KR102259508B1 - Wheel sorter having a plurality of variable wheel modules that can be driven independently - Google Patents

Abstract

The present invention relates to a wheel sorter for sorting goods such as parcels and parcel delivery services, and more particularly, to a wheel sorter capable of increasing the object sorting accuracy by individually controlling the rotation angle of each wheel according to the position and weight information of the object. it's about

Description

Wheel sorter having a plurality of variable wheel modules that can be driven independently

The present invention relates to a wheel sorter for sorting goods, such as parcels and parcels, and more particularly, to a wheel sorter capable of increasing the accuracy of sorting goods by individually controlling the rotation angles of each wheel according to the weight of the goods. .

In general, a wheel sorter system is used to sort items such as parcels or parcels. The wheel sorter is configured to automatically classify goods by delivery region as the small wheels installed in various parts of the conveyor rotate left and right after recognizing the barcode of the invoice attached to the goods and the angle is changed. Korean Patent Registration No. 10-1725337 discloses a wheel sorter system for automatic sorting of such objects. Since the conventional wheel sorter drives a plurality of wheels simultaneously by a link with a single motor, the left and right rotation angles of a plurality of wheels positioned in the same row are all equally controlled. According to this method, there is an advantage in that the control is very simple in classifying objects. However, even though the weights of the classified objects are very diverse, since the angles of the wheels are all controlled the same, the movement direction of the objects cannot be accurately controlled due to the difference in the inertial force according to the weight of the object and the friction force acting on the wheel. Errors occur frequently.

Republic of Korea Patent No. 10-1725337

The present invention was devised to solve the problems of the conventional wheel sorter as described above, and it is an object of the present invention to provide a wheel sorter capable of increasing the object sorting accuracy by controlling individual wheels to an optimal rotation angle according to the weight of the object. do.

A wheel sorter having a plurality of independently drivable variable wheel modules according to the present invention for achieving the above object is a wheel sorter that automatically sorts goods such as parcels or parcels, and a plurality of openings are formed on the surface. a classification table; It includes a plurality of variable wheel modules mounted in each opening of the sorting table, each of which is configured such that the angle of rotation in the left and right directions is independently adjustable so as to transport the goods transferred to the sorting table in any one of the left, right and straight directions. .

Here, the variable wheel module includes: a rotating plate rotatably disposed in the opening of the sorting table and having a wheel mounting hole in the center thereof; a transfer wheel disposed in the wheel mounting hole of the rotating plate and moving forward the object introduced into the sorting table as it rotates; a driving wheel connected to the conveying wheel by a belt; a wheel driving motor for rotating the driving wheel; a wheel bracket for supporting the rotating plate and the driving wheel; and a servomotor for rotating the wheel bracket left and right to rotate the rotating plate and the transfer wheel.

And, the wheel bracket includes a vertical extension formed vertically extending on both sides of the left and right, and a horizontal extension portion interconnecting the vertical extension on the left and right sides from the lower side, the upper end of the vertical extension is fixedly coupled to the rotating plate Both ends of the rotating shaft of the driving wheel are rotatably supported on the extension.

In addition, the control unit for generating a reference signal for adjusting the left and right rotation angle of each variable wheel module based on the position information and weight information of the object; a first wireless communication module for wirelessly transmitting the reference signal generated by the control unit; It further includes a second wireless communication module for receiving the reference signal transmitted from the first wireless communication module and transmitting to each variable wheel module.

In addition, a motor controller that receives the reference signal received from the second wireless communication module and outputs a control signal corresponding to the reference signal, and a driving power corresponding to the control signal output from the motor controller is input to the servo motor It further includes a motor drive that does.

Here, the control unit has a database of reference signals corresponding to the optimal rotation angles of individual servo motors according to the weight of the object set in advance for each transport direction of the object, and the reference signal generating module actually recognizes the reference signal database with reference to the reference signal database. The reference signals of individual servo motors are generated and output according to the weight of the object.

