CN112666897A - System combining dynamic production and braiding machine work management - Google Patents

Abstract

A system combining dynamic production and braiding machine work management comprises a production demand management unit, an advanced scheduling management unit, a cloth sample storage unit and a manufacturing execution unit. When the weaving machine is used, the production requirement management unit receives at least one piece of production requirement data, the advanced schedule management unit generates a piece of production schedule data according to a plurality of knitting machine working conditions and the production requirement data, the cloth sample storage unit stores a plurality of knitting machine working setting data, the manufacturing execution unit enables each knitting machine to extract one piece of knitting machine working setting data from the cloth sample storage unit for weaving based on one piece of production cloth sample data of the production schedule data, and the knitting machine forcibly deletes the currently used knitting machine working setting data when the weaving times of the knitting machine reach the weaving time limit set by the production schedule data.

Description

System combining dynamic production and braiding machine work management

Technical Field

The invention relates to a system, in particular to a system combining dynamic production and braiding machine work management.

Background

According to the prior art, the currently used cloth sample data is not automatically deleted immediately after the weaving operation of the existing weaving machine is completed, that is, the cloth sample data stored in each weaving machine is deleted from the machine only by additional operation of staff. Therefore, no-standing staff in the factory can take the machine, once the staff steals the patterns in the machine to carry out production by themselves and sells the products in advance before the products are sold in the factory, the factory is suspected of violating the security agreement of the client side, and the credit of the factory is damaged. Furthermore, if the employee steals the document and jumps to a competing company, it is a serious injury to the factory.

Disclosure of Invention

The main purpose of the invention is to solve the problem that the conventional weaving machine cannot delete the cloth sample data immediately after finishing the weaving operation and the cloth sample data flows out of the factory.

To achieve the above objective, the present invention provides a system for combining dynamic production and knitting machine operation management, which comprises a production requirement management unit, an advanced scheduling management unit, a cloth sample storage unit, and a manufacturing execution unit. The production demand management unit receives at least one piece of production demand data, the advanced schedule management unit is in information connection with the production demand management unit and generates production schedule data according to working conditions of a plurality of knitting machines arranged in a factory and the production demand data, the production schedule data comprises a plurality of sub-schedule data corresponding to the knitting machines, each sub-schedule data only corresponds to one of the knitting machines and comprises a piece of production cloth sample data and weaving frequency limiting data corresponding to the production cloth sample data, the cloth sample storage unit stores a plurality of knitting machine working setting data, cloth samples corresponding to the knitting machine working setting data are different, the cloth samples compiled by each knitting machine working setting data respectively correspond to one piece of the production cloth sample data, and the manufacturing execution unit is in information connection with the advanced schedule management unit and the cloth sample storage unit, and each knitting machine is enabled to work according to one of the sub-schedule data, each knitting machine extracts one of the knitting machine work setting data from the cloth sample storage unit based on the production cloth sample data contained in one of the sub-schedule data to perform weaving, and when the weaving times of the knitting machine reach the setting of the weaving time limit data, the knitting machine forcibly deletes the currently used knitting machine work setting data.

In one embodiment, the system includes a storage management unit and a delivery scheduling unit, the manufacturing execution unit has a plurality of material data generated according to each sub-schedule data, the storage management unit records a plurality of material storage data, the material storage data includes a name information, a position information and a quantity information, the delivery scheduling unit information connects the manufacturing execution unit and the storage management unit, and the delivery scheduling unit controls at least one of a plurality of transfer robots to transfer a corresponding production material to a corresponding one of the knitting machines according to the material data based on one of the sub-schedule data that one of the knitting machines is ready to implement.

In one embodiment, the transportation scheduling unit is in communication with at least one auxiliary handling device within the factory floor, and the transportation scheduling unit controls the auxiliary handling device according to a handling route of one of the handling robots.

In one embodiment, the auxiliary transportation device is a lifting device, a conveyor belt or a robot.

In one embodiment, the transfer scheduling unit records a plurality of factory location points, and controls the transfer robots to move based on the factory location points.

In one embodiment, the transportation scheduling unit is in communication with at least one portable electronic device held by a worker, and the transportation scheduling unit controls at least one of the transportation robots to transport based on a designated transport request sent by the portable electronic device.

In one embodiment, the manufacturing execution unit receives a good quantity data and a bad quantity data after each sub-schedule data is executed, and the advanced schedule management unit adds a supplementary production sub-schedule data to the production schedule data based on the working conditions of the knitting machines, the production demand data and the bad quantity data.

