TW201503986A - Multiple machine tool operating system - Google Patents

Abstract

Disclosed is a multiple machine tool operating system, comprising at least one control device and a plurality of machine tools. The control device comprises a data unit and a first transceiving module. The machine tool comprises an executing module and a second transceiving module. The first transceiving module and the second transceiving module communicate with each other and are employed to modulate and transmit data, or to receive and demodulate the data for operations. By separating the computer and the machine tools, more efficient application and higher machine utilization rate can be achieved. With data correction and modulation/demodulation of data transmission, distortion or noise interference caused by network transmission or compression can be avoided and the management of the one-to-many or the many-to-many operation system can be realized.

Description

Multi-tool operating system

The invention relates to a multi-tool machine operating system, in particular to a control device and a machine tool one-to-many, or a many-to-many operating system.

At present, the automatically controlled machine tools, such as Computer Numerical Control (CNC) lathes, are usually equipped with an industrial computer with an execution module, such as a tool module, a cooling water module, and a cutting oil module. An operator comes in, the so-called one-to-one mode. However, when the order quantity is large, there may not be so many operators to operate, which leads to the lack of personnel, and may cause the tool machine to be less dynamic.

With the improvement of computer performance, multi-core mobile phones or tablet PCs now work better than previous industrial PCs. While the network speed is increasing, theoretically one-to-many mode is feasible, but existing ones. The situation is the compression and interference of network packets, which is easy to produce data errors. This may lead to production processes and data errors, which may affect the production products. In addition, the network may have unstable conditions and cause data transmission. Stagnant, lost or wrong, therefore, a system that can solve the above problems is needed.

SUMMARY OF THE INVENTION A primary object of the present invention is to provide a multi-tool operating system comprising at least one control device and a plurality of power tools, the at least one control device and the power tool communicating with each other through at least one of a wired or wireless network architecture. The control device includes a data unit and a first transmission receiving module, wherein the data unit is configured to generate a product production data to be produced in the machine tool, and the first transmission receiving module is connected to the data unit to receive the production material of the product, and The production data of the product is converted into a modulation data and transmitted to the machine tool, or the signal sent back from the machine tool is received and demodulated.

Each of the machine tools includes an execution module and a second transmission and reception module, and the second transmission The sending and receiving module communicates with the first transmitting and receiving module, and is connected to the executing module for receiving the modulated data transmitted by the first transmitting and receiving module, and demodulating the modulated data into The product production data is transmitted to the execution module for product production, and receives the feedback signal from the execution module, and the feedback signal is converted into a modulation feedback signal, and then transmitted back to the first transmission receiving module. The first transmitting and receiving module demodulates the modulated feedback signal into a feedback signal and transmits the signal to the data unit.

The first transmission receiving module includes a first data correction unit, a first data modulation/demodulation unit, and a first transmission/reception unit, and the second transmission reception module includes a second data correction unit, Two data modulation/demodulation unit, and a second transmission/reception unit. The first data correction unit is connected to the data unit, automatically corrects the production data of the product, and outputs the automatically corrected product production data, and the first data modulation/demodulation unit is connected to the first data correction unit to receive The automatically corrected product production data is modulated and the production data is modulated to produce the modulated data. The first transmission/reception unit is connected to the first data modulation/demodulation unit, receives the modulation data, and transmits the modulation data.

The second transmitting/receiving unit and the first transmitting/receiving unit communicate with each other, receive the modulated data and output, and the second data modulation/demodulation changing unit is connected to the second transmitting/receiving unit to receive the modulation Data, and demodulating the modulated data into product production data, and outputting the second data correcting unit to the second data modulation/demodulation unit, receiving the product production data and performing data correction again before transmitting To the execution module. The feedback data generated by the execution module based on the production data of the product is also reversed in this way.

Further, the first/second transmission receiving module further includes at least one data transmission interface, for example, a memory card slot, a universal bus slot, a 1394 slot, an HDMI slot, etc., which may be urgent or network When the transmission status is unstable, the data is directly transmitted.

The invention separates the computer and the machine tool, can achieve more efficient application, and higher mechanical home rate, and cooperates with data correction and modulation/demodulation data transmission to avoid network transmission or compression. The resulting distortion or noise interference can achieve one-to-many or many-to-many operating system management.

