KR20220135292A - Apparatus for controlling drive of transport vehicle wheel in article transport system and method thereof - Google Patents

Abstract

According to an embodiment of the present invention, a device and method capable of preventing load or vibration applied to a transport vehicle and an article loaded therein are provided by configuring an operation mode of a front wheel or rear wheel of the transport vehicle to be switched at all times according to a driving environment of the transport vehicle. The device for switching an operation mode of a transport vehicle wheel in an article transporting system comprises: a processing unit receiving information on a moving path of the transport vehicle; a motion controlling unit generating a drive signal including a speed signal and a torque signal for driving front and rear wheels of the transport vehicle for a drive along a moving path; a front wheel driving unit controlling driving of the front wheel based on the speed signal; and a rear wheel driving unit controlling driving of the rear wheel based on one of the speed signal and the torque signal according to an operation mode. Here, the motion controlling unit may determine the operation mode of the rear wheel driving unit based on the moving path of the transport vehicle. Accordingly, load or vibration applied to the transport vehicle and the article loaded on the transport vehicle can be prevented.

Description

Apparatus and method for controlling the driving of a transport vehicle in a goods transport system

The present invention relates to an apparatus and method for controlling driving of a conveying vehicle in an article conveying system, and more particularly, to an apparatus and method for controlling an operation manner of a wheel in a conveying vehicle.

A semiconductor (or display) manufacturing process is a process for manufacturing a semiconductor device on a substrate (eg, a wafer), and includes, for example, exposure, deposition, etching, ion implantation, cleaning, packaging, and the like. A manufacturing plant for manufacturing a semiconductor device consists of one or more layers of clean rooms, and manufacturing facilities for performing a semiconductor manufacturing process are disposed on each layer.

In order to maximize the efficiency of the semiconductor manufacturing process, not only a method for improving each semiconductor manufacturing process, but also a technique for rapidly and efficiently transporting articles (eg, substrates) between manufacturing facilities has been introduced. Typically, an overhead hoist transport (OHT) system that transports goods along a path installed on the ceiling of a semiconductor manufacturing plant is being applied. In general, the OHT system includes a rail constituting a travel route, and a transport vehicle that travels along the rail and transports goods. In addition, when it is necessary to store an article during transport between semiconductor manufacturing facilities, a storage system for storing the article may be provided.

On the other hand, the transport vehicle travels and stops in order to perform the assigned task to transfer and load goods, and repeats these running and stopping operations. In addition, the path through which the transport vehicle moves may be configured in multiple layers, and may include various types of paths such as straight lines or curves, branching or merging. The transport vehicle includes a wheel including a front wheel mounted on the front side of the vehicle body and a rear wheel mounted on the rear side of the vehicle body for traveling along a vehicle body and rails, and a wheel axle on which a pair of wheels are mounted on both ends.

In general, when the transport vehicle travels on a travel path, the front wheels and the rear wheels of the transport vehicle travel in the speed control mode so that they have the same fixed speed (revolution speed). In addition, when the transport vehicle travels on a straight path, both the front and rear wheels of the transport vehicle travel along the driving rail using only the driving wheels, but may enter or depart from a non-linear path such as a curve, divergence, or merging. At this time, at least one of the front wheel and the rear wheel of the transport vehicle is driven along the auxiliary rail provided above the traveling rail by using the auxiliary wheel located outside the traveling wheel.

For example, when the transport vehicle enters a non-linear section (e.g., branch, curve, merging), the auxiliary wheel of the inner front wheel comes into contact with the auxiliary rail (refer to Fig. 7(b)), and the outer wheel of the front wheel It is in a floating state without contacting the rail, and since the rear wheel is still in a straight section, the driving wheels of both side (outer and inner) wheels are still in contact with the running rail (refer to FIG. 7(a) ). On the other hand, when the transport vehicle departs from a non-linear section, the front wheels enter a straight section, the driving wheels on both sides come into contact with the driving rail 110 , and the rear wheels exist in a section that is not yet straight, so The auxiliary wheel comes into contact with the auxiliary rail (refer to FIG. 7(c)).

A difference occurs between the moving distance of the auxiliary wheel and the moving distance of the traveling wheel due to the characteristics of the wheel shaft rotating at the same rotation speed and the size difference between the auxiliary wheel and the traveling wheel. Therefore, a speed difference occurs between the front wheel and the rear wheel, and the speed difference causes mutual interference such as load and vibration, and may affect the quality of goods loaded in the transport vehicle.

Republic of Korea Patent Publication No. 10-1901029 (September 21, 2018) Republic of Korea Patent Publication No. 10-1425122 (2014.07.24)

Accordingly, in order to solve the above problems, an embodiment of the present invention is to provide an apparatus and method capable of constantly changing the control method of each wheel according to the driving environment of the transport vehicle.

The problems to be solved of the present invention are not limited to those mentioned above, and other problems not mentioned will be clearly understood by those skilled in the art from the following description.

