CN114722576A - Simulation method and simulation system - Google Patents

Abstract

The application discloses a simulation method and a simulation system, wherein the simulation method comprises the following steps: acquiring order information, equipment configuration information and processing mode information; determining a workpiece to be processed according to the order information; determining processing equipment needing to be configured according to the equipment configuration information; determining the processing logic of the processing equipment according to the processing mode information; selecting processing equipment according to preset conditions; controlling the machining equipment to perform simulation machining on the workpiece according to the machining logic; and outputting visual display information according to the simulation result, and obtaining productivity information according to the order information, the equipment information and the simulation result. According to the technical scheme, the large-scale production process can be efficiently simulated, and visual display information and evaluation information are provided.

Description

Simulation method and simulation system

Technical Field

The present application relates to the field of simulation technologies, and in particular, to a simulation method and a simulation system.

Background

With the continuous improvement of market demand, the traditional single equipment carries out the cutting of single technology to panel in order to can't satisfy large-scale, the demand of wholesale.

In order to meet the requirements of large-scale and efficient production, the field of plate cutting is gradually developed into the way that a plurality of devices work simultaneously, and the plates can be cut by different processes.

However, in such a large-scale production process, the conventional simulation system with a single device cannot meet the requirement for intuitively demonstrating and evaluating the production process.

Disclosure of Invention

The application provides a simulation method which can efficiently simulate a large-scale production process and provide visual display information and evaluation information.

The simulation method provided by the application comprises the following steps:

acquiring order information, equipment configuration information and processing mode information;

determining a workpiece to be processed according to the order information;

determining processing equipment needing to be configured according to the equipment configuration information;

determining the processing logic of the processing equipment according to the processing mode information;

selecting processing equipment according to preset conditions;

controlling the machining equipment to perform simulation machining on the workpiece according to the machining logic;

and outputting visual display information according to the simulation result, and obtaining productivity information according to the order information, the equipment information and the simulation result.

Optionally, the preset condition includes: the processing apparatus designated by the user or the processing apparatus is in an idle state.

Optionally, the processing mode information is an independent processing mode, and the processing logic is determined to be an independent processing logic according to the independent processing mode;

the step of controlling the machining equipment to perform simulation machining on the workpiece according to the independent machining logic comprises the following steps:

acquiring equipment information of processing equipment;

checking whether the order information contains workpiece information which accords with the process type of the processing equipment;

if yes, acquiring workpiece information, deleting corresponding workpiece information from the order information, and performing simulation machining on the workpiece corresponding to the workpiece information by using the machining equipment;

and if not, deleting the processing equipment information.

Optionally, the processing mode information is a random processing mode, and the processing logic is determined to be random processing logic according to the random processing mode;

the step of controlling the machining equipment to perform simulation machining on the workpiece according to the random machining logic comprises the following steps:

acquiring equipment information of processing equipment;

checking whether the order information contains workpiece information or not;

if yes, acquiring workpiece information, deleting corresponding workpiece information from the order information, and performing simulation machining on the workpiece corresponding to the workpiece information by using the machining equipment;

if not, the simulation is finished.

Optionally, the processing mode information is a hybrid processing mode, and the processing logic is determined to be a hybrid processing logic according to the hybrid processing mode;

the method for carrying out simulation machining on the workpiece by controlling the machining equipment according to the hybrid machining logic comprises the following steps:

acquiring equipment information of processing equipment;

checking whether the order information contains workpiece information which accords with the process type of the processing equipment;

if yes, acquiring workpiece information, deleting corresponding workpiece information from the order information, and performing simulation machining on the workpiece corresponding to the workpiece information by using the machining equipment;

if not, checking whether the order information contains workpiece information or not;

if yes, acquiring workpiece information, deleting corresponding workpiece information from the order information, and simulating the machining of the workpiece corresponding to the workpiece information by using the machining equipment; deleting the processing equipment information;

if not, the simulation is finished.