According to the present invention as described above, by configuring a plurality of wheels to be driven independently, the individual wheels can be adjusted to an optimal rotation angle according to the weight of the object to be classified, thereby remarkably increasing the accuracy of object classification.

1 is an overall configuration diagram of a wheel sorter according to the present invention;
2 is a side view of the variable wheel module of the wheel sorter according to the present invention;
3 is a plan view of a variable wheel module of the wheel sorter according to the present invention;
4 is a control system diagram of a wheel sorter according to the present invention;
5 is a view for explaining a method of generating a reference signal for adjusting the rotation angle of the servo motor in the control unit of the wheel sorter system according to the present invention;
6 is a diagram illustrating a state in which objects are transported and sorted in various directions by the wheel sorter according to the present invention.

Hereinafter, the configuration and operation of a wheel sorter having a plurality of independently possible wheels according to the present invention will be described in detail with reference to the accompanying drawings and preferred embodiments.

1, in the wheel sorter according to the present invention, a classification table 100 is disposed between a first conveyor 10 and a second conveyor 20 spaced apart from each other by a predetermined interval, and the classification table 100 A plurality of variable wheel modules 200 are disposed on the surface.

The sorting table 100 is composed of a substantially flat plate-shaped member so that the object 1 transported through the first conveyor 10 can be transported while being supported from below, and the plurality of variable wheel modules 200 are mounted on the surface. A plurality of openings 110 are formed so that the The opening 110 is preferably formed in a circular shape so that the rotating plate 210 of the variable wheel module 200 to be described later can rotate smoothly.

The variable wheel module 200 is mounted in the opening 110 of the sorting table 100 and transports the object 1 transported to the sorting table 100 through the first conveyor 10 in the left, right and straight directions. The left and right rotation angles are configured to be independently adjustable so as to be transported in either direction, so as to automatically classify the goods (1) such as parcels or couriers. As shown in FIG. 1 , the variable wheel modules 200 are arranged and mounted while forming a plurality of rows on the sorting table 100, and as will be described later, individual variable wheel modules 200 are independently rotationally driven. The object (1) is transported in a predetermined direction.

2 shows the configuration of the variable wheel module 200 in more detail. 2A is a side view of the variable wheel module 200 viewed from the axial direction, and FIG. 2B is a side view of the variable wheel module 200 viewed from a direction perpendicular to the axial direction. do. As shown, the variable wheel module 200 includes a rotating plate 210 , a transfer wheel 220 , a driving wheel 230 , a wheel driving motor 240 , and a servo motor 270 .

The rotating plate 210 is a plate member rotatably disposed in the opening 110 of the sorting table 100 and is disposed to form a plane having the same height as the surface of the sorting table 100 . In addition, as shown in FIG. 3 , a wheel mounting hole 210a is formed through the rotating plate 210 so that the transfer wheel 220 can be inserted and mounted.

The transfer wheel 220 is a roller-shaped member that forwardly transfers the object 1 introduced into the upper part of the sorting table 100 as it rotates around the rotation axis, and is disposed in the wheel mounting hole 210a of the rotating plate 210 . In this state, the left and right ends of the rotating shaft are fixedly installed on the inner wall of the wheel mounting hole 210a or a wheel bracket 260 to be described later. And, the surface of the transfer wheel 220 is configured to protrude higher than the height of the surface of the rotating plate 210 to be in contact with the object (1). Accordingly, the transfer wheel 220 can be rotated on its own about the rotation axis, and at the same time, can be rotated in both left and right sides by the rotation of the rotating plate 210 as will be described later.

A driving wheel 230 is provided below the transfer wheel 220 . The driving wheel 230 is rotated by a wheel driving motor 240 to rotationally drive the transport wheel 220 , and as shown in FIG. 2 ( b ), one end of the rotation shaft of the driving wheel 230 . A wheel driving motor 240 is connected to the rim, and the driving wheel 230 and the transfer wheel 220 are interconnected by a belt 250 . Accordingly, when the wheel driving motor 240 is operated, the driving wheel 230 is rotated, and the rotational force of the driving wheel 230 is transmitted to the transport wheel 220 by the belt 250 to the transport wheel 220 . This rotation is driven.