An apparatus for controlling driving of a transport vehicle in an article transport system according to an embodiment of the present invention includes: a processing unit configured to receive information on a movement path of the transport vehicle; a motion control unit generating a driving signal including a speed signal and a torque signal for driving the front and rear wheels of the transport vehicle for driving along the moving path; a front wheel drive unit controlling driving of the front wheel based on the speed signal; and a rear wheel drive unit configured to control driving of the rear wheel based on one of the speed signal and the torque signal according to an operation mode. In this case, the motion control unit may determine the operation mode of the rear wheel drive unit based on a movement path of the transport vehicle.

In an embodiment, the motion control unit may set the operation mode of the rear wheel drive unit based on whether the movement path of the transport vehicle is a straight line.

In an embodiment, the motion control unit sets the operation mode of the rear wheel drive unit to a speed control mode when the movement path is a straight line, and sets the operation mode of the rear wheel drive unit to a torque control mode when the movement path is not a straight line can

In an embodiment, the operation mode of the rear wheel drive unit may be switched when the movement path is changed from a straight path to a non-linear path or when the movement path is changed from a non-linear path to a straight path.

In this case, the torque of the rear wheel may be controlled by a torque signal generated by the motion controller.

The torque signal may be a preset value or a value that is fed back by driving the front wheels.

Meanwhile, the front wheel drive unit controls driving of the front wheel based on one of the speed signal or the torque signal according to an operation mode, the rear wheel drive unit controls driving of the rear wheel based on the speed signal, and the motion control unit may determine the operation mode of the front wheel drive unit based on a movement path of the transport vehicle.

An apparatus for controlling driving of a transport vehicle in an article transport system according to an embodiment of the present invention includes: a processing unit configured to receive information on a movement path of the transport vehicle; a motion control unit generating a driving signal including a speed signal and a torque signal for driving the front and rear wheels of the transport vehicle for driving along the moving path; a front wheel drive unit for controlling driving of the front wheel based on one of the speed signal and the torque signal according to an operation mode; and a rear wheel drive unit configured to control driving of the rear wheel based on one of the speed signal and the torque signal according to an operation mode. In this case, the motion control unit may determine the operation mode of the front wheel drive unit and the rear wheel drive unit based on the slope of the speed signal.

In an embodiment, when the transport vehicle accelerates, the motion controller may set the operation mode of the front wheel drive unit to a speed control mode and the operation mode of the rear wheel drive unit to a torque control mode.

In an embodiment, when the transport vehicle decelerates or stops, the motion controller may set the operation mode of the front wheel drive unit to a torque control mode and the operation mode of the rear wheel drive unit to a speed control mode.

A method for controlling driving of a transport vehicle in an article transport system according to an embodiment of the present invention includes: acquiring information on a movement path of the transport vehicle; generating a position signal for determining a position of the transport vehicle along the movement path; generating a speed signal for determining a speed of the transport vehicle based on the position signal; determining an operation mode of the wheel driving unit based on the information on the movement path; and switching the operation mode of the rear wheel drive unit according to the determined operation mode and driving the transport vehicle.

The determining of the operation mode may include setting an operation mode of the rear wheel drive unit based on whether the movement path is a straight line.

The setting of the operation mode of the rear wheel drive unit may include setting the operation mode of the rear wheel drive unit to a speed control mode when the movement path is a straight line, and torque control the operation mode of the rear wheel drive unit if the movement path is not a straight line It may include the step of setting the mode.

A method for controlling driving of a transport vehicle in an article transport system according to an embodiment of the present invention includes: acquiring information on a movement path of the transport vehicle; generating a position signal for determining a position of the transport vehicle along the movement path; generating a speed signal for determining a speed of the transport vehicle based on the position signal; determining an operation mode of the wheel driving unit based on the slope of the speed signal; and switching the operation modes of the front wheel drive unit and the rear wheel drive unit based on the determined operation mode and driving the transport vehicle.

The determining of the operation mode may include setting an operation mode of the front-wheel drive unit to a speed control mode when the transport vehicle accelerates, setting an operation mode of the rear-wheel drive unit to a torque control mode, and when the transport vehicle decelerates. and setting the operation mode of the front wheel drive unit to a torque control mode and setting the operation mode of the rear wheel drive unit to a speed control mode.

According to an embodiment of the present invention, the traveling rail installed on the ceiling; a transport vehicle running along the running rail; An overhead hoist transport (OHT) including a higher level control device for instructing the transport vehicle may be provided. The transport vehicle includes: an article holding unit for receiving and holding the article from the manufacturing facility; a driving unit that travels along the traveling rail; a control unit for controlling the article holding unit and the driving unit, wherein the control unit includes: a processing unit for receiving a command for the conveying vehicle and information on a movement path of the conveying vehicle; a motion control unit generating a driving signal including a speed signal and a torque signal for driving the front and rear wheels of the transport vehicle for driving along the moving path; a front wheel drive unit controlling driving of the front wheel based on the speed signal; and a rear wheel drive unit configured to control driving of the rear wheel based on one of the speed signal or the torque signal according to an operation mode, wherein the motion control unit includes the rear wheel drive unit based on a movement path of the transport vehicle or the speed signal can determine the operation mode of

According to an embodiment of the present invention, a load or vibration ( That is, mutual interference between the front and rear wheels) can be prevented.