Compared with the prior art, the invention has the following characteristics: when the weaving times of the weaving machine reach the set weaving time limit data, the invention forcibly deletes the currently used work set data of the weaving machine, so that the work set data of the weaving machine can be deleted without extra operation of staff in the weaving machine, and the production cloth sample data of the invention is free from flowing out.

Drawings

Fig. 1 is a system unit diagram (i) according to an embodiment of the present invention.

Fig. 2 is a schematic diagram of elements of the data of the cloth sample produced according to the working setting data of the knitting machine according to an embodiment of the present invention.

Fig. 3 is a schematic unit diagram of a knitting machine corresponding to the data of the cloth sample produced according to an embodiment of the invention.

Fig. 4 is a system unit diagram (ii) according to an embodiment of the present invention.

Fig. 5 is a system unit diagram (iii) according to an embodiment of the present invention.

FIG. 6 is a factory floor configuration diagram (I) according to an embodiment of the invention.

FIG. 7 is a factory floor configuration diagram (II) according to an embodiment of the invention.

Fig. 8 is a system unit diagram (iv) according to an embodiment of the present invention.

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Work setting data of a knitting machine

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A finished product storage area

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Detailed Description

The present invention is described in detail and technical content with reference to the accompanying drawings, wherein:

referring to fig. 1 to 3, the present invention provides a system 10 for combining dynamic production and knitting machine operation management, the system 10 can be applied in a factory floor 20 to facilitate knitting machine operation management in the factory floor 20, the system 10 includes a production requirement management unit 11, an advanced scheduling management unit 12, a cloth sample storage unit 13 and a manufacturing execution unit 14. Moreover, the production requirement management unit 11, the advanced schedule management unit 12, the cloth sample storage unit 13 and the manufacturing execution unit 14 are components of a computer device (not shown), and the system 10 of the present invention can add different functions to the requirements of the factory floor 20 in practical implementation besides the production requirement management unit 11, the advanced schedule management unit 12, the cloth sample storage unit 13 and the manufacturing execution unit 14.

Further, the production demand management unit 11 receives at least one production demand data 51 during implementation, and the production demand data 51 can be provided to the production demand management unit 11 by a third party 50 outside the system 10, for example, the third party 50 can be at least one company service 501 or at least one customer 502, and the system 10 of the present invention can receive at least one company service 501 or at least one customer 502 to operate the system 10 and provide the production demand data 51 to the production demand management unit 11. The APC 12 is communicatively coupled to the MPU 11, the APC 12 receives the production request data 51 from the MPU 11, and generates a production schedule data 121 based on the production demand data 51 and the operation of the plurality of knitting machines 21 in the factory floor 20, wherein the knitting machines 21 can be a circular knitting machine or a flat knitting machine, respectively, and the production schedule data 121 describes the scheduled operation of each knitting machine 21 in the factory floor 20, for example, the production schedule data 121 can be used to describe the machine start time, the process time and the end time of each knitting machine 21 during the weaving operation, that is, the production schedule data 121 includes a plurality of sub-schedule data 122 corresponding to the knitting machines 21, and each sub-schedule data 122 corresponds to only one knitting machine 21. Furthermore, each of the sub-schedule data 122 includes a production cloth sample data 123 and a weaving number limit data corresponding to the production cloth sample data 123, the production cloth sample data 123 is a cloth pattern to be woven for each batch of cloth, and the weaving number limit data indicates the number of weaving times that each of the weaving machines 21 can weave the cloth pattern based on each of the sub-schedule data 122. For example, if the factory floor 20 includes the two knitting machines 21, the production schedule data 121 of the advanced schedule management unit 12 is configured to perform 100-fold jogging shoe upper knitting operations including a star by using the two knitting machines 21, at this time, the advanced schedule management unit 12 will make the production schedule data 121 include two sub-schedule data 122, each sub-schedule data 122 corresponds to one of the knitting machines 21, the production pattern data 123 of each sub-schedule data 122 is the shoe upper pattern including the star, and the knitting number limit data is 50, in other words, the production schedule data 121 will make the two knitting machines 21 knit 50-fold jogging shoe uppers including the star.