The present application further provides a simulation system, which includes:

the information acquisition module acquires order information, equipment configuration information and processing mode information;

the simulation module is used for configuring the processing equipment according to the equipment configuration information; determining a processing logic according to the processing mode information; selecting processing equipment according to preset conditions; controlling a machining device to perform simulation machining on the workpiece according to the machining logic;

and the result output module outputs visual display information according to the simulation result and outputs capacity information according to the order information, the equipment information and the simulation result.

Optionally, the order information includes a plurality of pieces of workpiece information, each piece of workpiece information including: the material of the workpiece, the thickness of the workpiece, the number of workpieces, the process type of the workpiece, and the processing time;

and/or, the device information includes: the type of processing equipment and the number of processing equipment.

Optionally, the information obtaining module includes:

the order information module acquires order information;

the device configuration module acquires device configuration information; and

a processing mode module that acquires processing mode information.

Optionally, the result output module includes:

the dynamic display module outputs visual display information according to a simulation result; and

and the data generation module outputs capacity information according to the order information, the equipment configuration information and the simulation result.

Optionally, the processing mode information includes:

the processing equipment carries out simulation processing on the workpieces with matched process types in the independent processing mode;

a random processing mode, wherein processing equipment carries out simulation processing on workpieces of any process type in the random processing mode; and

and in the hybrid processing mode, the processing equipment preferentially performs simulation processing on the workpieces with the matched process types, and if no workpiece with the matched process type exists, the simulation processing is performed on the workpiece with any process type.

The simulation method of the technical scheme of the application firstly needs to obtain order information, equipment configuration information and processing mode information. The workpiece to be machined in the simulation process can be determined according to the order information, the machining equipment to be used in the simulation process can be determined according to the equipment configuration information, and the machining logic of the machining equipment in the simulation process can be determined according to the machining mode information.

The simulation method can carry out simulation on the machining processes of various scales according to actual requirements. In the large-scale machining process, more machining devices are used, and the simulation method can reasonably configure a plurality of machining devices according to needs. Because the number of the processing equipment is large, the preset conditions can be set according to actual needs, the corresponding processing equipment is selected according to the preset conditions, the selected processing equipment carries out simulation processing on the determined workpiece according to the determined processing logic, and the actual processing process can be simulated quickly and effectively.

The simulation method can output visual display information to the simulation result, so that a user can clearly and effectively master related processing conditions before actual production, the user can know whether the design of a production line is reasonable or not according to the display information, the production line can be conveniently and effectively adjusted, and the debugging cost of actual equipment is saved.

The simulation method can also obtain the productivity information according to the order information, the equipment information and the simulation result. The user can clearly know the productivity of the production line according to the productivity information, so that the production and operation cost can be conveniently and effectively calculated and evaluated, and the design of the production line can be adjusted according to the productivity information.

Drawings

In order to more clearly illustrate the embodiments of the present application or the technical solutions in the prior art, the drawings used in the embodiments or the prior art descriptions will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present application, and other drawings can be obtained by those skilled in the art according to the structures shown in the drawings without creative efforts.

FIG. 1 is a schematic structural diagram of an embodiment of a simulation method of the present application;

FIG. 2 is a schematic structural diagram of another embodiment of the simulation method of the present application;

FIG. 3 is a schematic structural diagram of a simulation method according to another embodiment of the present application;

FIG. 4 is a schematic diagram of an embodiment of a simulation system of the present application;

fig. 5 is a schematic structural diagram of another embodiment of the simulation system of the present application.

The implementation, functional features and advantages of the objectives of the present application will be further explained with reference to the accompanying drawings.

Detailed Description

The technical solutions in the embodiments of the present application will be described clearly and completely with reference to the drawings in the embodiments of the present application, and it is obvious that the described embodiments are only some embodiments of the present application, and not all embodiments. All other embodiments, which can be derived by a person skilled in the art from the embodiments given herein without making any creative effort, shall fall within the protection scope of the present application.

It should be noted that all the directional indications (such as up, down, left, right, front, and rear … …) in the embodiment of the present application are only used to explain the relative position relationship between the components, the movement situation, and the like in a specific posture (as shown in the drawing), and if the specific posture is changed, the directional indication is changed accordingly.