1‧‧‧Multi-tool machine operating system

10‧‧‧Control device

11‧‧‧data unit

13‧‧‧First Transmission Receiver Module

20‧‧‧Tool machine

21‧‧‧Execution module

23‧‧‧Second transmission receiving module

25‧‧‧Data transmission interface

31‧‧‧Data Correction Unit

33‧‧‧First data modulation/demodulation unit

35‧‧‧First transmission/reception unit

41‧‧‧Second data correction unit

43‧‧‧Second data modulation/demodulation unit

45‧‧‧Second transmission/reception unit

The first figure is a schematic diagram of a unit of the multi-tool machine operating system of the present invention.

The second figure is a detailed schematic diagram of the first transmission receiving module and the second transmission receiving module in the first figure.

The third figure is a detailed schematic diagram of the first transmission receiving module or the second transmission receiving module in the first figure.

The embodiments of the present invention will be described in more detail below with reference to the drawings and the <RTIgt; </ RTI> <RTIgt; </ RTI> <RTIgt; </ RTI> <RTIgt; </ RTI> <RTIgt;

Referring to the first figure, a schematic diagram of a unit of the multi-tool machine operating system of the present invention. As shown in the first figure, the multi-tool operating system 1 of the present invention comprises at least one control device 10 and a plurality of power tools 20, the at least one control device 10 and the power tool 20 being at least through a wired or wireless network architecture. A mutual communication. The control unit 10 includes a data unit 11 and a first transmission and reception module 13. The data unit 11 is used to generate a product production data to be produced in the machine tool 20, and the first transmission and reception module 13 and the data unit 11 Connecting, receiving the production data of the product, and converting the production data of the product into a modulation data and transmitting it to the machine tool 20, or receiving the signal sent back from the machine tool 20, and performing demodulation, wherein the control device 10 can For computers, mobile phones, or tablets. In addition, the first transmitting and receiving module 13 may be installed inside the control device 10 or additionally mounted outside the control device 10.

Each of the power tool 20 includes an execution module 21 and a second transmission and reception module 23 . The second transmission and reception module 23 communicates with the first transmission and reception module 13 and is connected to the execution module 21 for The modulated data transmitted by the first transmitting and receiving module 13 is received, and the modulated data is demodulated into product production materials, and then transmitted to the execution module 21 for product production, and received from the execution module 21 The feedback signal is converted into a modulated feedback signal, and then transmitted back to the first transmitting and receiving module 13, and the first transmitting and receiving module 13 then demodulates the modulated feedback signal into feedback. The signal is then transmitted to the data unit 11. In addition, the second transmitting and receiving module 23 can be installed inside the power tool 20 or additionally mounted outside the power tool 20 .

Referring to the second figure, a detailed schematic diagram of the first transmission receiving module and the second transmission receiving module in the first figure. As shown in the second figure, the first transmission receiving module 13 includes a first data correction unit 31, a first data modulation/demodulation unit 33, and a first transmission/reception unit 35. The second transmitting and receiving module 23 includes a second data correcting unit 41, a second data modulation/demodulation unit 43, and a second transmitting/receiving unit 45. The first data correcting unit 31 is connected to the data unit 11, automatically corrects the product production data, and outputs the automatically corrected product production data, the first data modulation/demodulation unit 33 and the first data correcting unit. 31 is connected, receives the automatically corrected product production data, and modulates the production data of the product to generate the modulated data. The first transmission/reception unit 35 is connected to the first data modulation/demodulation conversion unit 33, receives the modulation data, and transmits it.

The second transmission/reception unit 45 and the first transmission/reception unit 35 communicate with each other Receiving the modulated data and outputting, the second data modulation/demodulation unit 43 is connected to the second transmission/reception unit 45, receives the modulated data, and demodulates the modulated data into a product. After the production data is output, the second data correction unit 41 is connected to the second data modulation/demodulation conversion unit 43 to receive the product production data and perform data correction again before transmitting to the execution module 21. The feedback data generated by the execution module 21 based on the production data of the product is also reversed in this manner, and is not described herein.