In addition, according to an embodiment of the present invention, it is possible to prevent the transport vehicle from slipping by moving the center of gravity of the transport vehicle by controlling the operation method of the front wheels or the rear wheels based on the acceleration of the transport vehicle.

In addition, according to an embodiment of the present invention, when the transport vehicle is traveling, the operation method of the wheels (front and/or rear wheels) is arbitrarily switched or switched according to a certain condition according to the driving situation, so that the speed between the front and rear wheels of the transport vehicle is changed. By preventing a vehicle, vibrations generated during driving can be attenuated, thereby reducing vibrations and shocks applied to goods loaded in a transported vehicle.

Effects of the present invention are not limited to those mentioned above, and other effects not mentioned will be clearly understood by those skilled in the art from the following description.

1 shows an example of an article conveying system in a manufacturing plant according to an embodiment of the present invention.
2 and 3 show a transport vehicle according to an embodiment of the present invention.
4 is a schematic block diagram illustrating driving of a transport vehicle according to an embodiment of the present invention.
5 is a schematic configuration diagram for explaining driving control of a transport vehicle according to an embodiment of the present invention.
6 shows an example of a method of switching an operation mode of a wheel of a transport vehicle according to an embodiment of the present invention.
7 shows an example of a wheel in contact with a rail according to whether the transport vehicle is in a straight line on a transport path according to an embodiment of the present invention.
8 is a straight line diagram illustrating the state of the transport vehicle when the transport vehicle accelerates or decelerates according to the embodiment of the present invention.
9 is a flowchart illustrating an example when both the front wheels and the rear wheels of the transport vehicle are controlled in the speed control mode according to the embodiment of the present invention.
10 is a flowchart showing an example when the rear wheels of the transport vehicle are controlled in the torque control mode according to the embodiment of the present invention.
11 and 12 are flowcharts illustrating an example of a method for controlling driving of a transport vehicle according to an embodiment of the present invention.

Hereinafter, with reference to the accompanying drawings, embodiments of the present invention will be described in detail so that those of ordinary skill in the art to which the present invention pertains can easily implement them. The present invention may be embodied in many different forms and is not limited to the embodiments described herein.

In order to clearly describe the present invention, parts irrelevant to the description are omitted, and the same reference numerals are assigned to the same or similar elements throughout the specification.

In addition, in various embodiments, components having the same configuration will be described using the same reference numerals only in the representative embodiment, and only configurations different from the representative embodiment will be described in other embodiments.

Throughout the specification, when a part is "connected (or coupled)" with another part, it is not only "directly connected (or coupled)" but also "indirectly connected (or connected)" with another member therebetween. combined)" is also included. In addition, when a part "includes" a certain component, this means that other components may be further included, rather than excluding other components, unless otherwise stated.

Unless defined otherwise, all terms used herein, including technical or scientific terms, have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. Terms such as those defined in a commonly used dictionary should be interpreted as having a meaning consistent with the meaning in the context of the related art, and should not be interpreted in an ideal or excessively formal meaning unless explicitly defined in the present application. does not

On the other hand, in the drawings, the size or shape of the component, the thickness of the line, etc. may be expressed somewhat exaggerated for the convenience of understanding.

1 shows an example of an article conveying system in a manufacturing plant. A semiconductor or display manufacturing line consists of one or more clean rooms, and manufacturing facilities 1 for performing a manufacturing process may be installed in each clean room. In general, a finally processed substrate may be completed by repeatedly performing a plurality of manufacturing processes on a substrate (eg, a wafer). When the manufacturing process is completed in a specific semiconductor manufacturing facility 1 , it is transferred to a facility for the next manufacturing process. The substrate is conveyed. Here, the substrate may be transported in a state stored in a container (eg, front opening unified pod, FOUP) capable of accommodating a plurality of substrates. The container accommodating the substrates may be transported by a transport vehicle (eg, overhead hoist transport, OHT) 20 .

The transport vehicle 20 runs on a rail 10 installed on the ceiling and interfaces with a higher-level server (vehicle control device) that instructs a transport operation command in a wireless communication mode. The vehicle control device receives a transfer command according to the work process from the integrated control system, and according to the command of the integrated control system, the vehicle control device 20 provides the shortest route from the origin to the destination in order to complete the transfer operation in the shortest time. It searches and selects a transport vehicle 20 in an optimal position suitable for performing a transport operation and commands a transport command. According to the transfer command of the vehicle control device, the transport vehicle 20 transfers the material from an arbitrary port commanded by the vehicle control device to a destination port.