In addition, the descriptions referred to as "first", "second", etc. in this application are for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicit ly indicating the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include at least one such feature. In addition, technical solutions between the embodiments may be combined with each other, but must be based on the realization of the technical solutions by a person skilled in the art, and when the technical solutions are contradictory to each other or cannot be realized, such a combination should not be considered to exist, and is not within the protection scope claimed in the present application.

With reference to fig. 1 to 5, the present application provides a simulation method and a simulation system using the simulation method, where the simulation method can set corresponding order information, device configuration information, and processing mode information according to different processing requirements, and the simulation system using the simulation method can efficiently perform simulation on a corresponding processing line, provide corresponding capacity information, and facilitate evaluation of production information.

The simulation method provided by the embodiment of the application comprises the following steps:

acquiring order information, equipment configuration information and processing mode information;

determining a workpiece to be processed according to the order information;

determining processing equipment needing to be configured according to the equipment configuration information;

determining the processing logic of the processing equipment according to the processing mode information;

selecting processing equipment according to preset conditions;

the processing equipment carries out simulation processing on the workpiece according to the processing logic;

and outputting visual display information according to the simulation result, and obtaining productivity information according to the order information, the equipment information and the simulation result.

The order information may include a plurality of pieces of workpiece information, and each piece of workpiece information may include one or more of a material of the workpiece, a thickness of the workpiece, a number of the workpieces, a process type of the workpiece, and the like.

The equipment configuration information may include at least one of a process type of the processing equipment and a number of the processing equipment. When the equipment configuration information only comprises the process type of the processing equipment, the simulation system can select the type of the process type of the processing equipment according to the equipment configuration information; when the equipment configuration information only includes the number of the processing equipment, the simulation system can select the number of the processing equipment according to the equipment configuration information; when the device configuration information includes both the process types and the number of the processing devices, the simulation system may select the types of the process types of the processing devices according to the device configuration information and select the number of the processing devices having different process types.

The processing mode information may include methods and steps of the processing equipment in selecting and processing the workpiece.

The simulation method of the technical scheme of the application firstly needs to obtain order information, equipment configuration information and processing mode information. The workpiece to be machined in the simulation process can be determined according to the order information, the machining equipment to be used in the simulation process can be determined according to the equipment configuration information, and the machining logic of the machining equipment in the simulation process can be determined according to the machining mode information.

The simulation method can carry out simulation on the machining processes of various scales according to actual requirements. In the large-scale machining process, more machining devices are used, and the simulation method can reasonably configure a plurality of machining devices according to needs. Because the number of the processing equipment is large, the preset conditions can be set according to actual needs, the corresponding processing equipment is selected according to the preset conditions, the selected processing equipment carries out simulation processing on the determined workpiece according to the determined processing logic, and the actual processing process can be simulated quickly and effectively.

The simulation method can output visual display information to the simulation result, so that a user can clearly and effectively master related processing conditions before actual production, the user can know whether the design of a production line is reasonable or not according to the display information, the production line can be conveniently and effectively adjusted, and the debugging cost of actual equipment is saved.

The simulation method can also obtain the productivity information according to the order information, the equipment information and the simulation result. The user can clearly know the productivity of the production line according to the productivity information, so that the production and operation cost can be conveniently and effectively calculated and evaluated, and the design of the production line can be adjusted according to the productivity information.

The preset conditions may include: the processing apparatus designated by the user or the processing apparatus is in an idle state.

After the processing equipment is configured by the simulation method, the specific processing equipment to be used for processing the workpiece can be selected automatically in a mode designated by a user or according to equipment information.

When the processing equipment is automatically selected through the equipment information, the processing equipment can be selected by judging whether the processing equipment is in an idle state or not. And when the processing equipment is judged to be in the idle state, selecting the corresponding processing equipment.