Further, the cloth sample storage unit 13 is in communication with the advanced scheduling management unit 12, the cloth sample storage unit 13 stores a plurality of knitting machine operation setting data 131, and the knitting machine operation setting data 131 may include operation settings of the knitting machines 21 during knitting, for example, the operation settings may be a needle-out state, a yarn feeding mode, and the like. Moreover, the patterns corresponding to the knitting machine working setting data 131 are different, and the patterns produced by each knitting machine working setting data 131 respectively correspond to the pattern of one of the production pattern data 123. In one embodiment, the cloth sample storage unit 13 can be implemented by a cloth sample designer, a loom manufacturer, or a textile manufacturer, and besides the cloth sample storage unit 13 can be a component of the computer device, the cloth sample storage unit 13 can also be a cloud database, i.e., the knitting machine working setting data 131 can be downloaded through a cloud during implementation. Furthermore, the manufacturing execution unit 14 is in communication with the advanced schedule management unit 12 and the cloth sample storage unit 13, and the manufacturing execution unit 14 enables each knitting machine 21 to operate according to one of the sub-schedule data 122, specifically, each knitting machine 21 extracts the knitting machine operation setting data 131 corresponding to the production cloth sample data 123 from the cloth sample storage unit 13 based on the production cloth sample data 123 included in one of the sub-schedule data 122, and performs knitting operation based on the knitting machine operation setting data 131. Further, when the knitting machine 21 sets the limit data of the number of times of weaving, the currently used operation setting data 131 of the knitting machine is forcibly deleted, for example, when the sub-schedule data 122 received by each knitting machine 21 describes that the limit data of the number of times of weaving is 20, the knitting machine 21 forcibly deletes the operation setting data 131 of the knitting machine after the knitting machine 21 performs 20 weaving operations.

Referring to fig. 1 to 3, the system 10 for dynamic production and knitting machine operation management according to the present invention is now described, first assuming that the production requirement management unit 11 receives the production requirement data 51 initially, and then the advanced scheduling management unit 12 outputs the production scheduling data 121 based on the production requirement data 51 and the operating status of the knitting machines 21 to be processed and manufactured after receiving the production requirement data 51 from the advanced scheduling management unit 12. The cloth sample storage unit 13 pre-stores each of the knitting machine operation setting data 131 corresponding to the production demand data 51. Then, the manufacturing execution unit 14 controls each knitting machine 21 based on the knitting machine operation setting data 131 and the production schedule data 121, so that each knitting machine 21 performs knitting. When the number of braids performed by the braiding machine 21 reaches the set value defined by the number of braids, the braiding machine 21 stops the weaving operation and forcibly deletes the braiding machine operation setting data 131 used at present. Accordingly, the present invention makes it possible to limit the weaving times of each knitting machine 21 by including the weaving time limit data in each sub-schedule data 122 of the advanced schedule management unit 12. Furthermore, the present invention forcibly deletes the currently used knitting machine operation setting data 131 when the knitting machine 21 sets the number of times of weaving to the number of times of weaving limit data, so that the production cloth pattern data 123 of the present invention is free from the misgivings.

In one embodiment, referring to fig. 4, the weaving time limit data indicates the total number of times the weaving machine 21 weaves based on each of the sub-schedule data 122, that is, the weaving machine 21 has a chance to produce a defective product during the weaving process based on the weaving time limit data. In order to avoid that the knitting machine 21 cannot complement the number of defective products due to the limited number of weaving times data after the knitting machine 21 produces defective products, the manufacturing execution unit 14 receives a good product number data and a defective product number data 141 after each sub-schedule data 122 is executed, and the advanced schedule management unit 12 adds a supplementary production sub-schedule data 124 to the production schedule data 121 based on the working status of the knitting machine 21, the production demand data 51, and the defective product number data 141. In practice, the apc unit 12 generates the supplemental production sub-schedule data 124 according to the operation status of the knitting machine 21 that will complete the current sub-schedule operation, and the manufacturing execution unit 14 makes the knitting machine 21 continuously produce the defective products according to the supplemental production sub-schedule data 124. In another embodiment, the MES 14 may also control one of the knitting machines 21 to perform the complementary production based on the complementary production sub-schedule data 124 after the knitting machines 21 have completed the knitting operation.

In another aspect, referring to fig. 5, the system 10 may further include a storage management unit 15 and a delivery scheduling unit 16, the storage management unit 15 is in communication with the production demand management unit 11, the storage management unit 15 records a plurality of material storage data, the material storage data respectively corresponds to one of a plurality of production materials, the material storage data respectively includes a name information, a quantity information and a position information, the name information referred to herein is a material name of each production material, the quantity information is a material quantity of each production material, and the position information is a location where each production material is placed. Further, referring to fig. 6, the place for placing the production materials is a plurality of operation areas 22 in the factory area 20, the operation areas 22 can be provided with the knitting machines 21 according to the requirement, and the operation areas 22 include a receiving area 221 for placing the raw materials when the raw materials enter the factory, a raw material storage area 222 for storing the raw materials, a production processing area 223 for processing the raw materials to form semi-finished products, a product inspection buffer area 224 for temporarily storing the semi-finished products to be inspected, a finished product storage area 225 for storing the finished products, and a to-be-shipped area 226 for placing the finished products to be shipped. Also, for example, assuming that 3000 jogging shoe cloth finished products are placed in the finished product storage area 225 in the factory floor 20, the warehouse management unit 15 records the product name of one of the production materials as jogging shoe cloth finished product, the number of the production materials as 3000, and the placement location as the finished product storage area 225.

