blind spots. Also, it is safer to judge with two workers than to judge with one worker. Thus, the safety is improved by the dispersion of the operation parts.

(3-2) Specific example 1 (abnormality detection control during forward travel)
The abnormality detection control during forward traveling will be described as a specific example 1 with reference to FIGS. 11 and 12. FIG. 11 is a flowchart showing the obstacle detection control during the forward traveling operation of the vanning / devanning apparatus. FIG. 12 is a schematic plan view showing a state during forward traveling operation of the vanning / devanning apparatus.

The operation when the device 1 is traveling forward will be described. For example, as shown in FIG. 12, workers S <b> 1 and S <b> 2 are traveling forward on the apparatus 1, that is, the first conveyor 9 (an example of a transport unit). Specifically, the operator S1 or S2 presses the forward travel button 67A or 67B, and the control unit 31 transmits a control signal to the travel unit 3 (an example of a moving unit) to drive the travel unit 3. The control unit 31 detects an obstacle using the laser scanner 77 when the apparatus 1 travels. In FIG. 12, a wall S exists diagonally forward to the right.
In step S11 of FIG. 11 (corresponding to step S1 of FIG. 9), it waits for an obstacle to be detected by the laser scanner 77 (an example of grasping an abnormality). In the above example, the wall S is detected. Specifically, a wall S exists in the intrusion prohibited area D of the laser scanner 77.

In step S12, the alarm device 79 issues an alarm. Specifically, the control unit 31 (an example of a controller) transmits a control signal to the alarm device 79. Thereby, worker S1 or S2 knows that wall S was detected.
In step S13 (corresponding to step S2 in FIG. 9), an emergency stop (deadlock) is performed. Specifically, the control unit 31 transmits a stop signal to the traveling unit 3 to stop traveling, and further changes the setting of the device 1 from the normal mode to the abnormal state mode. As a result, after that, even if the worker S1 or the worker S2 presses one of the forward travel buttons 67A and 67B, it does not function. In this case, even if one of the reverse travel buttons (not shown) is pressed, it may not function.

In step S14 (corresponding to step S5 in FIG. 10), for example, it is determined whether or not the forward travel buttons 67A and 67B of the first operating device 49A and the second operating device 49B are pressed simultaneously. Specifically, the control unit 31 makes the determination based on signals from, for example, forward travel buttons 67A and 67B. If operated simultaneously, the process moves to step S15. In cases other than simultaneous operation (when only one unit is operated or no operation is performed), the process proceeds to step S17.
In step S15 (corresponding to step S6 in FIG. 10), for example, the forward movement operation of the device 1 is performed. Specifically, the control unit 31 transmits a control signal to the traveling unit 3 to start traveling. In other words, when the two operators S1 and S2 operate the first operating device 49A and the second operating device 49B at the same time, a forcible operation is performed to operate the traveling unit 3 while the wall S is detected. it can. As an example, after an emergency stop, workers S1 and S2 can move the device 1 in a direction in which the wall S is located. This operation is actually performed when it is determined that the worker S1 and the worker S2 can move the device 1 forward without colliding with the wall S. In addition, said restoration operation | movement may include simultaneous operation of other buttons besides a forward travel button, and may be performed by simultaneous operation of only other buttons other than a forward travel button.
In step S16 (corresponding to step S7 in FIG. 10), it is determined whether or not the abnormal state has been recovered by the forced operation by the two workers described above. Once recovered, the process ends. If not recovered, the process returns to step S14.

In step S17, the aforementioned operation is stopped. Specifically, the control unit 31 transmits a control signal to the traveling unit 3 to stop, for example, forward traveling of the device 1. That is, if either the operator S1 or S2 releases his / her hand from, for example, the forward travel buttons 67A and 67B, the apparatus 1 stops again.
As described above, after the emergency stop, in order to advance the apparatus 1 in a certain direction of the wall S (that is, to perform a forced operation for disabling the laser scanner 77), the simultaneous operations of the workers S1 and S2 are performed. As a condition. As a result, during the forced operation, the workers S1 and S2 are operated at a fixed and safe position, so that the apparatus 1 can be moved safely.

(3-3) Specific example 2 (abnormality detection control when the work table is lowered)
An abnormality detection control when the work table is lowered will be described as a specific example 2 with reference to FIGS. 13 and 14. FIG. 13 is a flowchart showing the obstacle detection response control when the work table is lowered. FIG. 14 is a schematic side view showing one state when the work table is lowered.