The idle state of the processing equipment may be a state in which no workpiece is being processed on the processing equipment, and specifically may include: the processing equipment is not starting to process, the processing equipment is finishing processing, and the processing equipment is about to finish processing. The processing equipment is to finish processing, and the processing time and the feeding time of the workpieces are calculated to determine that the previous processing equipment finishes processing or just finishes processing before the next workpiece is transported to the processing equipment.

The preset conditions are set to be that the processing equipment is in an idle state, so that the processing equipment can process the workpiece with the highest efficiency as far as possible, and the simulated production line is ensured to have higher processing efficiency.

Referring to fig. 1, in the above embodiment, the processing mode may be an independent processing mode. When the acquired processing mode information is an independent processing mode, determining that the processing logic is an independent processing logic according to the independent processing mode;

the method for carrying out simulation machining on the workpiece by controlling the machining equipment according to the independent machining logic comprises the following steps:

acquiring equipment information of processing equipment;

checking whether the order information contains workpiece information which accords with the process type of the processing equipment;

if yes, acquiring workpiece information, deleting corresponding workpiece information from the order information, and performing simulation machining on the workpiece corresponding to the workpiece information by using the machining equipment;

and if not, deleting the processing equipment information.

The order information includes a plurality of pieces of workpiece information, and each piece of workpiece information may include a process type corresponding to the workpiece. In the independent processing logic, firstly, workpiece information in the order information is checked, and whether the order information contains the workpiece information meeting the process requirements of the processing equipment is searched. When the process type of the workpiece is matched with that of the processing equipment, the processing equipment processes the workpiece; when the process type of the workpiece does not match the process type of the processing equipment, the processing equipment does not process the workpiece.

When the "yes" condition is executed, the "simulation machining is performed on the workpiece corresponding to the workpiece information by using the machining equipment" only needs to ensure that the workpiece is placed on the machining equipment, the equipment information of the machining equipment can be deleted, and the equipment information of the machining equipment is acquired again according to the preset condition.

When the processing equipment is selected according to the preset condition, the equipment information of the processing equipment is acquired at the same time, and the equipment information may include the process type of the processing equipment.

In the independent processing logic, checking whether the order information contains the workpiece information which accords with the process type of the processing equipment; if yes, acquiring workpiece information, deleting corresponding workpiece information from the order information, and simulating the machining of the workpiece corresponding to the workpiece information by using the machining equipment; and if not, deleting the processing equipment information. The method specifically comprises the following steps:

the process type of the processing equipment is compared with the process type in the piece information in the order information.

If the order information is matched with the workpiece information, acquiring the workpiece information, and deleting the corresponding workpiece information in the order information; carrying out simulation machining on the workpiece corresponding to the workpiece information by using the machining equipment;

and if not, comparing the process type of the processing equipment with the process type of the next piece of workpiece information in the order information, and deleting the processing equipment information until all pieces of workpiece information in the order information are detected.

In the independent processing mode, as long as the processing equipment is idle, the workpieces meeting the process type of the processing equipment in the order information are conveyed to the processing equipment for processing, and the simulation is finished until the workpieces meeting the requirements in the order information are completely processed.

In the independent processing mode, the workpieces can be processed only according to the processing equipment corresponding to the process type corresponding to the workpiece information, other processing equipment cannot be used for processing, the optimal processing effect of each workpiece in the order information can be guaranteed, and the processing quality of the workpieces is high.

Referring to fig. 2, in the above embodiment, the machining mode may be a random machining mode. When the acquired machining mode information is a random machining mode, determining that the machining logic is random machining logic according to the random machining mode;

the step of controlling the machining equipment to perform simulation machining on the workpiece according to the random machining logic comprises the following steps:

acquiring equipment information of processing equipment;

checking whether the order information contains workpiece information or not;

if yes, acquiring workpiece information, deleting corresponding workpiece information from the order information, and performing simulation machining on the workpiece corresponding to the workpiece information by using the machining equipment;

if not, the simulation is finished.

In the random processing mode, as long as there is an idle processing device, the workpiece corresponding to the workpiece information in the order information is conveyed to the processing device for processing, and the simulation is finished until the workpieces in the order information are all processed.