Referring back to fig. 1 and 6, the delivery scheduling unit 16 is in communication with the manufacturing execution unit 14 and the stocker management unit 15, and the delivery scheduling unit 16 controls at least one of the plurality of transfer robots 60 to transfer the corresponding production material to the corresponding one of the knitting machines 21 according to the material data based on one of the sub-schedule data 122 prepared for implementation by one of the knitting machines 21. For example, when one of the sub-schedule data 122 describes that the batch of production materials is to be produced, the required raw materials are first taken out from the raw material storage area 222, then the raw materials are woven and then the quality inspection is performed, the transportation scheduling unit 16 controls at least one of the transportation robots 60 based on the sub-schedule data 122, so that the at least one of the transportation robots 60 firstly moves the required raw materials to the production processing area 223 from the raw material storage area 222 to be woven, and after the weaving is completed, the transportation scheduling unit 16 controls at least one of the transportation robots 60 again to move the woven materials to the quality inspection buffer area 224 from the transportation robot 60 to the production processing area 223 to be inspected. In one embodiment, when the transportation scheduling unit 16 is controlling the transfer robots 60, the transportation scheduling unit 16 does control the transportation routes of each transfer robot 60 in the operation zones 22, a plurality of factory location points may be located in the factory floor 20, and the transportation scheduling unit 16 records the factory location points. In practice, the transportation scheduling unit 16 can control the transfer robots 60 based on the factory locations, so that each transfer robot 60 can travel on the corresponding transfer route without causing interference problems such as collision. Further, the transportation scheduling unit 16 may also monitor the traveling status of each of the transfer robots 60 based on each of the factory locations, for example, at least one factory location may be respectively disposed in the raw material storage area 222 and the production processing area 223 in the factory 20, and when the transportation scheduling unit 16 is intended to control at least one of the transfer robots 60 to transfer raw materials from the raw material storage area 222 to the production processing area 223, the transportation scheduling unit 16 controls at least one of the transfer robots 60 to first pass through the factory location of the raw material storage area 222 and then pass through the factory location of the production processing area 223. Once the controlled transfer robot 60 passes through the factory location point of the raw material storage area 222 and does not reach the factory location point of the production processing area 223 within a predetermined time, the transportation scheduling unit 16 enables the personnel in the factory 20 to find the abnormality of the transfer robot 60 as soon as possible due to the fact that the travel path of the controlled transfer robot 60 is not recorded, thereby reducing the time required for abnormality elimination. In addition, the transportation scheduling unit 16 can also control the transportable range of the transfer robots 60 through the factory location points, for example, the factory location points are respectively set in the receiving area 221, the raw material storage area 222, the production processing area 223, the product inspection buffer area 224, the finished product storage area 225 and the to-be-shipped area 226 in the factory 20, and the transfer robots 60 are divided into a first transfer robot 61 going to and from the receiving area 221 and the raw material storage area 222, a second transfer robot 62 going to and from the raw material storage area 222 and the production processing area 223, a third transfer robot 63 going to and from the production processing area 223 and the product inspection buffer area 224, a fourth transfer robot 64 going to and from the product inspection buffer area 224 and the finished product storage area 225, and a fifth transfer robot 65 going to and from the finished product storage area 225 and the to-be-shipped area 226, accordingly, the transportation scheduling unit 16 controls the transportability ranges of the transfer robots 60, so that the system 10 can reduce the waiting time required for transportation.