Referring to FIG. 1 , manufacturing facilities 1 for performing a process are installed in a semiconductor or display manufacturing line, and rails forming a conveyance path (eg, a ceiling rail) for conveying goods between the manufacturing facilities 1 . A plurality of transport vehicles 20 may be provided for transporting articles to the manufacturing facilities 1 while traveling on the rail 10 and the rail 10 . In this case, the article transport vehicle 20 may receive driving power through a power supply unit (eg, a power supply cable) formed along the rail 10 . Meanwhile, the rail 10 may include a traveling rail 110 and an auxiliary rail 111 provided on the traveling rail 110 in a non-linear section.

When the transport vehicle 20 transports goods between the manufacturing facilities 1, the goods may be directly transferred from a specific manufacturing facility to another manufacturing facility, or may be transferred to another manufacturing facility after the goods are stored in a storage device. have. A storage device (eg, the article storage unit 30 ) may be installed on one side of the rail 10 . The storage device is installed adjacent to the side of the rack-type warehouse (stocker) and the rail 10 into which inert gas can be injected to maintain a clean environment in the container, and the rail side buffer or rail 10 for storing goods. It may include a lower rail buffer installed in the lower region to store articles, or a maintenance lifter for maintenance and repair of a transport vehicle.

2 and 3 show a transport vehicle according to an embodiment of the present invention. FIG. 2 shows the transport vehicle 20 as viewed from a diagonal of the travel path, and FIG. 3 shows the transport vehicle 20 as viewed from the side of the travel path.

2 and 3 , the transport vehicle 20 includes an article gripper 210 that receives and grips the article F from the manufacturing facility 1 , and a wheel 220 that runs along the rail 10 . And, the control unit 230 for controlling the article holding unit 210 and the wheel 220, and may include a frame 240 for protecting the article (F).

The article holding part 210 includes a gripper 211 for supporting the article F and a slide driving part 212 for slidingly driving the gripper 211 . The gripper 211 can grip the article F by supporting the flange portion of the article F. The slide driving unit 212 moves the gripper 211 in a horizontal direction, and may control the gripper 211 to grip or release the article F through the slide driving of the gripper 211 .

The wheel 220 includes a wheel body 221 in which devices for driving of the transport vehicle 20 (eg, a wheel shaft, a motor rotating the wheel shaft, a steering wheel controlling a direction, etc.) are installed, a traveling rail 110 and A driving wheel 222 that rotates in contact with the driving wheel 222 is provided on the outside of the driving wheel 222 to have a smaller radius than the driving wheel 222 and includes a driving auxiliary wheel 223 that can rotate in contact with the auxiliary rail 111 do. Here, the wheel 220 includes a front wheel 220A mounted on the front of the transport vehicle 20 and a rear wheel 220B mounted on the rear of the transport vehicle 20 . In general, the transport vehicle 20 travels along the traveling rail 110 by the rotation of the traveling wheel 222, and enters the non-linear traveling rail 110 such as a curve, branch, or merging, or enters the non-linear traveling rail ( When departing from 110 , at least one of the front wheels 220A and the rear wheels 220B of the transport vehicle travels along the auxiliary rail 111 by the rotation of the driving auxiliary wheel 223 .

The controller 230 may control overall operations for driving of the transport vehicle 20 and loading and unloading goods.

4 is a schematic block diagram of an apparatus for driving a transport vehicle according to an embodiment of the present invention; Referring to FIG. 4 , the control unit 230 for controlling the driving of the transport vehicle 20 is connected to the front wheels 220A and the rear wheels 220B, and the front wheels 220A are rotated by the driving of the front wheel drive unit 236A. and the rear wheel 220B is rotated by the driving of the rear wheel drive unit 236B.

According to an embodiment of the present invention, the controller 230 includes a processing unit 232 that receives a command for the transport vehicle 20 and provides information on a movement path of the transport vehicle 20, and performs driving according to the movement path. For this purpose, the motion control unit 234 for generating a drive signal including a speed signal and a torque signal for driving the front wheels 220A and the rear wheels 220B of the transport vehicle 20, and the front wheels 220A based on the speed signal It includes a front wheel drive unit 236A for controlling driving, and a rear wheel driving unit 236B for controlling driving of the rear wheel 220B based on one of a speed signal or a torque signal according to an operation mode. At this time, although not shown in detail, an encoder for measuring the moving distance of the transport vehicle 20 by measuring the rotation amount of the front wheel 220A or the rear wheel 220B may be provided.

The processing unit 232 processes data for control of the transport vehicle 20 and provides it to the motion control unit 234 . The processing unit 232 includes a communication module that transmits or receives signals with an upper control device (a manufacturing control system or a vehicle control system), a program (eg, an operating system) and data (eg, map data) for controlling the transport vehicle 20 . ) may include a memory for storing, and a processor for processing data received through the communication module and data stored in the memory.