In the random processing mode, the process type of the processing equipment is ignored, the process type corresponding to the workpiece in the workpiece information is ignored, and the idle processing equipment can be used for processing the workpiece, so that the workpiece can be processed more efficiently, and the processing speed of the workpiece is high.

When the "yes" condition is executed, the "simulation machining is performed on the workpiece corresponding to the workpiece information by using the machining equipment" only needs to ensure that the workpiece is placed on the machining equipment, the equipment information of the machining equipment can be deleted, and the equipment information of the machining equipment is acquired again according to the preset condition.

Referring to fig. 3, in the above embodiment, the processing mode may be a hybrid processing mode. When the obtained processing mode is a hybrid processing mode, determining that the processing logic is a hybrid processing logic according to the hybrid processing mode;

the method for carrying out simulation machining on the workpiece by controlling the machining equipment according to the hybrid machining logic comprises the following steps:

acquiring equipment information of processing equipment;

checking whether the order contains workpiece information which accords with the process type of the processing equipment;

if yes, acquiring workpiece information, deleting corresponding workpiece information from the order information, and performing simulation machining on the workpiece corresponding to the workpiece information by using the machining equipment;

if not, checking whether the order information contains workpiece information or not;

if yes, acquiring workpiece information, deleting corresponding workpiece information from the order information, and simulating the machining of the workpiece corresponding to the workpiece information by using the machining equipment; deleting the processing equipment information;

otherwise, the simulation is finished.

In the hybrid processing mode, when idle processing equipment exists, checking whether a workpiece matched with the process type of the processing equipment exists in order information or not, if so, processing according to an independent processing logic, and preferentially processing the matched workpiece; and if not, processing according to the random processing logic to process any workpiece in the order information.

The hybrid processing mode may be regarded as a combination of the independent processing mode and the random processing mode, that is, the independent processing mode is preferentially adopted, and when the conditions of the independent processing mode do not meet, the random processing mode is adopted. The processing time can be saved to the greatest extent under the condition of ensuring the processing quality of the workpiece, and the processing efficiency of the workpiece is ensured.

The application also provides a simulation system, which is used for executing the simulation method. The specific structure of the simulation method refers to the above embodiments, and since the simulation system adopts all the technical solutions of all the above embodiments, at least all the beneficial effects brought by the technical solutions of the above embodiments are achieved, and are not described in detail herein.

Referring to fig. 4, the simulation system includes: the device comprises an information acquisition module, a simulation module and a result output module.

The information acquisition module can acquire order information, equipment configuration information and processing mode information.

The simulation module configures the processing equipment according to the equipment configuration information; determining a processing logic according to the processing mode information; selecting processing equipment according to preset conditions; controlling a machining device to perform simulation machining on the workpiece according to the machining logic;

and the result output module outputs visual display information according to the simulation result and outputs capacity information according to the order information, the equipment information and the simulation result.

In the technical scheme of the application, the information acquisition module is used for acquiring simulation requirements for the simulation system. And the simulation module configures the machining equipment in the simulation system according to the equipment configuration information in the simulation requirement, and performs simulation machining on the workpiece by using the configured machining equipment. The simulation module can perform simulation processing of different scales according to different simulation requirements.

The simulation module configures the processing equipment according to the equipment configuration information, and the simulation module establishes a simulation model according to the equipment configuration information, wherein the simulation model comprises a plurality of processing equipment and other equipment which is matched with the processing equipment on the processing assembly line for operation.

The simulation model may include: stock equipment, loading equipment processing equipment, blanking equipment and the like. And configuring the process types and the number of the processing equipment according to the equipment configuration information. For example: the equipment configuration information comprises one laser cutting machine, and the number of the laser cutting machines is one; the device also comprises two plasma cutting machines; the flame cutting machine is characterized by further comprising one flame cutting machine. The processing equipment provided in the simulation module includes a laser cutting machine, two plasma cutting machines and a flame cutting machine. The feeding device is used for conveying the workpieces in the material warehouse device to the processing device for processing, and the discharging device is used for conveying the workpieces processed by the processing device away.