In view of the above, in one embodiment, and referring to fig. 7, the transfer robots 60 may be obstructed from moving due to a slope or an obstacle that may be disposed in the factory floor 20, and the factory floor 20 includes at least one auxiliary transfer device 23 connected to the transfer scheduling unit 16. In one embodiment, the auxiliary carrying device 23 may be a lifting device, a conveyor belt or a robot. In practice, the transportation scheduling unit 16 controls the auxiliary transportation device 23 according to the transportation route of one of the transportation robots 60, in other words, when the transportation robot 60 transports production materials, the transportation robot 60 approaches an obstacle in the factory floor 20 gradually, and the transportation scheduling unit 16 controls the auxiliary transportation device 23 to enable the auxiliary transportation device 23 to take over the production materials transported by the transportation robot 60 to continue the movement of the production materials. For example, since the factory floor 20 has a slope in the production area 223 and the inspection buffer 224 and the lifting device is disposed at a position corresponding to the slope, when the transfer robots 60 leave the production area 223, the transportation scheduling unit 16 controls the lifting device to enable the lifting device to take over the materials transferred by the transfer robots 60, thereby assisting the transfer robots 60 to transfer the materials to the inspection buffer 224 for inspection.

In one embodiment, referring to FIG. 8, in addition to the system 10 controlling the transfer robots 60 based on each of the sub-schedule data 122 with the transfer dispatch unit 16, the transfer dispatch unit 16 may also control at least one of the transfer robots 60 to transfer based on a designated transfer request 71 issued by a portable electronic device 70 held by a worker. In other words, when the worker in the factory has a demand for transporting the production materials, the worker can operate the portable electronic device 70 to make the portable electronic device 70 send the specified transporting request 71 and transmit the specified transporting request to the transporting and dispatching unit 16, and at this time, the transporting and dispatching unit 16 controls at least one of the transporting robots 60 to move to the specified operation area 22 for transporting.

The present invention may be embodied in other specific forms without departing from the spirit or essential attributes thereof, and it should be understood that various changes and modifications can be effected therein by one skilled in the art without departing from the spirit and scope of the invention as defined in the appended claims.

Claims (7)

1. A system for integrating dynamic production with work management of a knitting machine, comprising:

a production demand management unit for receiving at least one production demand data;

an advanced scheduling management unit, the information of which is connected with the production demand management unit, and which outputs a production scheduling data according to the working conditions of a plurality of knitting machines arranged in a factory and the production demand data, wherein the production scheduling data comprises a plurality of sub-scheduling data corresponding to the knitting machines, and each sub-scheduling data only corresponds to one of the knitting machines and comprises a production cloth sample data and a weaving number limiting data corresponding to the production cloth sample data;

the cloth sample storage unit stores a plurality of knitting machine working setting data, the cloth samples corresponding to the knitting machine working setting data are different, and the cloth sample compiled by each knitting machine working setting data respectively corresponds to one of the production cloth sample data; and

and the manufacturing execution unit is in information connection with the advanced schedule management unit and the cloth sample storage unit, so that each knitting machine works according to one of the sub-schedule data respectively, each knitting machine extracts one of the knitting machine working setting data from the cloth sample storage unit based on the production cloth sample data contained in one of the sub-schedule data to perform weaving, and the knitting machine forcibly deletes the currently used knitting machine working setting data when the weaving frequency reaches the weaving frequency limit data setting.

2. The system of claim 1, wherein the system comprises a stocker management unit and a delivery scheduling unit, the manufacturing execution unit has a plurality of material data generated according to each of the sub-schedule data, the stocker management unit records a plurality of material storage data, the material storage data respectively comprises a name information, a position information and a quantity information, the delivery scheduling unit information connects the manufacturing execution unit and the stocker management unit, the delivery scheduling unit controls at least one of the plurality of delivery robots to deliver the corresponding production material to the corresponding one of the knitting machines according to the material data based on one of the sub-schedule data to be executed by the knitting machine.

3. The system for integrated dynamic production and braiding machine work management of claim 2, wherein the delivery scheduling unit records a plurality of factory location points, and the delivery scheduling unit controls the transfer robot activities based on the factory location points.

4. The system of claim 2, wherein the transfer scheduling unit is in communication with at least one portable electronic device held by a worker, the transfer scheduling unit controlling at least one of the transfer robots to transfer based on a designated transfer request from the portable electronic device.

5. The system for integrated dynamic production and braiding machine work management of claim 2, wherein the delivery scheduling unit is in communication with at least one auxiliary handling device within the factory floor, the delivery scheduling unit controlling the auxiliary handling device according to a handling route of one of the handling robots.

6. The system for integrated dynamic production and braiding machine work management of claim 5, wherein the auxiliary handling device is a lifting device, a conveyor belt, or a robotic arm.

7. The system of any one of claims 1 to 6, wherein the manufacturing execution unit receives a good quantity data and a bad quantity data after each sub-schedule data is executed, and the advanced schedule management unit adds a supplementary production sub-schedule data to the production schedule data based on the working status of the knitting machines, the production demand data, and the bad quantity data.

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