5 shows a schematic configuration for explaining the drive control of the transport vehicle 20 according to the embodiment of the present invention.

Referring to FIG. 5 , the motion controller 234 includes a position controller 2342 that generates a position signal for determining a position of the transport vehicle 20 along a movement path, and a speed of the transport vehicle 20 based on the position signal. A speed controller 2344 that generates a speed signal for determining and a torque controller 2346 for providing a rear wheel torque signal to the rear wheel drive unit 236B.

As shown in FIG. 5 , a position signal indicating the position by time by the target moving position of the transport vehicle 20 is generated by the position controller 2342, and the speed of the transport vehicle 20 according to the position signal by time A speed signal representing and is provided to the front wheel drive unit 236A and the rear wheel drive unit 236B. Position controller 2342 , speed controller 2344 , and torque controller 2346 may each be implemented by separate hardware processors or software.

On the other hand, the amount of rotation of the front wheel 220A or the rear wheel 220B may be measured by an encoder (not shown), and the encoder (not shown) receives the rotation amount of the front wheel 220A or the rear wheel 220B from the amount of rotation of the transport vehicle 20 It is possible to determine the amount of movement of , and feed it back to the position controller 2342 . The position controller 2342 calculates a difference value between the target movement distance according to the target movement position and the actual movement distance of the transport vehicle 20, and the speed controller 2344 calculates a difference value between the target movement distance and the actual movement distance according to the difference value. You can adjust the speed.

However, when the transport vehicle 20 enters a non-linear path, such as a curve, branch, or merging, or departs from a non-linear path, at least one of the front wheels 220A and the rear wheels 220B is the driving wheel 222 . It is driven by the driving auxiliary wheel 223 instead of the driving wheel 223, and since there is a difference in the radius size of the driving wheel 222 and the driving auxiliary wheel 223, in this case, a difference may also occur in the amount of rotation measured by the encoder (not shown). can Due to this difference, a rotational speed difference occurs between the front wheels 220A and the rear wheels 220B of the transport vehicle 20, and mutual interference such as load and vibration occurs due to this speed difference, and It can also affect the quality of the product. Thus, the embodiment of the present invention eliminates the speed difference between the front wheels 220A and the rear wheels 220B by constantly switching the operation mode of the rear wheels 220B according to the movement path or speed signal of the transport vehicle 20 and removes the speed difference between the transport vehicles ( 20) and the load or vibration applied to the article F loaded on the transport vehicle 20 (that is, mutual interference generated between the front wheels 220A and the rear wheels 220B) can be prevented.

6 shows an example of a method for setting an operation mode of a wheel of a transport vehicle according to an embodiment of the present invention, and FIGS. 7 and 8 show an example of a situation in which operation mode switching is required.

According to an embodiment of the present invention, the motion controller 234 may set the operation mode of the rear wheel drive unit 236B based on whether the movement path is a straight line. At this time, the operation mode of the front wheel drive unit 236A is continuously maintained as the speed control mode for controlling the driving of the front wheel 220A based on the speed signal. For example, when the movement path is a straight line, the motion control unit 234 may set the operation mode of the rear wheel drive unit 236B to the speed control mode. As shown in Fig. 7(a), when the movement path of the transport vehicle 20 is a straight line, since both the front wheels 220A and the rear wheels 220B travel by the traveling wheels 222, the front wheels 220A and the rear wheels ( 220B) can prevent a speed difference between the front wheels 220A and the rear wheels 220B from occurring even when they are driven at the same speed using the speed control mode.

On the other hand, when the movement path is not a straight line, the motion control unit 234 may set the operation mode of the rear wheel drive unit 236B to the torque control mode. At this time, the operation mode of the front wheel drive unit 236A is continuously maintained in the speed control mode for controlling the driving of the front wheel 220A based on the speed signal. At this time, the operation mode of the rear wheel driving unit 236B, which was controlling the rear wheels 220B in the speed control mode in the straight section, is changed to the torque control mode when the moving path of the transport vehicle 20 is changed from a straight path to a non-linear path. is converted Specifically, at a point in time when the inner wheel of the front wheel 220A of the transport vehicle 20 starts to travel along the auxiliary rail 111 by the traveling auxiliary wheel 223A (refer to FIG. 7(b) ), the rear wheel drive unit 236B ) can be switched to torque control mode. Accordingly, in a section in which the movement path is not a straight line, the front wheel drive unit 236A of the transport vehicle 20 controls the front wheel 220A in the speed control mode, and the rear wheel drive unit 236B controls the rear wheel 220B in the torque control mode. will be in control

Meanwhile, although not shown in detail, when the inner wheel of the front wheel 220A travels along the auxiliary rail 111 by the driving auxiliary wheel 223A, the outer wheel of the front wheel 220A is in a non-contact state with the rail 10 . can Similarly, when the inner wheel of the rear wheel 220B travels along the auxiliary rail 111 by the driving auxiliary wheel 223A, the outer wheel of the rear wheel 220B may be in a non-contact state with the rail 10 .