The simulation module controls the machining equipment to perform simulation machining on the workpiece according to the machining logic specifically comprises the following steps: and the feeding equipment in the simulation model controls the feeding equipment to take out the workpiece on the material warehouse equipment according to the processing logic and convey the workpiece to corresponding processing equipment, the processing equipment processes the workpiece, and the discharging equipment conveys away the workpiece on the processing equipment after the processing is finished.

And a result output module of the simulation system outputs visual display information according to the simulation result of the simulation module and outputs capacity information according to the order information, the equipment information and the simulation result.

The simulation module can adjust the simulation processing according to the obtained different information, the result output module can quickly and effectively carry out visual dynamic display on the simulation processing of the simulation module, visual display information is provided for a user, and the device can be efficiently demonstrated.

The simulation system can also output corresponding capacity information according to the order information, the equipment information and the simulation result, is convenient for managing and controlling production and processing, and can effectively evaluate the value of the equipment.

The method for acquiring the order information, the equipment information and the processing mode information by the information acquisition module can be an information input mode, namely the order information, the equipment information and the processing mode information can be transmitted to the information acquisition module for other equipment except the information acquisition module, and the order information, the equipment information and the processing mode information can be manually input to the information acquisition module.

In the above embodiment, the order information may include a plurality of pieces of workpiece information, and each piece of workpiece information may include a material of the workpiece, a thickness of the workpiece, a number of the workpieces, a process type of the workpiece, a processing time, and the like.

When the simulation process simulated by the simulation module includes a cutting device, a marking device and a sorting device, the processing time may include a cutting time, a marking time, a sorting time, and the like.

The device information may include: the type of processing equipment and the number of processing equipment. The simulation module configures the machining type of the machining apparatus and the number of the machining apparatuses for machining according to the machining type of the machining apparatus and the number of the machining apparatuses.

The information acquisition module may include:

the order information module acquires order information;

the device configuration module is used for acquiring device configuration information;

and the processing mode module is used for acquiring the processing mode information.

Corresponding order information can be input into the order information module according to the requirement, and the process type and the number of the processing equipment can be input into the equipment configuration module according to the requirement.

The process type information of the processing device may include a laser cutting process, a plasma cutting process, and a flame cutting process. The processing equipment with the corresponding process type is selected according to the needs.

When the processing equipment selected by the equipment configuration module is the laser cutting machine when the processing equipment is configured, parameters such as laser wavelength, frequency and focal length of a laser head of the laser cutting machine can be correspondingly matched according to the material information of the workpiece and the thickness information of the workpiece, so that the laser cutting machine can effectively cut the workpiece with the thickness and the material.

According to the quantity information of the workpieces, the equipment configuration module can configure machining equipment with an adaptive quantity for machining so as to meet the machining requirements of users.

In the above embodiment, the result output module can automatically generate a readable capacity report according to the capacity information. The readable production capacity report output by the result output module is convenient for a user to view and interpret.

In the above embodiment, the result output module may include a dynamic display module and a data generation module, and the dynamic display module outputs visual dynamic display information according to the simulation result; and the data generation module outputs capacity information according to the order information, the equipment configuration information and the simulation result of the simulation module.

When a user only needs to display the machining process of the workpiece, the simulation system only executes the dynamic display module to output visual dynamic display information; when the user only needs to obtain the processed capacity information, the simulation system can be controlled to only execute the data generation module, so as to quickly and effectively obtain the capacity information related to the related production. The result output module is divided into the dynamic display module and the data generation module, so that the occupied memory for the operation of the simulation system can be saved, and the operation speed of the simulation system can be increased.

The dynamic display information may include information on positions and states of the workpieces and the devices in the simulation model over time.

The processing mode information may include:

the processing equipment carries out simulation processing on the workpieces with matched process types in the independent processing mode;

a random processing mode, wherein processing equipment carries out simulation processing on workpieces of any process type in the random processing mode; and

and in the hybrid processing mode, the processing equipment preferentially performs simulation processing on the workpieces with the matched process types, and if no workpiece with the matched process type exists, the simulation processing is performed on the workpiece with any process type.