The driving wheel 230 and the rotating plate 210 are supported by a wheel bracket 260 . As shown in (b) of FIG. 2, the wheel bracket 260 connects the vertical extension parts 262 vertically extending on both left and right sides and the vertical extension parts 262 on the left and right sides from the lower side. It includes a horizontal extension 264 . An upper end of the vertical extension portion 262 is fixedly coupled to the rotating plate 210 . In addition, the left and right ends of the rotary shaft of the driving wheel 230 are rotatably supported by the bearings on the horizontal extension part 264 . In addition, the wheel driving motor 240 is mounted on the outside of the one side vertical extension part 262 and is connected to the rotation shaft of the driving wheel 230 .

On the other hand, the lower portion of the wheel bracket 260, more specifically, the horizontal extension portion 264 of the wheel bracket 260 is connected to the servomotor 270 from the lower side. As shown in (b) of FIG. 2 , the servomotor 270 is fixedly installed on a fixing plate 280 , and the motor shaft of the servomotor 270 passes through the fixing plate 280 to the wheel bracket 260 . ) is combined with the horizontal extension 264 of the. Here, the fixed plate 280 is fixedly coupled to the sorting table 100 by a separate fastener, and the fixed plate 280 itself may be integrally configured with the sorting table 100 . Through this configuration, when the servomotor 270 is operated, the wheel bracket 260 is rotated, and the rotating plate 210 coupled to the wheel bracket 260 is rotated. Accordingly, the transfer wheel 220 mounted on the rotating plate 210 is also rotated.

3 exemplarily shows that the rotating plate 210 and the transfer wheel 220 are rotated by a predetermined angle in this way. As shown in (a) of FIG. 3 , the transfer wheel 220 arranged in the 12 o'clock direction moves in the 3 o'clock direction as shown in FIG. 3 (b) according to the operation of the servo motor 270 . It can be seen that it is rotated by 90°. Here, it is shown that the rotating plate 210 and the transfer wheel 220 are rotated by 90°, but when the actual object 1 is classified, the individual rotating plate 210 and the transfer wheel 220 according to the weight of the object 1 . It is controlled to rotate at various angles. Such a rotation control method will be described later.

Meanwhile, as shown in FIG. 1 , the wheel sorter according to the present invention further includes a scanner 10 . The scanner 10 is for acquiring information by recognizing the barcode 1a attached to the object 1, such as a parcel or courier. As shown in FIG. 1, the entry side of the classification table 100, more specifically to recognize the barcode 1a attached to the object 1 provided on the upper side of the first conveyor 10 to be transported along the first conveyor 10 in real time.

4 is a block diagram showing a control system for adjusting the rotation angle of the transfer wheel 220 based on the information recognized by the scanner 10 . As shown, the wheel sorter according to the present invention further includes a control unit 40 , a first wireless communication module 50 , and a second wireless communication module 272 .

The control unit 40 is a kind of computer system that processes the barcode 1a information recognized by the scanner 10, and is installed inside or outside the scanner 10 and can be connected to the scanner 10 by wire or wirelessly. have. In the present invention, the barcode 1a attached to the object 1 includes weight information and location information (delivery address information) of the object 1 , and the control unit 40 is recognized by the scanner 10 . The movement direction of the object 1 is determined based on the position information and weight information of the object 1, and a reference signal for adjusting the rotation angle of each variable wheel module is generated.

5 is a diagram for explaining a method of generating a reference signal in the control unit 40 . As shown, location information and weight information of the object 1 recognized by the scanner 10 are transmitted to the controller 40 . The control unit 40 includes a transfer direction determining module 42 and a reference signal generating module 44 .