An operation when the work table 7 of the apparatus 1 is lowered to the lower end position will be described. For example, as shown in FIG. 14, workers S <b> 1 and S <b> 2 lower the work table 7. Specifically, the operator S1 or S2 presses the work table lowering button 57A or 57B, and the control unit 31 transmits a control signal to the work table lifting unit 10 to drive the work table 7.
In step S <b> 21 of FIG. 13, the laser scanner 77 detects that the lowered work table 7 is mistaken when there is an object below the work table 7.

In step S22, the laser scanner 77 is temporarily disabled (muting). Specifically, the control unit 31 temporarily disables the detection of the laser scanner 77. In addition, when invalidation (muting) is functioning, it can be operated by one worker.
In step S23, muting is canceled according to a predetermined condition. The predetermined condition is when the area of the laser scanner 77 is switched during muting or when the power is turned off and turned on again.
In step S24 (corresponding to step S1 in FIG. 9), the work table 7 is detected as an obstacle by the laser scanner 77 (an example of grasping an abnormality).

In step S25, the warning device 79 issues a warning by sound or light. Specifically, the control unit 31 transmits a control signal to the alarm device 79. Thereby, the worker S1 or S2 knows that the workbench 7 has been detected.
In step S26 (corresponding to step S2 in FIG. 9), an emergency stop (deadlock) is performed. Specifically, the control unit 31 transmits a stop signal to the work table elevating unit 10 to stop the descent, and further changes the setting of the apparatus 1 from the normal mode to the abnormal state mode. As a result, after that, even if the worker S1 or the worker S2 presses one of the work platform lowering buttons 57A and 57B and one of the work platform raising bodies 55A and 55B, it does not function.

In step S27 (corresponding to step S5 in FIG. 10), whether or not each set of the work platform lowering buttons 57A and 57B or the work platform raising buttons 55A and 55B of the first operating device 49A and the second operating device 49B is pressed simultaneously. Is judged. Specifically, the control unit 31 makes the determination based on signals from the buttons. If operated simultaneously, the process moves to step S28. In cases other than simultaneous operation (when only one unit is operated or no operation is performed), the process proceeds to step S30.
In step S28 (corresponding to step S6 in FIG. 10), the work table 7 is moved up and down. Specifically, the control unit 31 transmits a control signal to the work table elevating unit 10 to elevate the work table 7. In other words, two workers S1 and S2 simultaneously operate the first operating device 49A and the second operating device 49B to execute a forcible operation to raise and lower the work table 7 while an obstacle is detected. it can. This is actually performed when it is determined that the work table 7 can be further lowered without the operator S1 and the worker S2 pinching an object.

In step S29 (corresponding to step S7 in FIG. 10), it is determined whether or not the abnormal state has been recovered by the above-mentioned forced operation by two workers. Once recovered, the process ends. If not recovered, the process returns to step S27. For example, if the work table 7 is raised to a height that cannot be detected by the laser scanner 77 by simultaneously pressing the work table raising bodies 55A and 55B in step S28, the work table 7 is not detected by the laser scanner 77 in step S29. As a result, it is determined that the system has recovered from the abnormal state.
In step S30, the aforementioned operation is stopped. Specifically, the control unit 31 transmits a control signal to the work table elevating unit 10 to stop the operation of the work table 7. That is, if either worker S1 or S2 releases the simultaneous operation button, the work table 7 stops moving up and down again.
As described above, after the emergency stop, in order to forcibly lower the workbench 7 (that is, to perform the forcible operation for disabling the laser scanner 77), the simultaneous operation of the workers S1 and S2 is a condition. Yes. As a result, during the forced operation, the workers S1 and S2 are operated at a fixed and safe position, and as a result, the work table 7 can be moved safely.

(4) Application of operation device As described above, each of the first operation device 49A and the second operation device 49B has a plurality of buttons (an example of a plurality of input means) for inputting operation details. .
The control unit 31 stores a plurality of combinations of buttons of the first operating device 49A and the second operating device 49B and operations of each moving device (an example of a moving unit) defined for each combination ( (Not shown).

For example, three types of combinations of one button of the first operating device 49A and one button of the second operating device 49B and three operations of the moving device are associated with each other and stored in the storage unit. Specifically, when only one button of the first operating device 49A is pressed, the conveyor lifting unit 8 raises the first conveyor 9 at a low speed. When only one button of the second operating device 49B is pressed, the conveyor lifting unit 8 raises the first conveyor 9 at a medium speed. If both one button of the first operating device 49A and one button of the second operating device 49B are pressed, the conveyor lifting unit 8 raises the first conveyor 9 at a high speed.
As described above, the combination of buttons and the operation of the moving unit operated by the combination can be stored in the storage unit. Therefore, when a new function is introduced, a new function can be input using an existing button. As a result, the number of parts can be reduced.