And when the processing mode information acquired by the processing mode setting module is the 'independent processing mode', performing simulation processing according to the independent processing logic. The laser cutting machine processes a workpiece whose process type is laser cutting, but does not process a workpiece whose process type is plasma cutting or flame cutting.

And when the machining mode information acquired by the machining mode setting module is a random machining mode, performing simulation machining according to the random machining logic. The workpieces in the order information can be processed on any processing equipment, and the process types corresponding to the workpieces can be ignored.

And when the machining mode information acquired by the machining mode setting module is a 'hybrid machining mode', performing simulation machining according to the hybrid machining logic. The laser cutting machine preferentially processes the workpiece with the laser cutting process type, and when the order information does not contain the workpiece information with the laser cutting process type, the rest workpieces in the order information are processed, and the process types corresponding to the workpieces are ignored.

In an embodiment of the present application, the configuring, by the simulation module, the processing device according to the device configuration information may include:

the simulation module establishes a simulation model according to the process type of the processing equipment and the number of the processing equipment;

the simulation model comprises a material library, a mechanical arm, marking equipment, feeding equipment, processing equipment, discharging equipment, sorting equipment and tray backflow equipment.

Above-mentioned simulation model can be for panel beating cutting production line simulation model, and above-mentioned processing equipment can include laser cutting equipment, flame cutting equipment and plasma cutting equipment.

The simulation module may control the machining apparatus to perform the simulation machining on the workpiece according to the machining logic, and may include: according to the following steps:

and the material library module simulates and stores corresponding workpieces according to the order information.

And the mechanical arm module is used for simulating and taking out the workpiece in the material library according to the process type and the processing mode information of the processing equipment, conveying the workpiece to the marking equipment and marking the workpiece with related information.

And the marking equipment module is used for marking the workpiece according to the relevant information simulation. The related information includes: the material of the workpiece, the thickness of the workpiece, the processing technology of the workpiece, the processing time, the marking time, the sorting time, the processing equipment information and the like. For example: and if the processing mode information is an independent processing mode, when the mechanical arm takes out the workpiece with the laser cutting process type, the processing equipment information recorded in the related information is the laser cutting machine.

And the feeding equipment module simulates to convey the workpiece from the marking equipment to the processing equipment according to the related information. For example: and if the processing equipment information recorded in the related information is the laser cutting machine, the feeding equipment conveys the workpiece marked on the marking equipment to the laser cutting machine.

And the processing equipment module simulates and finishes the processing process of the workpiece according to the processing time information in the relevant information. The processing equipment may include laser cutters, plasma cutters, and flame cutters.

The blanking equipment module simulates to convey the workpiece from the processing equipment to the sorting equipment;

and the sorting equipment module simulates the sorting process of the sorting equipment to the workpieces according to the sorting time in the relevant information. The sorting equipment simulated by the sorting equipment module can be composed of any number of sorting tables in series or in parallel.

And the tray backflow equipment module simulates the tray bearing the workpiece to flow back to the marking equipment.

The visual dynamic display information output by the dynamic display module in the result output module can display various devices in a workpiece processing assembly line in the simulation module, such as marking devices, feeding devices, processing devices, discharging devices and sorting devices, and further comprises a workpiece, a tray in a push disc backflow device and the like.

The productivity information output by the data generation module in the result output module may include information in the order information module and simulation result data of the simulation module, and the simulation result data may include total processing time, utilization rate of processing equipment, a gantt chart of order information, and the like. The result output module has the function of automatically generating reports and can automatically arrange the data into files readable by users.

The above description is only an alternative embodiment of the present application, and not intended to limit the scope of the present application, and all modifications and equivalents of the technical solutions that can be directly or indirectly applied to other related fields without departing from the spirit of the present application are intended to be included in the scope of the present application.