The transfer direction determining module 42 of the control unit 40 determines the transfer direction of the object 1 based on the received position information of the object 1 . In the control unit 40, the transfer direction (left, right, straight) according to the location information (delivery destination) of the article 1 is matched in advance. For example, if the delivery destination is Seoul, it is preset to the left, if it is Chungcheong, to the right, and if it is Gangwon, it is preset. Accordingly, for example, when the location information of the object 1 recognized and delivered by the scanner 10 is recognized as being in the Seoul area, the transfer direction determining module 42 determines the transfer direction of the object 1 to the left. And, when the location information of the object 1 is recognized as being in the Chungcheong and Gangwon regions, the transport direction is determined to the right and straight, respectively.

When the transport direction of the object 1 is determined, the reference signal generating module 44 of the control unit 40 provides a reference signal for adjusting the rotation angle of the individual servo motors 270 based on the transport direction and weight information of the object 1 . create As shown in FIG. 5 , in the control unit 40 , reference signals of individual servo motors 270 according to the weight of the object 1 in each transport direction of the object 1 are stored in a database. These reference signals perform a trial run while repeatedly changing the weight of the object 1 and the rotation angle of the servo motor 270 in advance, so that the object 1 is accurately transported and classified without errors. Optimal rotation of the servo motor 270 An angle value is found, and a reference signal for controlling the rotation of the thermomotor with this optimal rotational angle value is allocated to each server motor and stored in advance. The reference signal generating module 44 refers to the reference signal database of the servo motors 270 according to the weight of the object 1 set in advance for each transport direction of the object 1 in this way and according to the actual recognized weight of the object 1 A reference signal of individual servomotors 270 is generated. For example, as shown in FIG. 5 , when the transport direction of the object 1 is determined in a straight direction, all servo motors 270 should not rotate regardless of the weight of the object 1 , so all servo motors 270 . The reference signal of '0 (zero)' is preset. And, when the transport direction of the object 1 is determined to the left, when the weight of the object ₁ is recognized as M 1 , the reference signals of the servo motors 270 become α ₁₁ , α ₁₂ , and α _1n . Similarly, when the transport direction of the object 1 is determined to the right, when the weight of the object ₁ is recognized as M 1 , the reference signals of the servo motors 270 become β ₁₁ , β ₁₂ , and β _1n .

The reference signal generated in this way is, as shown in FIG. 4, each remote variable wheel module 200 through the first wireless communication module 50 built into the scanner 10 (or separately installed outside). ) is transmitted to the second wireless communication module 272 built in (or separately installed outside). The second wireless communication module 272 inputs the reference signal received from the first wireless communication module 50 to the motor controller 274, and the motor controller 274 generates a control signal corresponding to the reference signal to generate a motor to drive 276 . The motor drive 276 converts externally applied power to correspond to the control signal and inputs driving power to the servo motor 270 , and accordingly, the servo motor 270 is rotated by a specific rotation angle. On the other hand, it is preferable that the servomotor 270 is further provided with a sensor (not shown) for detecting a rotation angle, so that a signal sensed by the sensor is transmitted to the motor controller 274 to enable feedback control.

In this way, as shown in FIG. 6 , the angles of the individual servo motors 270 are adjusted according to the position information and weight information of the object 1 , so that the transfer wheels 220 of each variable wheel module 200 are As it is rotated at an optimal angle, the object 1 is automatically sorted by moving in the left and right or straight directions. In particular, in the conventional wheel sorter system, all the wheels arranged in the same row are configured to rotate at the same angle, whereas in the wheel sorter according to the present invention, the transfer wheels 220 of each variable wheel module 200 are all independently driven and objects According to the weight of (1), since the angle of each transfer wheel 220 is individually controlled to an angle optimized for object transfer, the accuracy of object classification is further improved.

In the above, specific embodiments of the present invention have been described. However, the spirit and scope of the present invention is not limited to these specific embodiments, and various modifications and variations are possible within the scope of not changing the subject matter of the present invention. Anyone who has it will understand. Therefore, the embodiments described above are provided to completely inform the scope of the invention to those of ordinary skill in the technical field to which the present invention belongs, and should be understood as illustrative and non-limiting in all respects, The invention is only defined by the scope of the claims.