2. Features of Embodiments The device 1 (an example of a transport device) includes a first conveyor 9 (an example of a transport unit), a traveling unit 3 (an example of a moving unit), a first operating device 49A, and a second operating device 49B (at least An example of two operation units) and a control unit 31 (an example of a controller) are provided.
The traveling unit 3 moves the first conveyor 9.
The first operating device 49A and the second operating device 49B are for operating the traveling unit 3 by the workers S1 and S2, and are provided at positions where they cannot be operated simultaneously.
When the operation of the traveling unit 3 that cannot be operated by one of the first operating device 49A and the second operating device 49B is simultaneously operated by the first operating device 49A and the second operating device 49B. Control to operate.

  In this apparatus 1, when the first conveyor 9 cannot be operated by one worker, the two workers S1 and S2 operate the first operating device 49A and the second operating device 49B at the same time. Can perform actions that humans cannot perform. That is, two workers S1 and S2 are operated at a fixed and safe position, and as a result, the apparatus 1 can be moved safely.

3. Other Embodiments Although a plurality of embodiments of the present invention have been described above, the present invention is not limited to the above embodiments, and various modifications can be made without departing from the scope of the invention. In particular, a plurality of embodiments and modifications described in this specification can be arbitrarily combined as necessary.
The conveying device is not limited to a vanning / devanning device. The transport device may be, for example, a stacker crane, a ground traveling carriage, or the like.
Abnormality detection during travel of the apparatus is not limited to forward travel, and can be applied to reverse travel, for example.
Abnormality detection when raising and lowering the workbench is not limited to lowering, but can be applied to raising, for example.

The type, number, mounting method, and mounting position of the operation device are not limited to the above embodiment. For example, three or more operating devices may be provided.
The operating device may include a retrofit that can be attached as necessary.
The operation device may include a simple switch.
The operating device may be a plurality of remote controllers connected to the transport device.
Examples of emergency stop and forced operation of the device widely include emergency stop due to sensor failure or misrecognition and subsequent forced operation.

  The present invention can be widely applied to a transfer device that performs a load transfer operation by an operator's operation.

1: Vanning and devanning device 3: Traveling unit 5: Conveyor 7: Work table 8: Conveyor lifting unit 9: First conveyor 10: Work table lifting unit 11: Second conveyor 12: Conveyor vertical position sensor 13: Third conveyor 14 : Work table vertical position sensor 15: Fourth conveyor 17: Fifth conveyor 31: Controller 49A: First operating device 49B: Second operating device 51A: Conveyor up button 51B: Conveyor up button 53A: Conveyor down button 53B: Conveyor Down button 55A: Work table up button 55B: Work table up button 57A: Work table down button 57B: Work table down button 61: Angle sensor 67A: Forward travel button 67B: Forward travel button 77: Laser scanner 79: Alarm device S1: Worker S2: Worker W: Luggage

Claims (6)

A transport section;
A moving unit for moving the conveying unit;
For operating the moving unit by an operator, at least two operating units provided at a position where the operator cannot operate at the same time;
A controller that controls the operation of the moving unit that cannot be operated by one of the two operation units to be operated when operated simultaneously by the two operation units;
A transport apparatus comprising: It further comprises an abnormality grasping means for grasping the abnormality of the transfer device,
When the abnormality is grasped by the abnormality grasping means, the controller controls the moving unit not to operate by an operation from one of the two operation units, and the two operation units The conveying apparatus according to claim 1, wherein the moving unit is controlled to operate when operated simultaneously. The abnormality grasping means is an obstacle detector that detects obstacles around the transport device,
When the obstacle is detected by the obstacle detector, the controller controls the moving unit not to be operated by the operation from the one operation unit, and is operated by the two operation units at the same time. In this case, the transfer device according to claim 2, wherein control is performed so that the moving unit can be operated while the obstacle is detected.   When the obstacle is detected by the obstacle detector, the controller performs control that can move the transport unit in a direction in which the obstacle is present when the two operation units are operated simultaneously. The conveyance apparatus of Claim 3 to perform. The abnormality grasping means is an area sensor that detects a lower part of the transport unit;
The transport unit has a lifter for an operator to ride,
The two operation units are arranged above the lifter,
When the area sensor detects that the lifter is lowered, the controller controls the moving unit not to operate by an operation from the one operating unit, and is operated by the two operating units simultaneously. The conveying apparatus according to claim 2, wherein the moving unit is operated to control the lifter to move up and down. Each of the two operation units has a plurality of input means for inputting operation details,
The said controller has a memory | storage part which memorize | stores the several combination of the said input means of the said 2 operation parts, and operation | movement of the said movement part prescribed | regulated for every said combination. The conveying apparatus as described in.

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