Contrary to the above-described case, when the movement path of the transport vehicle 20 is changed from a non-linear path to a linear path, the operation of the rear wheel drive unit 236B that controls the rear wheel 220B in the torque control mode in the non-linear section The mode is switched back to the speed control mode when the moving path of the transport vehicle 20 is changed from a non-linear path to a straight path. Specifically, when the rear wheel 220B of the transport vehicle 20 enters the straight section and starts to travel along the traveling rail 110 by the traveling wheel 222B again (refer to FIG. 7(c) ), the rear wheel drive unit The operating mode of 236B may be switched back to the speed control mode.

As such, when the moving path of the transport vehicle 20 is not a straight line, at least one of the front wheels 220A and the rear wheels 220B of the transport vehicle 20 as shown in FIGS. 7B and 7C . Because the wheel of the driving wheel 222 drives the rail 10 by the driving auxiliary wheel 223, not the driving wheel 222, the speed difference between the front wheel 220A and the rear wheel 220B does not occur by torque controlling the rear wheel 220B. can prevent it

At this time, the torque of the torque-controlled rear wheel 220B may be controlled by a torque signal generated by the motion controller 234 .

The torque signal may be a preset value and commanded by the motion controller 234 .

Alternatively, the torque signal may be a value fed back by the torque generated by the driving of the front wheel 220A. That is, as shown in FIG. 10 , the torque generated from the front wheel 220A traveling at the speed value commanded by the motion control unit 234 is transmitted back to the motion control unit 234 and then commanded to the rear wheel drive unit 236B. it could be

For example, the operation mode of the front wheel 220A or the rear wheel 220B may be commanded from the motion controller 234 to the front wheel drive unit 236A or the rear wheel drive unit 246B using an input/output method.

Meanwhile, according to another embodiment of the present invention, the front wheel drive unit 236A controls the driving of the front wheel 220A based on one of a speed signal or a torque signal according to an operation mode, and the operation mode of the rear wheel drive unit 236B is It is continuously maintained in the speed control mode and the motion control unit 234 determines the operation mode of the front-wheel drive unit 236A based on the movement path of the transport vehicle 20 to determine the operation mode of the front-wheel drive unit 236A based on whether the movement path is a straight line. You can also switch accordingly.

According to another embodiment of the present invention, the motion controller 234 may determine the operation modes of the front wheel drive unit 236A and the rear wheel drive unit 236B based on the slope of the speed signal. For example, the motion control unit 234 sets the operation mode of the front wheel drive unit 236A to the speed control mode when the transport vehicle 20 accelerates (when the slope of the speed signal is positive), and sets the operation mode of the rear wheel drive unit ( 236B) may be set to the torque control mode. As shown in Fig. 8(b), when the transport vehicle 20 accelerates, the transport vehicle 20 has a property of rotating clockwise due to inertia and the weight is shifted forward, so the speed signal is transmitted to the front wheel drive unit ( 236A), the operation mode of the front wheel drive unit 236A is set to the speed control mode, and the operation mode of the rear wheel drive unit 236B is set to the torque control mode, so that the transport vehicle 20 can stably accelerate.

On the other hand, when the conveying vehicle 20 decelerates or stops (when the slope of the speed signal is negative), the driving unit controller 2346 determines that as shown in FIG. The control ability of the front wheel drive unit 236A may be lost because it has a property of rotating in a counterclockwise direction and the weight is shifted to the rear. Therefore, by transmitting the speed signal to the rear wheel drive unit 236B to set the operation mode of the rear wheel drive unit 236B to the speed control mode and the operation mode of the front wheel drive unit 236A to the torque control mode, the transport vehicle 20 is stable. can be slowed down to

Similarly, the torque of the front wheel drive unit 236A or the rear wheel drive unit 236B may be commanded as a preset value by the motion control unit 234 .

Alternatively, the torque of the wheel traveling in the torque control mode may be a value fed back by the torque generated by the speed control of the wheel traveling in the speed control mode. That is, the speed signal may be received by the motion controller 234 and fed back by the torque generated by the wheel operating in the speed control mode, and may be commanded to the wheel in the torque control mode.

For example, the operation modes of the front wheels 220A and the rear wheels 220B may be commanded from the sean control unit 234 to the front wheel drive unit 236A and the rear wheel drive unit 246B using an input/output method.

On the other hand, the encoder (not shown) calculates the moving distance of the transport vehicle 20 by measuring the rotation amount of the front wheels 220A or the rear wheels 220B, and the speed controller 2344 calculates the distance calculated by the encoder (not shown). The speed signal can be corrected according to the distance traveled.