1: object 1a: barcode
10: first conveyor 20: second conveyor
30: scanner 40: control unit
42: transfer direction determination module 44: reference signal generation module
50: first wireless communication module 100: classification table
110: opening 200: variable wheel module
210: rotating plate 210a: wheel mounting hole
220: feed wheel 230: driven wheel
240: wheel drive motor 250: belt
260: wheel bracket 262: vertical extension
264: horizontal extension 270: servo motor
272: second wireless communication module 274: motor controller
276: motor drive 280: fixed plate

Claims (6)

A wheel sorter for automatically sorting items (1) such as parcels or couriers,
a classification table 100 having a plurality of openings 110 formed on its surface;
The angle of rotation in the left and right directions is independently adjusted to transport the object 1 mounted in each opening 110 of the sorting table 100 and transferred to the sorting table 100 in any one of the left, right, and straight directions. including a plurality of variable wheel modules 200 configured to be possible;
The variable wheel module 200 is rotatably disposed in the opening 110 of the sorting table 100 and includes a rotating plate 210 having a wheel mounting hole 210a in the center thereof, and a wheel of the rotating plate 210 . A transfer wheel 220 that is disposed in the mounting hole 210a and rotates to move the object 1 introduced into the sorting table 100 forward, and is connected by the transfer wheel 220 and the belt 250 A driving wheel 230, a wheel driving motor 240 for rotating the driving wheel 230, a wheel bracket 260 supporting the rotating plate 210 and the driving wheel 230, and the wheel bracket ( and a servomotor 270 for rotating the rotary plate 210 and the transfer wheel 220 by rotating the 260 left and right;
The wheel bracket 260 includes a vertical extension portion 262 formed to extend vertically on both left and right sides, and a horizontal extension portion 264 for interconnecting the vertical extension portions 262 on the left and right sides from a lower side. The upper end of the extension part 262 is fixedly coupled to the rotating plate 210, and the left and right ends of the rotation shaft of the driving wheel 230 are rotatably supported on the horizontal extension part 264;
a control unit 40 for generating a reference signal for adjusting the left and right rotation angles of each of the variable wheel modules 200 based on the position information and weight information of the object (1);
a first wireless communication module 50 for wirelessly transmitting the reference signal generated by the control unit 40;
a second wireless communication module 272 for receiving the reference signal transmitted from the first wireless communication module 50 and transmitting it to each variable wheel module 200;
The control unit 40 includes a transfer direction determining module 42 that determines which direction of the left, right, and straight directions to transfer the object 1 based on the location information of the object 1, and the transfer direction determination module ( Based on the transport direction of the object 1 and the weight information of the object 1 determined in 42), a reference signal for adjusting the left-right rotation angle of the servo motor 270 of each variable wheel module 200 is generated. A signal generating module 44 is included, and the control unit 40 includes reference signals corresponding to the optimum rotation angle of the individual servo motors 270 according to the weight of the object 1 set in advance for each transport direction of the object 1 . Doedoe database, the reference signals are to control the servomotor 270 with the optimal rotation angle value for each weight obtained by performing a trial run while repeatedly changing the weight of the object 1 and the rotation angle of the servomotor 270 in advance. As a signal for the purpose, it is allocated for each servo motor 270 and stored in advance, The reference signal generating module 44 generates and outputs the reference signals of the individual servo motors 270 according to the weight of the actual object 1 with reference to the reference signal database;
The transfer wheels 220 of each variable wheel module 200 are all independently driven, and the angle of the transfer wheels 220 of each variable wheel module 200 is individually controlled according to the weight of the object 1 wheel sorter with delete delete delete The method of claim 1,
A motor controller 274 that receives a reference signal received from the second wireless communication module 272 and outputs a control signal corresponding to the reference signal, and a drive corresponding to the control signal output from the motor controller 274 Wheel sorter further comprising a motor drive (276) for inputting electric power to the servo motor (270). delete

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