Referring to the third figure, the first transmission receiving module or the second transmission receiving module in the first figure Detailed schematic of the group. A schematic of another embodiment. As shown in the third figure, the first transmission receiving module 13 or the second transmission receiving module 23 further includes at least one data transmission interface 25, and the data transmission interface 25 can be a memory card slot and a universal bus slot. At least one of the 1394 slot and the HDMI slot can transmit data directly in an emergency or when the network transmission state is unstable. The invention is characterized in that the computer and the machine tool are separated, which can achieve more efficient application, and higher mechanical home rate, and can cooperate with data correction and modulation/demodulation data transmission to avoid network transmission. Or the distortion or noise interference caused by compression, or the data discontinuity when the transmission is stagnant, and can achieve one-to-many or many-to-many operating system management. .

The above is only a preferred embodiment for explaining the present invention, and is not intended to be It is intended that the present invention be construed as being limited by the scope of the invention.

1‧‧‧Multi-tool machine operating system

10‧‧‧Control device

11‧‧‧data unit

13‧‧‧First Transmission Receiver Module

20‧‧‧Tool machine

21‧‧‧Execution module

23‧‧‧Second transmission receiving module

Claims (10)

A multi-tool machine operating system comprising: at least one control device comprising a data unit and a first transmission receiving module, wherein the data unit is configured to generate a product production data, and the first transmission receiving module and the data unit Connecting, receiving the production data of the product, and converting the production data of the product into a modulated data; and a plurality of machine tools, each of the machine tools comprising an execution module and a second transmission receiving module, the second The transmitting and receiving module communicates with the first transmitting and receiving module, and is connected to the executing module for receiving the modulated data transmitted by the first transmitting and receiving module, and demodulating the modulated data. After the production data of the product is transferred to the execution module for product production, and receiving a feedback signal from the execution module, and converting the feedback signal into a modulation feedback signal, returning to the first The receiving module is transmitted, and the first transmitting and receiving module demodulates the modulated feedback signal into a feedback signal and then transmits the signal to the data unit. The multi-tool machine operating system of claim 1, wherein the second transmitting and receiving module and the first transmitting and receiving module communicate with each other by at least one of a wired or wireless network architecture. The multi-tool machine operating system of claim 1, wherein the first transmitting and receiving module is installed inside the control device. The multi-tool machine operating system of claim 1, wherein the first transmitting and receiving module is installed outside the control device. The multi-tool machine operating system of claim 1, wherein the second transmission and reception The module is mounted inside the machine tool. The multi-tool machine operating system of claim 1, wherein the second transmitting and receiving module is installed outside the machine tool. The multi-tool machine operating system of claim 1, wherein the at least one control device comprises at least one of a computer, a mobile phone, or a tablet computer. The multi-tool operating system of claim 1, wherein the first transmitting and receiving module comprises a first data correcting unit, a first data modulation/demodulation unit, and a first transmission/ a receiving unit, wherein the second transmitting and receiving module comprises a second data correcting unit, a second data modulation/demodulation unit, and a second transmitting/receiving unit, wherein the first data correcting unit is connected to the data unit Automatically correcting the production data of the product, and outputting the automatically corrected product production data, the first data modulation/demodulation unit is connected with the first data correction unit, and receiving the automatically corrected product production data. And modulating the production data of the product to generate the modulation data, the first transmission/reception unit is connected to the first data modulation/demodulation unit, receiving the modulation data, and transmitting the data The second transmitting/receiving unit and the first transmitting/receiving unit communicate with each other, receive the modulated data and output, and the second data modulation/demodulation changing unit is connected to the second transmitting/receiving unit, Receiving the modulation data, and demodulating the modulation data into product production materials, and outputting the second data correction unit to the second data modulation/demodulation conversion unit, receiving the production data of the product and performing again The data is corrected and then transmitted to the execution module, and the execution module is reversed according to the above unit based on the feedback data generated by the product production data. The multi-tool machine operating system of claim 1, wherein the second transmitting/receiving unit and the second transmitting/receiving unit are at least one phase of a wired or wireless network architecture. Mutual communication. The multi-tool machine operating system of claim 1, wherein one of the first transmission receiving module and the second transmission receiving module comprises at least one data transmission interface, and the at least one data transmission interface comprises At least one of a memory card slot, a universal bus slot, a 1394 slot, and an HDMI slot.