9 is a flowchart illustrating an example when both the front and rear wheels of the transport vehicle are controlled in the speed control mode according to the embodiment of the present invention, and FIG. 10 is the speed control of the front wheels of the transport vehicle according to the embodiment of the present invention. It is a block diagram showing an example when the mode is maintained and the rear wheels are controlled in the torque control mode.

11 and 12 are flowcharts of a method for controlling driving of a transport vehicle according to an embodiment of the present invention. 11 and 12 may be performed by the controller 230 or the motion controller 234 .

Referring to FIG. 11 , in the method for controlling the driving of the transport vehicle 20 according to an embodiment of the present invention, the step of obtaining information on the movement path of the transport vehicle 20 ( S1005 ), the movement path generating a position signal for determining the position of the transport vehicle 20 according to (S1010) and generating a speed signal for determining the velocity of the transport vehicle 20 based on the position signal (S1015); Determining the operation mode of the wheel drive unit (front wheel drive unit, rear wheel drive unit) based on the path (S1020) and switching the operation mode of the rear wheels of the conveyance vehicle 20 according to the determined operation mode and driving the conveyance vehicle 20 (S1025) is included.

In one embodiment of the present invention, the step of determining the operation mode ( S1020 ) may include setting the operation mode of the rear wheel drive unit based on whether the movement path of the transport vehicle 20 is a straight line. For example, the method may include setting the operation mode of the rear wheel drive unit to the speed control mode when the movement path is a straight line, and setting the operation mode of the rear wheel drive unit to the torque control mode when the movement path is not a straight line. At this time, the operation mode of the front wheel drive unit is maintained in the speed control mode.

In addition, the step of setting the operation mode of the rear wheel drive unit to the torque control mode is to switch the operation method of the rear wheels from the speed control mode to the torque control mode at the time when the front wheels of the transport vehicle 20 start to travel by the driving auxiliary wheel. may include steps.

Meanwhile, according to another embodiment of the present invention, contrary to the above, the operation mode of the rear wheel drive unit 236B is continuously maintained as the speed control mode, and the operation mode of the front wheel drive unit 236A can be switched depending on whether the movement path is a straight line. have.

Referring to FIG. 12 , a method for controlling the driving of a transport vehicle 20 according to another embodiment of the present invention includes: acquiring information on a movement path of the transport vehicle 20 ( S2005 ); Generating a position signal for determining the position of the transport vehicle 20 along the path (S2010), and generating a speed signal for determining the velocity of the transport vehicle 20 based on the position signal (S2015); Determining the operation mode of the wheel drive unit (front wheel drive unit, rear wheel drive unit) based on the speed signal (S2020) and switching the operation mode of the front wheel drive unit and the rear wheel drive unit of the conveyance vehicle 20 based on the operation mode signal and a step (S2025) of driving (20).

In another embodiment of the present invention, the step of determining the operation mode ( S2020 ) may include setting the operation modes of the front wheel drive unit and the rear wheel drive unit based on the slope of the speed signal of the transport vehicle 20 . For example, when the transport vehicle 20 accelerates, the method may include setting the operation mode of the front wheel drive unit to the speed control mode and setting the operation mode of the rear wheel drive unit to the torque control mode. Conversely, when the transport vehicle 20 decelerates, the method may include setting the operation mode of the front wheel drive unit to the torque control mode and the operation mode of the rear wheel drive unit to the speed control mode.

Hereinafter, the torque of the front wheel or the rear wheel may be controlled by a torque signal generated based on the speed signal, and the torque signal may be a commanded value or a value fed back from the wheel operated in the speed control mode.

This embodiment and the drawings attached to this specification merely clearly show some of the technical ideas included in the present invention, and those skilled in the art can easily infer within the scope of the technical ideas included in the specification and drawings of the present invention. It will be apparent that all possible modifications and specific embodiments are included in the scope of the present invention.

Therefore, the spirit of the present invention should not be limited to the described embodiments, and not only the claims to be described later, but also all those with equivalent or equivalent modifications to the claims will be said to belong to the scope of the spirit of the present invention. .

10: rail
20: transport vehicle
110: running rail
111: auxiliary rail
210: article holding unit
220: wheel
220A: front wheel
220B: rear wheel
222 (222A, 222B): travel wheel
223 (223A, 223B): Driving aid wheel
230: control unit
232: processing unit
234: motion control
236A: front wheel drive
236B: rear wheel drive

Claims (16)