Claims (10)

1. A simulation method, characterized in that the simulation method comprises:

acquiring order information, equipment configuration information and processing mode information;

determining a workpiece to be processed according to the order information;

determining processing equipment needing to be configured according to the equipment configuration information;

determining the processing logic of the processing equipment according to the processing mode information;

selecting processing equipment according to preset conditions;

controlling the machining equipment to perform simulation machining on the workpiece according to the machining logic;

and outputting visual display information according to the simulation result, and obtaining productivity information according to the order information, the equipment information and the simulation result.

2. The simulation method of claim 1, wherein the preset condition comprises: the processing apparatus designated by the user or the processing apparatus is in an idle state.

3. The simulation method according to claim 1, wherein the machining mode information is an independent machining mode, and the machining logic is determined to be an independent machining logic according to the independent machining mode;

the method for carrying out simulation machining on the workpiece by controlling the machining equipment according to the independent machining logic comprises the following steps:

acquiring equipment information of processing equipment;

checking whether the order information contains workpiece information which accords with the process type of the processing equipment;

if yes, acquiring workpiece information, deleting corresponding workpiece information from the order information, and performing simulation machining on the workpiece corresponding to the workpiece information by using the machining equipment;

and if not, deleting the processing equipment information.

4. The simulation method according to claim 2, wherein the machining mode information is a random machining mode, and the machining logic is determined to be a random machining logic according to the random machining mode;

the step of controlling the machining equipment to perform simulation machining on the workpiece according to the random machining logic comprises the following steps:

acquiring equipment information of processing equipment;

checking whether the order information contains workpiece information or not;

if yes, acquiring workpiece information, deleting corresponding workpiece information from the order information, and performing simulation machining on the workpiece corresponding to the workpiece information by using the machining equipment;

if not, the simulation is finished.

5. The simulation method according to claim 2, wherein the machining mode information is a hybrid machining mode, and the machining logic is determined to be a hybrid machining logic according to the hybrid machining mode;

the method for carrying out simulation machining on the workpiece by controlling the machining equipment according to the hybrid machining logic comprises the following steps:

acquiring equipment information of processing equipment;

checking whether the order information contains workpiece information which accords with the process type of the processing equipment;

if yes, acquiring workpiece information, deleting corresponding workpiece information from the order information, and performing simulation machining on the workpiece corresponding to the workpiece information by using the machining equipment;

if not, checking whether the order information contains workpiece information or not;

if yes, acquiring workpiece information, deleting corresponding workpiece information in the order information, and simulating the machining of the workpiece corresponding to the workpiece information by utilizing the machining equipment; deleting the processing equipment information;

if not, the simulation is finished.

6. A simulation system, characterized in that the simulation system comprises:

the information acquisition module acquires order information, equipment configuration information and processing mode information;

the simulation module is used for configuring the machining equipment according to the equipment configuration information; determining a processing logic according to the processing mode information; selecting processing equipment according to preset conditions; controlling a machining device to perform simulation machining on the workpiece according to the machining logic;

and the result output module outputs visual display information according to the simulation result and outputs capacity information according to the order information, the equipment information and the simulation result.

7. The simulation system of claim 6, wherein the order information comprises a plurality of workpiece information, each workpiece information comprising: the material of the workpiece, the thickness of the workpiece, the number of workpieces, the process type of the workpiece, and the processing time;

and/or, the device information includes: the type of processing equipment and the number of processing equipment.

8. The simulation system of claim 6, wherein the information acquisition module comprises:

the order information module acquires order information;

the device configuration module acquires device configuration information; and

a processing mode module that acquires processing mode information.

9. The simulation system of claim 6, wherein the result output module comprises:

the dynamic display module outputs visual display information according to a simulation result; and

and the data generation module outputs capacity information according to the order information, the equipment configuration information and the simulation result.

10. The simulation system of claim 6, wherein the machining mode information comprises:

the processing equipment carries out simulation processing on the workpieces with matched process types in the independent processing mode;

a random processing mode, wherein processing equipment carries out simulation processing on workpieces of any process type in the random processing mode; and

and in the hybrid processing mode, the processing equipment preferentially performs simulation processing on the workpieces matched with the process types, and if no workpiece matched with the process types exists, the simulation processing is performed on the workpiece of any process type.

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