An apparatus for controlling driving of a conveying vehicle in an article conveying system, the apparatus comprising:
a processing unit configured to receive information on a movement path of the transport vehicle;
a motion control unit generating a driving signal including a speed signal and a torque signal for driving the front and rear wheels of the transport vehicle for driving along the moving path;
a front wheel drive unit controlling driving of the front wheel based on the speed signal; and
a rear wheel drive unit for controlling the driving of the rear wheel based on one of the speed signal or the torque signal according to an operation mode;
The motion control unit determines the operation mode of the rear wheel drive unit based on a movement path of the transport vehicle.
According to claim 1,
The motion control unit sets the operation mode of the rear wheel drive unit based on whether the moving path of the transport vehicle is straight.
3. The method of claim 2,
The motion control unit sets the operation mode of the rear wheel drive unit to a speed control mode when the movement path is a straight line, and sets the operation mode of the rear wheel drive unit to a torque control mode when the movement path is not a straight line .
4. The method of claim 3,
The operation mode of the rear wheel drive unit is switched when the movement path is changed from a straight path to a non-linear path or when the moving path is changed from a non-linear path to a straight path.
4. The method of claim 3,
The torque of the rear wheel is applied to the torque signal generated by the motion control unit.
Device characterized in that controlled by.
6. The method of claim 5,
The torque signal is a preset value or a value fed back by driving the front wheel.
According to claim 1,
The front wheel drive unit controls the driving of the front wheel based on one of the speed signal or the torque signal according to an operation mode,
The rear wheel drive unit controls the driving of the rear wheel based on the speed signal,
The motion control unit determines the operation mode of the front wheel drive unit based on a movement path of the transport vehicle.
An apparatus for controlling driving of a conveying vehicle in an article conveying system, the apparatus comprising:
a processing unit configured to receive information on a movement path of the transport vehicle;
a motion control unit generating a driving signal including a speed signal and a torque signal for driving the front and rear wheels of the transport vehicle for driving along the moving path;
a front wheel drive unit for controlling driving of the front wheel based on one of the speed signal and the torque signal according to an operation mode; and
a rear wheel drive unit for controlling the driving of the rear wheel based on one of the speed signal or the torque signal according to an operation mode;
The motion control unit determines the operation modes of the front wheel drive unit and the rear wheel drive unit based on a slope of the speed signal.
9. The method of claim 8,
When the motion control unit accelerates the transport vehicle,
An operation mode of the front wheel drive unit is set to a speed control mode, and an operation mode of the rear wheel drive unit is set to a torque control mode.
9. The method of claim 8,
When the motion control unit decelerates or stops the transport vehicle,
An operation mode of the front wheel drive unit is set to a torque control mode and an operation mode of the rear wheel drive unit is set to a speed control mode.
A method for controlling driving of a transport vehicle in an article transport system, the method comprising:
obtaining information on a movement path of the transport vehicle;
generating a position signal for determining a position of the transport vehicle along the movement path;
generating a speed signal for determining a speed of the transport vehicle based on the position signal;
determining an operation mode of the wheel driving unit based on the information on the movement path; and
and a driving step of switching the operation mode of the rear wheel drive unit according to the operation mode and driving the transport vehicle.
12. The method of claim 11,
Determining the operation mode comprises:
and setting an operation mode of the rear wheel drive unit based on whether the movement path is straight.
13. The method of claim 12,
The step of setting the operation mode of the rear wheel drive unit comprises:
When the movement path is a straight line, the operation mode of the rear wheel drive unit is set to a speed control mode,
and setting an operation mode of the rear wheel drive unit to a torque control mode when the movement path is not a straight line.
A method for controlling driving of a transport vehicle in an article transport system, the method comprising:
obtaining information on a movement path of the transport vehicle;
generating a position signal for determining a position of the transport vehicle along the movement path;
generating a speed signal for determining a speed of the transport vehicle based on the position signal;
determining an operation mode of the wheel driving unit based on the slope of the speed signal; and
and a driving step of switching the operation modes of the front wheel drive unit and the rear wheel drive unit based on the determined operation mode and driving the transport vehicle.
15. The method of claim 14,
Determining the operation mode comprises:
When the transport vehicle accelerates, an operation mode of the front-wheel drive unit is set to a speed control mode and an operation mode of the rear-wheel drive unit is set to a torque control mode;
and setting an operation mode of the front-wheel drive unit to a torque control mode and setting an operation mode of the rear-wheel drive unit to a speed control mode when the transport vehicle decelerates.
running rails installed on the ceiling;
a transport vehicle running along the running rail;
and a higher-order control device that commands a command to the transport vehicle;
The transport vehicle is
an article holding unit for receiving and holding the article from the manufacturing facility;
a driving unit that travels along the traveling rail;
A control unit for controlling the article holding unit and the driving unit,
The control unit is
a processing unit configured to receive a command for the transported vehicle and information on a movement path of the transported vehicle;
a motion control unit generating a driving signal including a speed signal and a torque signal for driving the front and rear wheels of the transport vehicle for driving along the moving path;
a front wheel drive unit controlling driving of the front wheel based on the speed signal; and
a rear wheel drive unit for controlling the driving of the rear wheel based on one of the speed signal or the torque signal according to an operation mode;
The motion control unit is an overhead hoist transport (OHT), characterized in that for determining the operation mode of the rear wheel drive unit based on the moving path or the speed signal of the transport vehicle.

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